Improvements to the Design and Use of Post-tensioned Self-centering Energy-dissipative (SCED) Braces

Erochko, Jeffrey A.

07 August 2013

The self-centering energy dissipative (SCED) brace is an innovative cross-bracing system that eliminates residual building deformations after seismic events and prevents the progressive drifting that other inelastic systems are prone to experience under long-duration ground motions. This research improves upon the design and use of SCED braces through three large-scale experimental studies and an associated numerical building model study. The first experimental study increased the strength capacity of SCED braces and refined the design procedure through the design and testing of a new high-capacity full-scale SCED brace. This brace exhibited full self-centering behaviour and did not show significant degradation of response after multiple earthquake loadings. The second experimental study extended the elongation capacity of SCED braces through the design and testing of a new telescoping SCED (T-SCED) brace that provided self-centering behaviour over a deformation range that was two times the range that was achieved by the original SCED bracing system. It exhibited full self-centering in a single storey full-scale frame that was laterally deformed to 4% of its storey height. The third experimental study confirmed the dynamic behaviour of a multi-storey SCED-frame in different seismic environments and confirmed the ability of computer models of differing complexity to accurately predict the seismic response. To achieve these goals, a three-storey SCED-braced frame was designed, constructed, and tested on a shake table. Lastly, a numerical six-storey SCED-braced building model was constructed. This model used realistic brace properties that were determined using a new software tool that simulates the full detailed mechanics of SCED and T-SCED braces. The building model showed that initial SCED brace stiffness does not have a significant effect on SCED frame behaviour, that T-SCEDs generally perform better than traditional SCEDs, and that the addition of viscous dampers in parallel with SCED braces can significantly reduce drifts and accelerations while only causing a small increase in the base shear.

Structures

Earthquake Engineering

Passive Damping

Self-Centering Systems

0543

Improvements to the Design and Use of Post-tensioned Self-centering Energy-dissipative (SCED) Braces

Erochko, Jeffrey A.

07 August 2013

The self-centering energy dissipative (SCED) brace is an innovative cross-bracing system that eliminates residual building deformations after seismic events and prevents the progressive drifting that other inelastic systems are prone to experience under long-duration ground motions. This research improves upon the design and use of SCED braces through three large-scale experimental studies and an associated numerical building model study. The first experimental study increased the strength capacity of SCED braces and refined the design procedure through the design and testing of a new high-capacity full-scale SCED brace. This brace exhibited full self-centering behaviour and did not show significant degradation of response after multiple earthquake loadings. The second experimental study extended the elongation capacity of SCED braces through the design and testing of a new telescoping SCED (T-SCED) brace that provided self-centering behaviour over a deformation range that was two times the range that was achieved by the original SCED bracing system. It exhibited full self-centering in a single storey full-scale frame that was laterally deformed to 4% of its storey height. The third experimental study confirmed the dynamic behaviour of a multi-storey SCED-frame in different seismic environments and confirmed the ability of computer models of differing complexity to accurately predict the seismic response. To achieve these goals, a three-storey SCED-braced frame was designed, constructed, and tested on a shake table. Lastly, a numerical six-storey SCED-braced building model was constructed. This model used realistic brace properties that were determined using a new software tool that simulates the full detailed mechanics of SCED and T-SCED braces. The building model showed that initial SCED brace stiffness does not have a significant effect on SCED frame behaviour, that T-SCEDs generally perform better than traditional SCEDs, and that the addition of viscous dampers in parallel with SCED braces can significantly reduce drifts and accelerations while only causing a small increase in the base shear.

Structures

Earthquake Engineering

Passive Damping

Self-Centering Systems

0543

Transient Motion Control of Passive and Semiactive Damping for Vehicle Suspensions

Carter, Angela K.

10 August 1998

This research will compare the transient response characteristics of a four-degree-of-freedom, roll-plane model, representing a class 8 truck, using passive and semiactive dampers. The semiactive damper control policies that are examined include the previously developed policies of on-off skyhook, continuous skyhook, and on-off groundhook control, along with a newly developed method of fuzzy logic semiactive control. The model input will include body forces and torques, as well as transient displacements at the tires. The model outputs include the vehicle body heave and roll displacements, the vertical displacement of the tire (wheel hop) and the vertical acceleration of the vehicle body. For each output, the maximum peak-to-peak and RMS values of the response are examined. The results of the study show that semiactive dampers have minimal effect on improving the vehicle body and tire transients due to forces or torques applied to the body, as compared to passive dampers. For road inputs, however, semiactive dampers are able to provide a more favorable compromise between the body and axle transient dynamics, when compared to passive dampers. The fuzzy logic semiactive control policy that is proposed in this research is better able to balance the body and axle dynamics than the conventional semiactive damping control policies that are investigated. Further research on the application of fuzzy logic semiactive control concepts is suggested, in order to fully investigate the potential of such control schemes for vehicle suspensions. / Master of Science

fuzzy logic

groundhook

passive damping

semiactive damping

skyhook

vehicle suspension

Design of viscoelastic damping for noise & vibration control: modelling, experiments and optimisation

Hazard, Laurent

20 February 2007

The scope of this research concerns the passive damping of structural vibrations by the use of viscoelastic layers. It is motivated by the need for efficient numerical tools to deal with the medium frequency behaviour of industrial viscoelastic sandwich products. The sandwich modelling technique is based on the use of an interface element: the two deformable plates are modelled by special plate elements while the intermediate dissipative layer is modelled with interface elements. This interface element is based on the first-order shear deformation theory and assume constant peel and shear stresses in the polymer thickness. This element couples the lower and upper layers without additional degrees of freedom. The partition of unity finite element method (PUFEM) is applied to the development of enriched Mindlin plate elements. The element shape functions are obtained as the product of partition of unity functions with arbitrary chosen enrichment functions. Polynomial enrichment leads to the generation of high-order polynomial shape functions and is therefore similar to a p-FEM technique. Numerical examples illustrate the use of both PUFEM Mindlin plate elements and interface elements for the simulation of viscoelastic sandwich structures.

generalized finite element

optimisation

viscoelastic

vibration

acoustic

passive damping

PUFEM

partition of unity

Improving Machining System Performance through designed-in Damping : Modelling, Analysis and Design Solutions

Daghini, Lorenzo

January 2012

With advances in material technology, allowing, for instance, engines to withstand higher combustion pressure and consequently improving performance, comes challenges to productivity. These materials are, in fact, more difficult to machine with regards to tool wear and especially machine tool stability. Machining vibrations have historically been one of the major limitations to productivity and product quality and the cost of machining vibration for cylinder head manufacturing has been estimated at 0.35 euro per part. The literature review shows that most of the research on cutting stability has been concentrating on the use of the stability limits diagram (SLD), addressing the limitations of this approach. On the other hand, research dedicated to development of machine tool components designed for chatter avoidance has been concentrating solely on one component at the time. This thesis proposes therefore to extend the stability limits of the machining system by enhancing the structure’s damping capability via a unified concept based on the distribution of damping within the machining system exploiting the joints composing the machine tool structure. The design solution proposed is based on the enhancement of damping of joint through the exploitation of viscoelastic polymers’ damping properties consciously designed as High Damping Interfaces (HDI). The tool-turret joint and the turret-lathe joint have been analysed. The computational models for dimensioning the HDI’s within these joints are presented in the thesis and validated by the experiments. The models offer the possibility of consciously design damping in the machining system structure and balance it with regards to the needed stiffness. These models and the experimental results demonstrate that the approach of enhancing joint damping is viable and effective. The unified concept of the full chain of redesigned components enables the generation of the lowest surface roughness over the whole range of tested cutting parameters. The improved machining system is not affected by instability at any of the tested cutting parameters and offers an outstanding surface quality. The major scientific contribution of this thesis is therefore represented by the proposed unified concept for designing damping in a machining system alongside the models for computation and optimisation of the HDIs. From the industrial application point of view, the presented approach allows the end user to select the most suitable parameters in terms of productivity as the enhanced machine tool system becomes less sensitive to stability issues provoked by difficult-to-machine materials or fluctuations of the work material properties that may occur in ordinary production processes. / <p>QC 20120413</p> / DampComat / Production 4 micro / FFI Robust Machining

Machining performance

Cutting stability

Passive damping

High Damping Interface

Boring bar

Turret

電磁共振ダンパによる振動制御

井上, 剛志, INOUE, Tsuyoshi, 石田, 幸男, ISHIDA, Yukio, 角, 正貴, SUMI, Masaki

09 1900

No description available.

Vibration Control

Passive Damping

Dynamic Vibration Absorber

Resonance Circuit

Voice Coil Motor

Vibro-Acoustic Analysis of a Thin Cylindrical Shell with Minimal Passive Damping Patches

Taulbee, Ron J.

23 August 2013

No description available.

Mechanical Engineering

Vibro-acoustic

Acoustics

Insertion losses

Passive damping

Damping patches

Thin Shell

Development of Refined Analytical Vibration Models for Plates and Shells with Combined Active and Passive Damping Treatments

Plattenburg, Joseph Allan

23 September 2016

No description available.

Mechanical Engineering

Shell Vibrations

Noise and Vibration Control

Modal Analysis

Laboratory Experiments

Active and Passive Damping

Estimation of Elastic and Damping Characteristics of Viscoelastically Constrained Carbon Strands

Vasudeva, Sumit

05 January 2006

Traditional large space structure construction incorporates the use of lightweight tubular metal alloys that have good strength to weight and stiffness to weight ratio. Recently, however, space structure construction has shifted focus on materials that are ultra lightweight, have high strength, have low package volume and possess excellent damping characteristics. Substantial damping is required in space since there is no surrounding medium to provide damping. Such a construction uses composites in a fabric form that displays viscoelastic behavior. The viscoelastic behavior is attributed to energy dissipation because of the shear stresses between the various fibrous strands that are kept in place by constraining viscoelastic layers. This type of vibration control falls under the rubric of passive damping of structures and has been found to have certain advantages over active damping such as less complexity as it does not require sensors, actuators and power supply that are needed for active damping. One such material consists of woven carbon strands constrained by layers of viscoelastic damping material. Dynamics and buckling behavior of a structure in the form of a tube made from this material with metallic end caps is modeled and analyzed using commercially available Finite Element Analysis code ABAQUS®. The current analysis deals with the non-pressurized tube since the structure can maintain the tubular configuration as well as support end caps on account of the stiffness provided by the composites. Since no simple analytical approaches are available to predict damping of these materials, experimental data was used to estimate the damping characteristics of the material. The mass of the end cap was also estimated from the experimental impulse response as exact mass of the end cap (that was rigidly fixed to the tube) was unknown. / Master of Science

Passive Damping

Buckling

Finite element method

Viscoelasticity

Prony Series

Space Structures

Composites

Etude Expérimentale et Modélisation par la méthode des éléments discrets de l’amortissement dans les matériaux granulaires / Experimental study and modeling by the discrete element method of damping in granular media

Daoud, Marwa

15 September 2016

Ce travail de thèse a pour objet d’analyser le processus de dissipation d’énergie dans les amortisseurs par milieux granulaires. Des études de nature expérimentale, analytique et numérique ont été menées afin de pouvoir détecter les paramètres clefs agissant sur la dissipation; un modèle expérimental minimal a été présenté en premier lieu afin de mettre en évidence l’efficacité des milieux granulaire en tant qu’amortisseurs de vibrations. Un second modèle expérimental plus élaboré a été développé, avec de multiples protocoles expérimentaux, pour mener une étude paramétrique et détecter leurs impacts sur l’évolution du facteur de perte du système. On montre que le coefficient de perte ne dépend pas du matériau des particules ou leur nombre, mais dépend fortement de la masse totale des grains embarqués et sur l’amplitude du signal vibrant. Nos mesures montrent aussi la contribution de l'écoulement visqueux de l'air entourant les grains au facteur de perte globale des amortisseurs.La partie analytique à son tour a permis de retrouver le comportement obtenu expérimentalement par le billet du développement des équations du mouvement du système, celle des énergie cinétique et énergie dissipée afin de proposer enfin une équation maitresse qui décrit l’évolution du facteur de perte réduit au sein de notre système. Pour atteindre une plus grande précision, une modélisation du système granulaire par la méthode des éléments discrets (DEM) a permis de retrouver les mêmes conclusions et ainsi valider les constatations expérimentales et le modèle analytique proposé. / This thesis aims to analyze the process of energy dissipation in particle dampersExperimental, analytical and numerical studies have been conducted in order to identify key parameters influencing the dissipation; minimal experimental model was introduced first to highlight the efficiency of granular media as shock absorbers of vibrations. A second more sophisticated experimental model was developed, with multiple experimental protocols, to conduct a parametric study and detect their impact on the evolution of the system loss factor. It is shown that the loss coefficient is independent of the particle material or their number, but depends strongly on the total mass of embedded grains and on the amplitude of the vibrating signal. Our measurements also show the contribution of viscous flow of the air surrounding the grains to the overall loss factor.The analytical part in turn led to the discovery The behaviour obtained experimentally by the development of the equations of motion of the system, that of kinetic energy dissipated and energy to finally offer a mistress equation which describes the evolution of the loss factor reduced within our system. To achieve greater accuracy, a model of the granular system by the discrete element method (DEM) allowed to find the same conclusions and thus validate the experimental findings and the proposed analytical model.

Amortisseurs Passifs

Vibration

Milieu granulaire.

Dissipation

Méthode des éléments discrets

Passive damping

Vibration

Granular media

Dissipation

Discrete element method