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11	The effectiveness of particle dampers under centrifugal loads Els, Daniel Nicolaas Johannes 03 1900 (has links) Thesis (PhD (Mechanical and Mechatronic Engineering))--University of Stellenbosch, 2009. / The main research objective of this dissertation was to determine the performance parameters of particle dampers (PDs) under centrifugal loads. A test bench was developed consisting of a rotating cantilever beam with a PD at the tip. Equal mass containers with di erent depths, filled with a range of uniform sized steel ball bearings, were used as PDs. For all the tests, the total PD mass was identical. During operation the tip of the beam was displaced, and after release, the beam could vibrate freely. The decay in the vibratory motion of the tip of the beam was measured over a range of centrifugal loads. The experiments were duplicated numerically with a discrete element method (DEM) model, calibrated against the experimental data. This model could then be used for a more in-depth investigation of phenomena occurring when PDs are under centrifugal loads. From the data analysis, it can be concluded that there are two zones of damping, one with a high and one with a low damping factor. These damping zones depend on the ratio between the peak vibration acceleration and the centrifugal loading. Each zone has a limit in terms of the centrifugal loading beyond which the PD cannot function if the vibration amplitude is fixed. In the high damping zone, it was found that the excitation state of the particles was high enough for the system vibration frequency to change. In the low damping zone, there is only limited motion between the particles. The main parameters that influence the performance of the PDs are the friction between the particles themselves and with the container, the PD length/diameter aspect ratio, and the particle size. An important finding is that a PD with less layers (increase in particle size) will still function at a higher centrifugal load compared to one with a smaller number number of layers. Particle dampers Dissertations -- Mechanical engineering Theses -- Mechanical engineering Vibration Centrifugal force Granular materials
12	Dielectric Properties of Epoxy/Alumina Nanocomposite Influenced by Control of Micrometric Agglomerates Hayakawa, Naoki, Takei, Masafumi, Hoshina, Yoshikazu, Hanai, Masahiro, Kato, Katsumi, Okubo, Hitoshi, Kurimoto, Muneaki 06 1900 (has links) No description available. tan δ particle dispersibility agglomerate centrifugal force ultrasonic wave alumina nanoparticle Epoxy nanocomposite
13	Permittivity Characteristics of Epoxy/Alumina Nanocomposite with High Particle Dispersibility by Combining Ultrasonic Wave and Centrifugal Force Hayakawa, Naoki, Takei, Masafumi, Hoshina, Yoshikazu, Hanai, Masahiro, Kato, Katsumi, Okubo, Hitoshi, Kurimoto, Muneaki 05 August 2010 (has links) No description available. centrifugal force ultrasonic wave particle dispersibility permittivity alumina nanoparticle Epoxy nanocomposite
14	Evaluation of time varying stresses in a Howden fan van Mierlo, Tim, Żywalewski, Rafal January 2015 (has links) In this work, the time varying stresses in a Howden axial flow fan are obtained by finite element analyses. Dynamic substructuring is used to obtain accurate values of the stresses in the threads of the blade shaft, the component which connects the blade with the hub. Three different global models are used to compare the influence of neglecting the fan shaft and the stiffness influence of the centrifugal force. The relative displacements, which are obtained from the global models, have been used as boundary condition in the detailed models. The detailed models are used to obtain the Von Mises stresses in the root of the threads of the blade shaft. Finally the results of the three global models are compared with experimental measured data provided by Howden. The experimental data results in the highest Von Mises stresses. The model with the fan shaft and the stiffness influence of the centrifugal force gives values for the Von Mises stresses which are approximately twenty percent lower. The model without the fan shaft results in the lowest stresses which are approximately forty percent lower than the stresses obtained using the measured data. Finite element analyses Dynamic substructuring Axial flow fan Blade Rotor dynamics Centrifugal force
15	Numerical and Experimental Studies of Deployment Dynamics of Space Webs and CubeSat Booms Mao, Huina January 2017 (has links) In this thesis, experiments and simulations are performed to study the deployment dynamics of space webs and space booms, focusing on the deployment and stabilization phases of the space web and the behavior of the bi-stable tape spring booms after long-term stowage. The space web, Suaineadh, was launched onboard the sounding rocket REXUS-12 from the Swedish launch base Esrange in Kiruna on 19 March 2012. It served as a technology demonstrator for a space web. A reaction wheel was used to actively control the deployment and stabilization states of the 2×2 m2 space web. After ejection from the rocket, the web was deployed but entanglements occurred since the web did not start to deploy at the specified angular velocity. The deployment dynamics was reconstructed by simulations from the information recorded by inertial measurement units and cameras. Simulations show that if the web would have started to deploy at the specified angular velocity, the web would most likely have been deployed and stabilized in space by the motor, reaction wheel and controller used in the experiment. A modified control method was developed to stabilize the out-of-plane motions before or during deployment. New web arms with tape springs were proposed to avoid entanglements. A deployable booms assembly composed of four 1-m long bi-stable glass fiber tape springs was designed for the electromagnetically clean 3U CubeSat Small Explorer for Advanced Missions (SEAM). The deployment dynamics and reliability of the SEAM boom design after long-term stowage were tested by on-ground experiments. A simple analytical model was developed to predict the deployment dynamics and to assess the effects of the GOLS and the combined effects of friction, viscoelastic strain energy relaxation, and other factors that act to decrease the deployment force. In order to mitigate the viscoelastic effects and thus ensure self-deployment, different tape springs were designed, manufactured and tested. A numerical model was used to assess the long-term stowage effects on the deployment capability of bi-stable tape springs including the friction, nonlinear-elastic and viscoelastic effects. A finite element method was used to model a meter-class fully coiled bi-stable tape spring boom and verified by analytical models. / <p>QC 20170508</p> / SEAM Deployable structure Space web Centrifugal force deployment Deployable boom Bi-stable tape spring Fiber-reinforced composite Viscoelasticity Mechanical Engineering Maskinteknik
16	Application of Functionally Graded Material for Reducing Electric Field on Electrode and Spacer Interface Okubo, Hitoshi, Takei, Masafumi, Hoshina, Yoshikazu, Hanai, Masahiro, Kato, Katsumi, Kurimoto, Muneaki 02 1900 (has links) No description available. Gas insulated switchgear (GIS) Centrifugal force Filler Epoxy resin Spacer Electric field Permittivity Functionally graded material (FGM)
17	Investigation of an extremely flexible stowable rotor for micro-helicopters Sicard, Jérôme 12 July 2011 (has links) This thesis describes the analysis, fabrication and testing of a rotor with extremely flexible blades, focusing on application to a micro-helicopter. The flexibility of the rotor blades is such that they can be rolled into a compact volume and stowed inside the rotor hub. Stiffening and stabilization of the rotor is enabled by centrifugal forces acting on a tip mass. Centrifugal effects such as bifilar and propeller moments are investigated and the torsional equation of motion for a blade with low torsional stiffness is derived. Criteria for the design of the tip mass are also derived and it is chosen that the center of gravity of each blade section must be located ahead of the aerodynamic center. This thesis presents the design of 18-inch diameter two-bladed rotors having untwisted circular arc airfoil profile with constant chord. A systematic experimental investigation of the effect of various blade parameters on the stability of the rotor is conducted in hover and forward flight. These parameters include blade flexibility in bending and torsion, blade planform and mass distribution. Accordingly, several sets of blades varying these parameters are constructed and tested. It is observed that rotational speed and collective pitch angles have a significant effect on rotor stability. In addition, forward flight velocity is found to increase the blade stability. Next, the performance of flexible rotors is measured. In particular, they are compared to the performance of a rotor with rigid blades having an identical planform and airfoil section. It is found that the flexible blades are highly twisted during operation, resulting in a decreased efficiency compared to the rigid rotor blades. This induced twist is attributed to an unfavorable combination of tip body design and the propeller moment acting on it. Consequently, the blade design is modified and three different approaches to passively tailor the spanwise twist distribution for improved efficiency are investigated. In a first approach, extension-torsion composite material coupling is analyzed and it is shown that the centrifugal force acting on the tip mass is not large enough to balance the nose-down twist due to the propeller moment. The second concept makes use of the propeller moment acting on the tip mass located at an index angle to produce an untwisted blade in hover. It is constructed and tested. The result is an untwisted 18-inch diameter rotor whose maximum Figure of Merit is equal to 0.51 at a blade loading of 0.14. Moreover, this rotor is found to be stable for any collective pitch angle greater than 11 degrees. Finally, in a third approach, addition of a trailing-edge flap at the tip of the flexible rotor blade is investigated. This design is found to have a lower maximum Figure of Merit than that of an identical flexible rotor without a flap. However, addition of this control surface resulted in a stable rotor for any value of collective pitch angle. Future plans for increasing the efficiency of the flexible rotor blades and for developing an analytical model are described. / text Flexible rotor blade Micro helicopter Stowable Aeroelastic stability Propeller moment Bifilar moment Centrifugal force Pitch flap flutter Divergence Luffing
18	Evaluation of different centrifugation settings using BD Microtainer® tubes Molin, Elin January 2016 (has links) In order to keep the turnaround time it is desirable to have few centrifugal programs and be able to centrifuge microtainer tubes together with vacutainer tubes. BD has launched a new type of microtainer tube that got a lower g-force than the older one on the same centrifugation program. The aims was to compare this program and three other, more powerful, programs and compare the impact on some common analytes and serum indices, especially on hemolysis. Three test parts was performed using venous samples taken from healthy individuals, 1) transfer of whole blood from serum tube to microtainer tubes, a clinical chemistry analysis; 2) whole blood from plasma tube to microtainer tubes, a clinical chemistry analysis and 3) whole blood from plasma tube to microtainer tubes for platelet count analysis. All tubes were examined for gel formation. The result showed a significant variance between some settings for some analytes but foremost at 899g and at 2000g, both in 10 min. The platelet count was below the threshold limit at 2000g. No tube had insufficient formation of the gel. The setting of 2000g was found suitable for microtainer tubes. These results correspond with the recommended settings from BD. Further studies are needed with more analytes and test subjects and a simulated transport time for plasma, because of the increased risk for hemolysis, to confirm if the same setting can be used for microtainer tubes (899g) as for the older microtainer tube and vacutainer tube (1300g). Preanalytic error Lithium-heparin evaluation PST relative centrifugal force clinical chemistry Analytical interference Clinical Medicine Klinisk medicin
19	Studium přípravy a struktury nanovláken anorganických a organických biomateriálů / Study of preparation and structure of nanofibers of inorganic and organic biomaterials Ručková, Jana January 2014 (has links) The aim of this Master’s thesis is to investigate the preparation and structure of nanofibres of inorganic and organic biomaterials. Nanofibres of polycaprolactone, chitosane and their composites with hydroxyapatite particle were prepared by centrifugal force spinning process, which uses centrifugal forces for nanofibres spinning. Designed nanofibres can be used in bone tissue engineering. Experimental activity has started with synthesis of hydroxyapatite nanoparticles and preparation of polymer solutions and composite suspensions at different concentrations. The solutions and the suspensions were characterized by density and viscosity which were changed in dependence on temperature and polymer concentration. The solutions and the suspensions were spun at varying speeds and using two different sizes of collectors. The dependence of spinneret head revolution speed, size of collectors and polymer concentration on nanofibres diameter was studied. Biological activity of polycaprolactone and hydroxyapatite/polycaprolactone nanofibres was tested by means of SBF.
20	Deployment Control of Spinning Space Webs and Membranes Gärdsback, Mattias January 2008 (has links) Future solar sail and solar power satellite missions require deployment of large and lightweight flexible structures in space. One option is to spin the assembly and use the centrifugal force for deployment, stiffening and stabilization. Some of the main advantages with spin deployment are that the significant forces are in the plane of rotation, a relatively simple control can be used and the tension in the membrane or web can be adjusted by the spin rate to meet the mission requirements. However, a successful deployment requires careful development of new control schemes. The deployment rate can be controlled by a torque, applied either to a satellite in the center or by thrusters in the corners, or by deployment rate control, obtained by tether, spool braking or folding properties. Analytical models with only three degrees of freedom were here used to model the deployment of webs and membranes for various folding patterns and control schemes, with focus on space webs folded in star-like arms coiled around a center hub. The model was used to investigate control requirements and folding patterns and to obtain optimal control laws for centrifugal deployment. New control laws were derived from the optimal control results and previously presented control strategies. Analytical and finite element simulations indicate that the here developed control laws yield less oscillations, and most likely more robustness, than existing controls. Rotation-free (RF) shell elements can be used to model inflation or centrifugal deployment of flexible memebrane structures by the finite element method. RF elements approximate the rotational degrees of freedom from the out-of-plane displacements of a patch of elements, and thus avoid common singularity problems for very thin shells. The performance of RF shell elements on unstructured grids is investigated in the last article of this thesis, and it is shown that a combination of existing RF elements performs well even for unstructured grids. / QC 20100729 Flexible structures space webs membranes solar sails solar power systems deployment control optimal control centrifugal force deployment spin deployment rotation-free shell elements TECHNOLOGY TEKNIKVETENSKAP

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