Joint Interface Effects on Machining System Vibration

Fu, Qilin

January 2013

Vibration problems are still the major constraint in modern machining processes that seek higher material removal rate, shorter process time, longer tool life and better product quality. Depending on the process, the weaker structure element can be the tool/tool holder, workpiece/fixture or both. When the tool/tool holder is the main source of vibration, the stability limit is determined in most cases by the ratio of length-to-diameter. Regenerative chatter is the most significant dynamic phenomenon generated through the interaction between machine tool and machining process. As a rule of thumb, the ratio between the tool’s overhang length and the tool’s diameter shouldn’t exceed 4 to maintain a stable machining process while using a conventional machining tool. While a longer tool overhang is needed for specific machining operations, vibration damping solutions are required to ensure a stable machining process. Vibration damping solutions include both active and passive damping solutions. In the passive damping solutions, damping medium such as viscoelastic material is used to transform the vibration strain energy into heat and thereby reduce vibration amplitude. For a typical cantilever tool, the highest oscillation displacement is near the anti-node regions of a vibration mode and the highest oscillation strain energy is concentrated at the node of a vibration mode. Viscoelastic materials have been successfully applied in these regions to exhibit their damping property. The node region of the 1st bending mode is at the joint interfaces where the cantilever tools are clamped. In this thesis, the general method that can be used to measure and characterize the joint interface stiffness and damping properties is developed and improved, joint interfaces’ importance at optimizing the dynamic stiffness of the joint interface is studied, and a novel advancing material that is designed to possess both high young’s modulus and high damping property is introduced. In the joint interface characterization model, a method that can measure the joint interface’s stiffness and damping over the full frequency range with only the assembled structure is presented. With the influence of a joint interface’s normal pressure on its stiffness and damping, an optimized joint interface normal pressure is selected for delivering a stable machining process against chatter with a boring bar setting at 6.5 times overhang length to diameter ratio in an internal turning process. The novel advancing material utilizes the carbon nano particles mixed in a metal matrix, and it can deliver both high damping property and high elastic stiffness to the mechanical structure. / <p>QC 20130521</p> / PoPJIM, HydroMod, XPRES, NanoComfort

Joint Interface

Vibration

Damping

Chatter

Machining

Carbon NanoComposite

PECVD

HiPIMS

Engineering and Technology

Teknik och teknologier

Modelling of contacts in Adams flex bodies using Mamba / Modellering av kontakter i Adams flexkroppar med hjälp av Mamba

Joshi, Shashwat

January 2021

Simulations are a powerful tool used to reduce development time and cost in the vehicle industry. However, the models used in simulations are simplifications of reality, and there are commonly contradicting requirements between accuracy and computational efficiency. Vehicles are constructed with a large number of parts joined together with bolts, welds and other joints. At these locations and other places where different surfaces come in contact, the contact can have a considerable effect on the dynamic behaviour of the part and capturing this effect in simulations can be difficult because of their nonlinear nature.  This thesis aims to evaluate different methods for simulating contacts and their effects under dynamic conditions. The thesis is performed at Scania, one of the top commercial vehicle manufacturer, which aims to increase the use of simulations in the design of their vehicles to have better designs with lower cost and time investments.  This thesis uses the multibody simulation software Adams Car to evaluate two different contact simulation methods, one developed by Adams and the other is the softwareMamba developed by Magna. Mamba defines special modes called Joint-interface modes, which capture the deformation in the vicinity of the contact. The contact simulations are compared with some of the existing simulation methods and physical test data by implementing it on cases where contact plays an important role in dynamic behaviour. Two such cases are identified as the leaf spring and the frame-subframe assembly. For the leaf spring example, the stiffness and energy dissipation were compared for Mamba simulations with the Adams built-in multi-beam model and physical test data. The stiffness with the Mamba contact model better matched the test data, but the energy dissipation was better modelled with the Adams leaf spring model. For the frame-subframe assembly, the effect of the Mamba contact modes was evaluated for random vibration tests by comparing acceleration Power Spectral Density (PSD), relative displacement and Operating Deflection Shape (ODS) analysis. The Adams contact model was also implemented for this case but could not converge to a solution. Improvement in accuracy was observed with Mamba contact simulations compared to simulations which ignored contact, but with the drawback of significantly higher simulation times. / Simuleringar är ett kraftfullt verktyg som används för att minska utvecklingstiden och kostnaderna i fordonsindustrin. De modeller som används i simuleringar är dock förenklingar av verkligheten, och det finns vanligtvis motstridiga krav mellan noggrannhet och beräkningseffektivitet. Fordon är konstruerade med ett stort antal delar sammanfogade med bultar, svetsar och andra skarvar. På dessa platser och andra platser där olika ytor kommer i kontakt kan kontakten ha en avsevärd effekt på delens dynamiska beteende och att fånga denna effekt i simuleringar kan vara svårt på grund av deras olinjära karaktär. Detta examensarbete syftar till att utvärdera olika metoder för att simulera kontakter och deras effekter under dynamiska förhållanden. Examensarbetet har utförts hos Scania, en av de främsta tillverkarna av kommersiella fordon, som har som mål att öka användningen av simuleringar i utformningen av sina fordon för att få bättre konstruktioner med lägre kostnads och tidsinvesteringar. Detta examensarbete använder multikroppssimuleringsprogramvaran Adams Car för att utvärdera två olika kontaktsimuleringsmetoder, en utvecklad av Adams och denna andra är Mamba som är utvecklad av Magna. Mamba definierar ‘Joint interface modes’, som fångar upp deformationen i närheten av kontakten. Kontaktsimuleringen med Mamba jämförs med några av de befintliga simuleringsmetoderna samt fysiska testdata genom att implementera den i fall där kontakt spelar en viktig roll i det dynamiska beteendet. Två sådana fall identifieras som bladfjädern och ram-subramenheten. För blad-fjäder exemplet jämfördes styvhet och energiförlust för Mamba simuleringar med Adams inbyggda multi-balksmodell och fysiska testdata. Styvheten med Mamba-kontaktmodellen stämde bättre överens med testdata, men energiförlusten modellerades bättre med Adams bladfjädermodell. För ram-subramenheten utvärderades effekten av kontaktmoderna i Mamba för slumpmässiga vibrationstest genom att jämföra spektraltätheten för accelerationerna Power Spectral Density (PSD), relativ förskjutning och Operating Deflection Shape (ODS) analys. Adams kontaktmodell implementerades också för detta fall men kunde inte konvergera till en lösning. Förbättring i noggrannhet observerades med Mamba kontaktsimuleringar jämfört med simuleringar som ignorerade kontakt, men med nackdelen med betydligt längre simuleringstider.

Contact simulation

Mamba

Joint Interface Modes

Leaf spring modelling

Frame-subframe contact

ODS analysis

PSD

Kontaktsimulering

Mamba

bladfjädermodellering

ram-subramkontakt

ODS analys

PSD

Vehicle Engineering

Farkostteknik

Einfluss von additiven thermischen Belastungen auf das Langzeitverhalten von stromführenden Schraubenverbindungen mit verzinnten und vernickelten Leitern aus Aluminium und Kupfer in elektrisch angetriebenen Fahrzeugen

Poudeu, F.S.D., Beilner, M., Schlegel, S.

04 June 2024

Zur Stromübertragung innerhalb von elektrischen Komponenten (zum Beispiel in der Batterie) im Fahrzeug werden bevorzugt Stromschienen eingesetzt. Diese werden aus Gründen der Austauschbarkeit und Reparaturfähigkeit über Schraubenverbindungen gefügt. Abhängig von den Leiter- und den Beschichtungswerkstoffen, den Montageparametern und den Belastungsbedingungen im Betrieb altern diese stromführenden Schraubenverbindungen zeitabhängig. Dadurch erhöhen sich der Verbindungswiderstand und die Verbindungstemperatur. Wenn die anwendungsspezifische Grenztemperatur an der Kontaktstelle erreicht ist, kann die Funktion der Schraubenverbindung beeinträchtigt werden oder ein Ausfall auftreten. In diesem Beitrag werden die Einflüsse der Belastungsarten abhängig von den Leiter- und Beschichtungswerkstoffen und von der Montagevorspannkraft auf das Verhalten von Schraubenverbindungen untersucht und gegenüber dargestellt. Darauf aufbauend wird die dominante Belastung hergeleitet. / Busbars are preferred for power transmission within the electrical components (for example in in the battery) in the vehicle. These are connected with bolts for reasons of interchangeability and reparability. Depending on the conductor and coating materials, the assembly parameters and the load conditions during operation, these current-carrying bolted connections age over time. This increases the connection resistance and the connection temperature. If the application-specific limit temperature is reached at the contact point, the function of the bolted connection can be impaired or failure can occur. In this article, the influences of the types of load depending on the conductor and coating materials and the assembly preload force on the behavior of current-carrying bolted connections are examined and compared. Based on this, the dominant load is derived.

info:eu-repo/classification/ddc/620

ddc:620

info:eu-repo/classification/ddc/660

ddc:660

info:eu-repo/classification/ddc/670

ddc:670