Reduction at source of V-type Diesel engines’ vibrations

Add to my library

BM2610 V1 Quizzed article

Reduction at source of V-type Diesel engines’ vibrations

Author : Béchir MOKDAD

Publication date: April 10, 2018, Review date: October 23, 2020 | Lire en français

Add to my library Add to my library

Logo Techniques de l'Ingenieur You do not have access to this resource.
Request your free trial access! Free trial

Already subscribed?

Overview

ABSTRACT

Controlling the dynamic behavior of internal combustion engines has been gaining importance in industry in recent years. Non-controlled dynamic deformation can result in premature fatigue of components and repetitive failures, with costly downtime. This article reviews the architectural parameters of multi-cylinder V-engines that allow the reduction, at source, of the vibrations of these machines and thereby minimize failures. This can be integrated in a firing sequence optimization procedure, where numerous aspects are evaluated by means of indicators.

Read this article from a comprehensive knowledge base, updated and supplemented with articles reviewed by scientific committees.

Read the article

AUTHOR

  • Béchir MOKDAD : Engineer from the National Engineering School of Tunis (ENIT) – Tunisia - Doctorate in Mechanics, Energy and Engineering from the Institut National Polytechnique de Grenoble (INPG) – France - Group Manager Mechanical Calculations – Liebherr-Components Colmar SAS, France

 INTRODUCTION

The development of modern diesel engines is characterized by a constant trend towards increasing specific power and efficiency. To meet these demands, the peak combustion pressure increases with each new engine generation (250 bar is the current state of the art, compared with 150 bar in the early 90s). Consequently, the reliability and durability of basic components such as the crankshaft are constantly being improved to keep pace with this trend. These technical challenges are compounded by increasingly stringent requirements in terms of pollutant emissions, low fuel consumption and economic return on investment.

Faced with this demanding technical and economic context, the development of high-performance internal combustion engines requires good control of the vibration behavior and durability of the various components, while minimizing their oversizing. With the considerable progress made in numerical simulations, this requires a number of parameters and aspects to be taken into account right from the start of the project. One of the major aims of this development phase is, if possible, to reduce motor vibration at source, as it can potentially come from multiple sources, manifest itself in many forms and, above all, cause numerous problems during operation. The essential aim of this article is to present the key parameters of the architecture of V-type internal combustion engines with up to 24 cylinders. Unlike in-line engines and small V-engines, the state of the art for engines with more than 12 cylinders is much less mature. What's more, there are a number of little-known or little-analyzed phenomena, which can be overcome by reference to experience or, indeed, by means of relatively comfortable safety factors.

This work mainly concerns 4-stroke diesel-cycle internal combustion engines running at high rotational speeds up to 15 m.s- 1 mean piston speed. These engines are equipped with turbochargers enabling them to achieve mechanical power ratings of up to 5 MW, making them suitable for a wide range of applications, including marine, mining and stationary applications such as generator sets. To avoid restricting ourselves to this range of engines, many of the phenomena explained in this work can also be generalized to gasoline engines, gas engines, 2-stroke engines and naturally aspirated engines.

At the end of the article, readers will find a glossary and a table of symbols used.

You do not have access to this resource.
Logo Techniques de l'Ingenieur

Exclusive to subscribers. 97% yet to be discovered!

You do not have access to this resource. Click here to request your free trial access!

Already subscribed?


KEYWORDS

V-angle   |   crankstar   |   firing sequence   |   inner bending   |   thermodynamic performances   |   axial resonance

Ongoing reading
Reduction at source of V-type Diesel engines’ vibrations

Article included in this offer

"Hydraulic, aerodynamic and thermal machines"

( 177 articles )

Complete knowledge base

Updated and enriched with articles validated by our scientific committees

Services

A set of exclusive tools to complement the resources

View offer details

Dans les ressources documentaires

Transmissions dans l’automobile - Bruits et vibrations des transmissions latérales

Les transmissions latérales d’une automobile, qui comprennent un joint homocinétique côté boîte de vitess...

Transmissions dans l’automobile - Contribution aux bruits et vibrations dans l’habitacle des véhicules

Le bruit et les vibrations du moteur perçu dans l’habitacle d’un véhicule passe par différents éléments, ...

Phénomènes fondamentaux des vibrations des moteurs d’automobile

La gestion des vibrations du groupe motopropulseur (GMP) est un enjeu qui ne peut être négligé quand sont...

Essais des moteurs automobiles - Moyens de mesure

Un banc d'essais est un ensemble de matériels installés dans un endroit insonorisé et permettant de repro...

Tous les livres blancs
Article Une soufflerie pixellisée pour drones
19 March 2020
Une soufflerie pixellisée pour drones

Pour tester la résistance des drones à tous types de vents, tels les rafales, les tourbillons ou encore les cisaillements, l\'HEPIA développe un centre de tests...

Toutes les actualités
Contact us