Elastocaloric effect vs fatigue life: Exploring the durability limits of Ni-Ti plates under pre-strain conditions for elastocaloric cooling

Tušek, Jaka; Žerovnik, Andrej; Čebron, Matjaž; Brojan, Miha; Žužek, Borut; Engelbrecht, Kurt; Cadelli, Andrea

doi:10.1016/j.actamat.2018.03.032

Cited by 126 publications

(34 citation statements)

References 55 publications

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“…Fatigue life is an important challenge that must also be addressed before the technology can be considered for commercialization. I have listed over 1 million cycles as a goal because there are indications that eCMs that can withstand even 100 000 cycles may have infinite fatigue life [33]. If we consider a 20 000 h lifetime operating at 1 Hz, the required lifetime will be 72 000 000 cycles.…”

Section: Challenges For Ecmentioning

confidence: 99%

“…The potential benefits of operating in compression are discussed in [34] and several reported devices are currently operating in compression, but their fatigue life has not yet been reported. Other methods to improve fatigue life include implementing advanced materials [16] and applying the strain in tension at the middle of the superelastic region rather than at a fully relaxed state [33]. Another solution to the fatigue challenge is to develop new, more resilient materials or to improve fatigue properties by controlling hysteresis [35].…”

Section: Challenges For Ecmentioning

confidence: 99%

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Future prospects for elastocaloric devices

Engelbrecht

2019

J. Phys. Energy

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Elastocaloric cooling (EC) is an alternative cooling technology that has been identified as having the potential to be more efficient than vapor compression systems. It is based on the elastocaloric effect, which is a change in temperature coupled to an applied uniaxial strain in materials such as NiTi alloys. Although EC is a promising technology for energy savings in the future, there are still challenges to be addressed if it is to be commercially successful. This paper gives a summary of the state of the art and recent developments in the area as well as perspectives on the most important challenges that must be met to make the technology commercial.

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Section: Challenges For Ecmentioning

confidence: 99%

Section: Challenges For Ecmentioning

confidence: 99%

Future prospects for elastocaloric devices

Engelbrecht

2019

J. Phys. Energy

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“…Consequently, the temperature of the EC element increases up to T2 = T1 + ΔT, where the size and sign of ΔT depends on the material and applied stress [see Eq. (9)]. The EC material, which still remains elastically strained, then is put into contact with a thermal sink so that heat is ejected from the system.…”

Section: Figurementioning

confidence: 99%

“…SMA alloys present two main drawbacks in the context of EC cooling [9,10]. One is related to the unavoidable hysteresis effects associated with the first-order nature of the martensitic phase transition.…”

Section: Archetypal Ec Materials: Shape-memory Alloysmentioning

confidence: 99%

“…Likewise, the large latent heat accompanying the first-order martensitic phase transition in archetypal EC compounds renders excellent cooling performances [8]. Nevertheless, conventional EC materials also present some drawbacks, mainly associated with their structural stability, mechanical fatigue, and phase-transition hysteresis, which lead to durability and irreversibility issues that may limit severely their cooling performance and applicability [9]. Finding new MC materials with improved mechanical and phase switching properties is highly desirable for the deployment of sustainable, environmentally friendly, and highly scalable solid-state cooling applications.In this review article, we survey a large number of MC materials ranging from archetypal shape-memory alloys to less renowned EC compounds like polymers, polar oxides, organometal halide perovskites, molecular crystals, multiferroics, and fast-ion conductors.…”

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Novel mechanocaloric materials for solid-state cooling applications

Cazorla

2019

Applied Physics Reviews

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Current refrigeration technologies based on compression cycles of greenhouse gases are environmentally threatening and cannot be scaled down to on-chip dimensions. Solid-state cooling is an environmentally friendly and highly scalable technology that may solve most of the problems associated with current refrigerant methods. Solid-state cooling consists of applying external fields (magnetic, electric, and mechanical) on caloric materials, which react thermally as a result of induced phase transformations. From an energy efficiency point of view, mechanocaloric compounds, in which the phase transitions of interest are driven by mechanical stresses, probably represent the most encouraging type of caloric materials. Conventional mechanocaloric materials like shape-memory alloys already display good cooling performances however in most cases they also present critical mechanical fatigue and hysteresis problems that limit their applicability. Finding new mechanocaloric materials and mechanisms able to overcome those problems while simultaneously rendering large temperature shifts, is necessary to further advance the field of solid-state cooling. In this article, we review novel families of mechanocaloric materials that in recent years have been shown to be specially promising in the aspects that conventional mechanocaloric materials are not, and which exhibit unconventional but significant caloric effects. We put an emphasis on elastocaloric materials, in which the targeted cooling spans are obtained through uniaxial stresses, since from an applied perspective these appear to be the most accomplished. Two different types of mechanocaloric materials emerge as particularly hopeful from our analysis, (1) compounds that exhibit field-induced order-disorder phase transitions involving either ions or molecules (polymers, fast-ion conductors, and plastic crystals), and (2) multiferroics in which the structural parameters are strongly coupled with polar and/or magnetic degrees of freedom (magnetic alloys and oxide perovskites).Keywords: solid-state cooling, caloric materials, field-induced transformations, entropy potential positive impact in world's sustainability caused by even modest improvements in energy efficiency is enormous. Meanwhile, for microchips to perform optimally the heat generated by electric currents needs to be removed; efficient micro-sized coolers operating near room temperature, therefore, are pressingly needed for successful engineering of faster and more compact electronic devices.Solid-state cooling is an environmentally friendly, highly energy-efficient, and highly scalable technology that may solve most of the problems associated with current refrigerant methods. Solid-state cooling relies on caloric materials and the application of external fields. In caloric materials reversible temperature shifts are achieved through the application/removal of electric, magnetic, or mechanical fields that render electrocaloric, magnetocaloric, or mechanocaloric effects, respectively. These caloric effects are ori...

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Thermo‐Haptic Materials and Devices for Wearable Virtual and Augmented Reality

Lee

Kim

Sul

et al. 2020

Adv Funct Materials

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The current generation of virtual and augmented realities (VR/AR) has substantially advanced in the past decade because of the rapid development of converging technologies in various engineering and scientific fields. However, the current VR/AR technologies rely mainly on visual and auditory senses to physically replicate the virtual environment, although tactile senses play a significant role in the daily life since a myriad of tactile information is received through physical touch. Of the tactile senses, thermal senses are of great importance to be reproduced in the VR/AR field, since heat is transferred constantly and further interact with the surrounding environment. To date, there has been a huge amount of research studies on functional materials, thermo‐haptic devices, and wearable electronics that have all converged to form the fundamental groundwork for the development of wearable thermal VR/AR devices. In this progress report, a review on various physical mechanisms and research is provided that can potentially be applied in the next generation of thermal VR/AR technologies and discuss the essential challenges that need to be addressed.

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Elastocaloric effect vs fatigue life: Exploring the durability limits of Ni-Ti plates under pre-strain conditions for elastocaloric cooling

Cited by 126 publications

References 55 publications

Future prospects for elastocaloric devices

Future prospects for elastocaloric devices

Novel mechanocaloric materials for solid-state cooling applications

Thermo‐Haptic Materials and Devices for Wearable Virtual and Augmented Reality

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