A Two-Stage Variable Compression Ratio System for Large-Bore Engines with Advanced Hydraulic Control Circuit and Mechanical Locking Device

A Two-Stage Variable Compression Ratio System for Large-Bore Engines with Advanced Hydraulic Control Circuit and Mechanical Locking Device

In order to meet upcoming emission targets, an increasing number of ships using Liquefied Natural Gas (LNG) as fuel have been put into service. In this context, many shipowners are particularly interested in the dual-fuel (DF) large-engine technology, which enables ships to operate with both gaseous...

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Veröffentlicht in:SAE International journal of engines 2022-01, Vol.15 (2), p.247-262, Article 03-15-02-0011
Hauptverfasser: Marten, Christopher, Pendovski, Denis, Pischinger, Stefan, Bick, Werner
Format: Artikel
Sprache:eng
Schlagworte:
Alternative fuels
Circuits
Combustion
Conrod
Design
Diesel fuels
Dual fuel
Engines
Equipment and supplies
Hydraulic
Hydraulic control
Large bore engine
Layouts
Liquefied natural gas
Liquid fuels
Locking
Marine
Marine engines
Methods
Properties
Shipping
Ships
Simulation
Variable compression ratio
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container_issue 2
container_start_page 247
container_title SAE International journal of engines
container_volume 15
creator Marten, Christopher
Pendovski, Denis
Pischinger, Stefan
Bick, Werner
description In order to meet upcoming emission targets, an increasing number of ships using Liquefied Natural Gas (LNG) as fuel have been put into service. In this context, many shipowners are particularly interested in the dual-fuel (DF) large-engine technology, which enables ships to operate with both gaseous and conventional liquid fuels. The use of different combustion principles in DF engines requires a layout of the base engine with a relatively low compression ratio (CR) for the gas mode to prevent unstable combustion (knocking). However, this layout leads to disadvantages in the Diesel operation mode, which requires a higher CR for optimal fuel efficiency. Therefore, a two-stage variable compression ratio (VCR) system is a technology particularly suitable for DF engines. It allows to reduce fuel costs by approximately 5.5%. This article presents an innovative VCR connecting rod (conrod) design for modern DF engines that adapts the piston position by changing the effective conrod length. The VCR system is developed by the Institute for Combustion Engines of the Rheinisch-Westfälische Technische Hochschule (RWTH) Aachen University together with Forschungsgesellschaft für Energietechnik und Verbrennungsmotoren (FEV) Europe GmbH. It is equipped with a novel functional principle inside the conrod’s small eye specifically tailored to large engine boundary conditions. The system includes an advanced hydraulic circuit combining the function of a hydraulic freewheel, the oil supply for piston cooling, and a mechanical locking device (LD) for both CRs. In a comprehensive simulation study, the layout and the system behavior of the new hydraulic circuit are presented using a one-dimensional (1D) hydraulic-mechanical simulation model, which was validated in advance with measurement data from a passenger car (PC) engine. The study intends to examine the functional behavior of the VCR system during engine operation. The focus is on the switching process between the two CRs, as well as on the fixed CR operation. The aim is to provide a deeper understanding of the hydraulic-mechanical behavior and to identify special requirements on the system.
doi_str_mv 10.4271/03-15-02-0011
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identifier ISSN: 1946-3936
ispartof SAE International journal of engines, 2022-01, Vol.15 (2), p.247-262, Article 03-15-02-0011
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1946-3944
1946-3944
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recordid cdi_proquest_journals_2642109167
source Jstor Complete Legacy
subjects Alternative fuels
Circuits
Combustion
Conrod
Design
Diesel fuels
Dual fuel
Engines
Equipment and supplies
Hydraulic
Hydraulic control
Large bore engine
Layouts
Liquefied natural gas
Liquid fuels
Locking
Marine
Marine engines
Methods
Properties
Shipping
Ships
Simulation
Variable compression ratio
title A Two-Stage Variable Compression Ratio System for Large-Bore Engines with Advanced Hydraulic Control Circuit and Mechanical Locking Device
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