Masaomi Kimura scite author profile

Masaomi Kimura

5Publications

96Citation Statements Received

71Citation Statements Given

How they've been cited

103

How they cite others

Affiliations

Kindai University, The University of Tokyo, Toyota Motor Corporation (Japan)

Publications

Order By: Most citations

Small Loosening of Bolt-nut Fastener Due to Micro Bearing-Surface Slip: A Finite Element Method Study

Izumi

Kimura

Sakai

2007

JMMP

View full text Add to dashboard Cite

Bolt-nut fasteners are widely used in mechanical structures due to the systems' ease of disassembly for maintenance and their relatively low cost. However, vibration-induced loosening has remained problematic. In this paper, we investigated the mechanisms of the loosening process due to micro bearing-surface slip within the framework of the three-dimensional finite element method (FEM). The results show close agreement with Kasei's experimental results. It is found that the early-stage nut rotation observed experimentally originates from simultaneous bolt-nut rotation induced by the tightening torsion of the bolt and does not correspond to loosening rotation. Therefore, loosening rotation should be defined by the relative rotation angle of the nut with respect to the bolt. It is also found that small loosening is initiated when the vibration force reaches about 50 to 60% of the critical loading necessary for bearing-surface slip. Attention should be paid to the contact state of both bearing and thread surfaces when considering the loosening of bolt-nut tightening systems. Contact states can be classified into three types: complete slip involving no sticking region, micro slip involving no constant-sticking region over a vibration cycle, and localized slip involving a constant-sticking region over a vibration cycle. It is also found that loosening rotation can proceed when either micro slip or complete slip occurs at both the thread and bearing contact surfaces.

show abstract

Loosening-resistance evaluation of double-nut tightening method and spring washer by three-dimensional finite element analysis

Izumi

Yokoyama

Kimura

et al. 2009

Engineering Failure Analysis

View full text Add to dashboard Cite

Localized and extended states in one-dimensional disordered system: random-mass Dirac fermions

et al. 1999

View full text Add to dashboard Cite

System of Dirac fermions with random-varying mass is studied in detail. We reformulate the system by transfer-matrix formalism. Eigenvalues and wave functions are obtained numerically for various configurations of random telegraphic mass m(x).Localized and extended states are identified. For quasi-periodic m(x), low-energy wave functions are also quasi-periodic and extended, though we are not imposing the periodic boundary condition on wave function. On increasing the randomness of the varying mass, states lose periodicity and most of them tend to localize. At the band center or the low-energy limit, there exist extended states which have more than one peak spatially separate with each other comparatively large distance. Numerical calculations of the density of states and ensemble averaged Green's functions are explicitly given. They are in good agreement with analytical calculations by using the supersymmetric methods and exact form of the zero-energy wave functions.

show abstract

Non-locally correlated disorder and delocalization in one dimension (I): Density of states

Ichinose¹,

Kimura²

1999

Nuclear Physics B

View full text Add to dashboard Cite

We study delocalization transition in a one-dimensional electron system with quenched disorder by using supersymmetric (SUSY) methods. Especially we focus on effects of nonlocal correlation of disorder, for most of studies given so far considered δ-function type white noise disorder. We obtain wave function of the "lowest-energy" state which dominates partition function in the limit of large system size. Density of states is calculated in the scaling region. The result shows that delocalization transition is stable against nonlocal short-ranged correlation of disorder. Especially states near the band center are enhanced by the correlation of disorder which partially suppresses random fluctuation of disorder. Physical picture of the localization and the delocalization transition is discussed. Quenched disorder plays important roles in various physical phenomena. Anderson localization is one of these examples[1]. Especially in two and lower dimensions almost all states are localized, and extended delocalized states are isolated points in physical parameter region. The transition between quantum Hall plateaus is such an example. For the transition between integer quantum Hall plateaus, useful model, named network model, has been proposed[2], which incorporates effects of localization and quantum tunneling in a strong magnetic field. Numerical studies indicate that the network model belongs to the same universality class of the transition between integer quantum Hall plateaus. However it is rather difficult to solve the network model analytically because there exists no controllable parameter for perturbative expansion and also because of nature of quenched disorder itself. Compared with the twodimensional (2D) systems, one dimensional (1D) systems are more tractable. These 1D systems include Dyson's study on random strength harmonic springs[3], random Ising model by McCoy and Wu[4], and more recently random exchange spin chains[5]and random hopping tight-binding (RHTB) model [6,7,8].Recently supersymmetric (SUSY) methods appear useful for handling the quenched disorder. SUSY methods are applied to the network model [9], the 1D RHTB model [7] etc. In this paper we shall revisit the 1D RHTB model by applying the SUSY methods. Especially we shall consider nonlocally correlated quenched disorder and study stability of the delocalization transition which exists in the case of the δ-function-type white noise disorder. The model contains two parameters which control magnitude of fluctuation and correlation length of disorder. We expect that we can get detailed physical picture of (de)localization transition from calculations of density of states, Green's functions, etc. as a function of the above parameters. Another motivation of the present work is rather technical, i.e., we show how to use the SUSY methods for nonlocally correlated disorder systems.

show abstract

Simulation of water temperature in paddy fields by a heat balance model using plant growth status parameter with interpolated weather data from weather stations

Xie

Kimura

Iida

et al. 2020

Paddy Water Environ

View full text Add to dashboard Cite

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

customersupport@researchsolutions.com

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

Masaomi Kimura

Small Loosening of Bolt-nut Fastener Due to Micro Bearing-Surface Slip: A Finite Element Method Study

Loosening-resistance evaluation of double-nut tightening method and spring washer by three-dimensional finite element analysis

Localized and extended states in one-dimensional disordered system: random-mass Dirac fermions

Non-locally correlated disorder and delocalization in one dimension (I): Density of states

Simulation of water temperature in paddy fields by a heat balance model using plant growth status parameter with interpolated weather data from weather stations

Contact Info

Product

Resources

About