An Investigation of the Feasibility of Microscale Adaptive Passive Vibration Neutralizers

Weber, Michael A.

12 June 2002

This thesis concerns the control of an adaptive passive vibration neutralizer and the feasibility of miniaturizing this type of tunable vibration neutralizer for small-scale applications. An analytical model for the adaptive passive vibration neutralizer is derived and compared to experimental results. A tuning algorithm is derived from a curve-fit of experimental tests on the specific neutralizer. A more generic tuning algorithm is also developed, which does not require testing of the neutralizer for optimal control. Both tuning algorithms are tested using a chirp forcing function to simulate drift in the excitation frequency of a host structure. Computer simulation and experimental results are given for these tests. A novel low-cost, small-scale vibration neutralizer is constructed from packing bubble-wrap. Analytical models for the stiffness are calculated, and experimental data is used to derive a damped mass-spring model. Miniaturization of vibration neutralizers is described, and many of the pitfalls in design are discussed. Theoretical tuning frequencies of possible adaptive passive vibration neutralizers at different scales are included. The goal for these miniaturized vibration neutralizers is vibration control in computer hard drives. A hard drive is analyzed for vibration problems. Included are plots of the velocities of the read-write head and spindle. Limitations of the measurement equipment are discussed, and directions for future work on small-scale tunable vibration neutralizers are outlined. / Master of Science

piezoelectric

laser vibrometer

air bubble

hard disk drive

vibration control

microsystems

nanotechnology

Simulating the Elastic Response of the Solid Earth due to Ocean Tide Loading in the La Plata Estuary

Whaley, Michael K.

January 2021

No description available.

Geophysics

Earth

Ocean Tide Loading

La Plata Estuary

elastic response

disk load

solid Earth deformation

surface loading

Solving Navier-Stokes equations in protoplanetary disk using physics-informed neural networks

Mao, Shunyuan

07 January 2022

We show how physics-informed neural networks can be used to solve compressible \NS equations in protoplanetary disks. While young planets form in protoplanetary disks, because of the limitation of current techniques, direct observations of them are challenging. So instead, existing methods infer the presence and properties of planets from the disk structures created by disk-planet interactions. Hydrodynamic and radiative transfer simulations play essential roles in this process. Currently, the lack of computer resources for these expensive simulations has become one of the field's main bottlenecks. To solve this problem, we explore the possibility of using physics-informed neural networks, a machine learning method that trains neural networks using physical laws, to substitute the simulations. We identify three main bottlenecks that prevent the physics-informed neural networks from achieving this goal, which we overcome by hard-constraining initial conditions, scaling outputs and balancing gradients. With these improvements, we reduce the relative L2 errors of predicted solutions by 97% ~ 99\% compared to the vanilla PINNs on solving compressible NS equations in protoplanetary disks. / Graduate / 2022-12-10

Machine learning

protoplanetary disk

physics-informed neural networks

scientific machine learning

astronomy

differential equations

Parametric Study of the Rossby Wave Instability in a Two-Dimensional Barotropic Disk / 広いパラメータ領域を被覆する二次元順圧円盤上におけるロスビー波不安定性の研究

Ono, Tomohiro

26 March 2018

京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第20917号 / 理博第4369号 / 新制||理||1627(附属図書館) / 京都大学大学院理学研究科物理学・宇宙物理学専攻 / (主査)教授 嶺重 慎, 准教授 前田 啓一, 教授 太田 耕司 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DFAM

Rossby wave instability

protoplanetary disk

linear stability analysis

numerical simulation

vortex

400

An Investigation of the Impact of Contact Parameters on the Wear Coefficient

Janakiraman, Venkatakrishna

22 August 2013

No description available.

Mechanical Engineering

Wear Coefficient

Archard's Wear Model

Twin Disk Tests

Gears

Deep R-Band Surface Photometry of NGC891

Miller, Eric

January 1996

No description available.

Astronomy

Astrophysics

Physics

disk galaxies

galactic evolution

galactic halos

galactic structure

NGC891

Study of Plants Used Against Infections by California Native American Tribes

Rojas, Maria J

01 December 2020

The objectives of this research were to evaluate the antibacterial activity and to determine the chemical composition of a list of medicinal plants used by Native Americans in California. Artemisia californica, Mimulus aurantiacus, Equisetum telmateia, Equisetum hyemale, and Marah fabacea were selected from a list of plants reported as having been used for ailments related to infections by tribes located in California. The extracts obtained through steam distillation from E. telmateia, E. hyemale and M. fabacea were assayed for in vitro antibacterial activity against 16 Gram-negative and 6 Gram-positive bacteria using disk diffusion assays and measuring the diameters of inhibition zones. E. telmateia showed the most promising antibacterial activity. The extracts from A. californica, M. aurantiacus and E. telmateia were analyzed for chemical composition, finding eucalyptol, thujone, eugenol, caryophyllene, germacrene D, and propanal as some of the secondary metabolites identified using GC-MS. Our results suggest that E. telmateia can be a potential source for novel antimicrobials against pathogenic bacteria.

Medicinal Plants

Essential Oil

Antibacterial Activity

UTI

Ethnobotany

Disk Diffusion Assay

Alternative and Complementary Medicine

Biology

Microbiology

Nonlinear transverse vibrations of centrally clamped rotating circular disks

Manzione, Piergiuseppe

23 March 1999

A study is presented of the instability mechanisms of a damped axisymmetric circular disk of uniform thickness rotating about its axis with constant angular velocity and subjected to various transverse space-fixed loading systems. The natural frequencies of spinning floppy disks are obtained for various nodal diameters and nodal circles with a numerical and an approximate method. Exploiting the fact that in most physical applications the thickness of the disk is small compared with its outer radius, we use their ratio to define a small parameter. Because the nonlinearities appearing in the governing partial-differential equations are cubic, we use the Galerkin procedure to reduce the problem into a finite number of coupled weakly nonlinear second-order equations. The coefficients of the nonlinear terms in the reduced equations are calculated for a wide range of the lowest modes and for different rotational speeds. We have studied the primary resonance of a pair of orthogonal modes under a space-fixed constant loading, the principal parametric resonance of a pair of orthogonal modes when the disk is subject to a massive loading system, and the combination parametric resonance of two pairs of orthogonal modes when the excitation is a linear spring. Considering the case of a spring moving periodically along the radius of the disk, we show how its frequency can be coupled to the rotational speed of the disk and lead to a principal parametric resonance. In each of these cases, we have used the method of multiple scales to determine the equations governing the modulation of the amplitudes and phases of the interacting modes. The equilibrium solutions of the modulation equations are determined and their stability is studied. / Master of Science

Combination parametric resonance

Principal parametric resonance

Duffing Oscillator

Rotating disk

Primary Resonance

Inflammatory-Based Therapies Driven by Intervertebral Disc Injury Responses

Kenawy, Hagar Mohamed

January 2024

Intervertebral disc (IVD) degeneration is a major cause of low back pain (LBP) worldwide which is expected to affect 80% of the world’s population. IVD degeneration (IDD) is a key player in the degenerative cascade associated with LBP. Pro-inflammatory cytokines and mediators, such as nitric oxide, have been shown to be triggers and mediators of IDD. Due to the avascular nature of the adult IVD, the disc is unable to heal or regenerate when damaged. The multi-components of the IVD, namely glycosaminoglycan (GAG)-rich nucleus pulposus (NP), a concentric collagen dense annulus fibrosis (AF), and cartilage endplates (CEPs), further complicate possible regenerative solutions. Cell therapies show promise. This is supported by studies that demonstrate the use of mesenchymal stem cells (MSCs) in animal models showing potential in mitigating inflammatory signaling as well as recovering proteoglycan content. Despite these promising findings, several gaps in knowledge remain. While the biochemical and mechanical properties of an injured disc (via physical or chemical stimulation) have been characterized, the resulting inflammatory signaling cascades remain undefined. A growing body of evidence suggests that TLR4 is involved in the pathogenesis of the IVD. However, it is unknown how TLR4 mediates injury responses of the IVD. Second, it is unknown how mechanical loading of IVDs can influence the transcriptome or secretome of the IVD. The IVD is normally exposed to multimodal loading (e.g., compression, tension, shear, hydrostatic pressure, and osmotic pressure). Both frequency and magnitude regulate whether loading is beneficial or detrimental to disc integrity, which will be explored. Furthermore, the secretome of the IVD, especially during loading, may be essential to creating therapies targeted for regeneration of the IVD. There may be key, distinct paracrine factors that are released in IVD conditioned loading media which can influence the regenerative and anti-inflammatory capabilities of cell-based therapies. To address these gaps, this thesis describes a series of experiments employing novel ex vivo organ culture model to study the response of the IVD to various injury modalities (inflammatory stimulation, puncture injury, compressive loading), and resulting changes in inflammatory, biomechanical, and biochemical responses. Through methods such as RNA sequencing and proteomics, we now have expanded the characterization to beyond candidate genes or proteins, and are more informed on (1) the IVD response to injury, (2) the role of TLR4 signaling in this ex vivo organ culture model, in addition to (3) the downstream effects of loading and how paracrine factors can be used to improve and develop potential cell and molecular therapies. Sex-based differences, in male and female rat caudal IVDs, were also identified and are analyzed in the context of response to injury.

Biomedical engineering

Biomechanics

Intervertebral disk--Diseases

Backache--Treatment

Inflammation

Nitric oxide--Physiological effect

Mesenchymal stem cells

Rotating Disk Electrode Design for Concentration Measurements in Flowing Molten Chloride Salts

Sullivan, Kelly Marie

25 July 2022

Over the past several years as interest in cleaner energy sources has grown nuclear power has come to the forefront. However, as interest in nuclear power grows so does the concern over the amount of high-level radioactive waste produced. Currently, the most popular way to deal with spent nuclear fuel is interim storage until a viable treatment option becomes available. Simply waiting for spent fuel to become safe to handle will take thousands of years and is not a reasonable long-term solution. We will soon run out of space in our spent fuel pools and while more dry storage space can be found it is not an ideal solution. One answer to this problem is the reprocessing of spent nuclear fuel. This could be done with either the plutonium uranium reduction extraction (PUREX) method or the pyroprocessing method. Since PUREX does not have the same level of built-in proliferation resistance as pyroprocessing, pyroprocessing is starting to be seen as a good alternative method. Pyroprocessing would take the spent nuclear fuel from a light water reactor and make it into a metal-based fuel that could be used in certain advanced reactors. Molten salt reactors are of particular interest when it comes to reprocessing spent nuclear fuel because of their unique property of using a liquid fuel. Molten salt reactors and spent fuel reprocessors could be directly connected which would save both time and money as little storage and transportation would need to be considered. Regardless of how and where the used nuclear fuel is being recycled it is important to be able to keep track of the major actinides and fission products in the fuel as it moves through the process. Electrochemical concentration measurements are straightforward and well understood in static cases when there is only a single element to consider. When additional elements are added, or the system is flowing rather than static, things get slightly more complicated but are still decently well understood. However, in the case of spent fuel reprocessing the system is both be flowing and contains much more than a single element. This case is not well understood and is what this study attempts to understand. Two different rotating electrodes were designed to simulate flowing conditions in an electrochemical cell. The first was a tungsten rotating disk electrode (RDE) and the second was a graphite RDE. We were not able to fully insulate the tungsten RDE and were therefore unable to achieve reliable results. Because of this the tungsten design was put aside in favor of the graphite design, which did prove to be sufficiently insulated. The graphite RDE was tested in two different salt systems: LiCl-KCl-NiCl2-CrCl2 and LiCl-KCl-EuCl3-SmCl3. In the nickel-chromium system the graphite RDE produced the expected results. The calculated nickel concentration was found to be within 10% of the measured concentration. Calculations of the chromium concentration, however, were not possible due to the deposition of nickel on the graphite surface, which increased the surface area of the working electrode. When the graphite RDE was tested in the second system it was first tested in the ternary salt LiCl-KCl-EuCl3 and was able to produce decent results. The concentration of europium calculated from the scan was within 10% of the measured value. When the RDE was tested in the LiCl-KCl-EuCl3-SmCl3 salt the results did not come out as expected. Several rather noisy CV curves were obtained and no alterations to the cell seemed to affect them. At this point it was determined that the reason for the confused scans was a connection problem that could not be remedied within the time frame of this study. While this study does not accomplish the task it set out to do, it is a good step in the direction toward understanding flowing systems containing more than a single element of interest and has successfully designed a reliable graphite RDE. / Master of Science / As interest in nuclear power continues to grow, so does the concern over the amount of high-level nuclear waste produced. More nuclear power means more nuclear reactors and thus more spent nuclear fuel to be dealt with. Currently most used nuclear fuel ends up in interim storage facilities where it is meant to wait until it is safe to handle, which could take several thousand years, or until a reliable disposal method is determined. On this path the amount of spent fuel that requires storage will quickly overrun the amount of storage space safely available. One way to reduce the amount of nuclear waste is to reprocess it to be used as fuel for different types of reactors. The pyroprocessing method takes the spent nuclear fuel from a typical light water reactor and recycles it into fuel that can be used in certain types of advanced reactors, such as molten salt reactors (MSR) and sodium-cooled fast reactors (SFR). The reprocessing system works to separate the usable actinide elements, such as uranium and plutonium, from any fission products or other contaminants. During these processes it is important to be able to keep track of the concentrations of each of these different elements to ensure proper separation. This study examines the use of two rotating disk electrode (RDE) designs that are meant to simulate the flowing conditions found in many reprocessing systems. These RDEs were to be used to measure the concentrations of different elements in molten salt systems. The first design, a tungsten RDE, could not be properly insulated and thus was unable to produce reliable results when tested in the electrochemical cell. The second design was a graphite RDE. This design did prove to be properly insulated and was able to produce good results when tested in the cell. The graphite RDE was tested in both LiCl-KCl-NiCl2-CrCl2 and LiCl-KCl-EuCl3-SmCl3. In the first system the concentration of nickel was correctly calculated using the data collected with the graphite RDE, while the chromium concentration could not be due to the nickel deposition on the graphite. In the second system, good results were obtained before the SmCl3 was added to the salt. At this point a connection error became apparent and reliable results were no longer possible. Further study is needed to understand the LiCl-KCl-EuCl3-SmCl3 system using the graphite RDE.

Rotating Disk Electrode

Cyclic Voltammetry

Concentration Measurements

Pyroprocessing

Molten Salt Reactors