general information about the project the aesop project project description objectives partners...
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General information about the General information about the ProjectProject
The AESOP Project
Project Description
Objectives
Partners
Description of Work
Expected Results
Database Information
TIP
List of Work Packages
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Project DescriptionProject Description
Assessment of Energy Saving in Oil Pipelines
Project founded by the EC under the Energy, Environment and Sustainable Development.
Duration: 36 months - 2000/20036 European Partners
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ObjectivesObjectives
To reduce the energy consumption and to increase the transport capabilities of oil pipeline networks
To develope the techniques required to use long-chain polymers as Drag Reducing Agent (DRA) in European oil pipeline networks
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PartnersPartners
Compañía Logística de Hidrocarburos (CLH, S.A.) Société du Pipeline Méditerranée Rhône (SPMR) Energy Solutions (ESI) Asociación para la Investigación y Cooperación
Industrial de Andalucía (AICIA) Fiat Research Centre (CRF) Centre Spatial De Liege (CSL) Société des Transports Pétroliers par Pipe-line
(TRAPIL)
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Description of WorkDescription of Work Experimental studies of the effect on oil product
characteristics when high DRA rates are added.
– laboratory tests and analysis to determine how long -chain polymers can be broken
Large scale experimental studies of the efficiency of long chain polymers on pipeline oil transportation systems with low/high DRA rates.
To obtain a model of how the polymers behave and how the injection rate affects the operation.
To establish a methodology for the use of polymers, considering specific instrumentation and computer aided design programs.
Database design and manteinance with the results of the tests.
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Expected ResultsExpected Results Data base containing experiment data. Set of models and corresponding validation procedures and
validation results. Computer programmes for designing and optimal operation
of oil pipelines using DRA. A prototype of equipment for polymer shearing at oil
pipelines with validation data. An assessment of the effect of DRA on quality of base
products (gasolines and diesel oil) when high DRA rates are added.
Two of the partners’ oil pipelines with the instrumentation and operating procedures required for the use of DRA.
An assessment of the benefits obtained by the technique.
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General General Characteristics of DBCharacteristics of DB
DBMS
Independence between data and
procedures
Availability of the information
Coherent information
Standardised documentation
Quick and simple access
Flexibility
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General General Characteristics of DBCharacteristics of DB
User logic
Global Logic
Physic structure
Conceptual
Logical
Abstract Levels
Data Models Formalisation
E/R Model
Relational Model (FNBCD)
Relational DB hierarchy DB Codasyl DB
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Technological Implementation Technological Implementation PlanPlan The Technological Implementation Plan (TIP) is a specification for the
exploitation of the results of the project. It is concerned with the exploitable potential we have generated and how
we plan to realise that potential. It is to ensure that the maximum number of tangible and intangible results
become available. The Commission's monitoring and evaluation of the exploitation phase of
your project will be based on the TIP so it is an important planning document, not just a deliverable.
A good TIP is the best way to demonstrate to the Commission the value of the results.
It is an active document that can be completed at the start of the project and updated at mid-term and at project completion.
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Technological Implementation Technological Implementation PlanPlan1.- Overview and description of all project and results
(Publishable). It will be used to document the results in CORDIS.
2. -Description of the intentions for dissemination and use by each partner (Confidential)
3.- Search for collaboration through Commission services (Optional, Publishable)
4.- Assessment of the European interests (Publishable). Co-ordinator to explain the interest for the European Union of the achieved results
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List of Work PackagesList of Work PackagesWP nº Work Package Tit le WP Leader Person
monthStartmth
Endmth
Deliverab.nº
WP1 Assessment of effect on fuelperformance for highadditive concentrations
CLH 82,6 0 19
WP1.1 Laboratory analysis of oilproduct specifications withDRA
CLH 19,5 0 6 D1/1.1/1
WP1.2 Laboratory test for polymershearing
CSL 18,6 0 12 D2/1.2/1D3/1.2/2D4/1.2/3
WP1.3 Assessment of effect on enginebehaviour
CRF 19,9 0 19 D5/1.4/1
WP1.4 Assessment of effect oninjectors
CLH 15,1 3 12 D6/1.4/1
WP1.5 Database of fuel performance AICIA 9,5 0 19 D7/1.5/1WP2 Experimental field studies of
flow improversCLH 91,1 0 27
WP2.1 Test Design CLH 4 0 2 D8/2.1/1WP2.2 Conditioning of installations CLH 6 1 4 D9/2.2/1
D10/2.2/2WP2.3 Effectiveness analysis of long
chain polymerCLH 25,5 3 17 D11/2.3/1
WP2.4 Length and DiscontinuityInfluence
CLH 25,2 3 17 D12/2.4/1
WP2.5 Influence on MeasurementEquipment
SPMR 25,4 9 27 D13/2.5/1D14/2.5/2
WP2.6 Database of experimental fieldtests
AICIA 5,0 2 27 D15/2.6/1
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List of Work PackagesList of Work Packages
WP3 Effectiveness modeldevelopment
AICIA 42,9 12 26
WP3.1 Model of Polymers Efficiency AICIA 20,5 12 24 D16/3.1/1D17/3.1/2D18/3.1/3
WP3.2 Model of Polymer Degradation CRF 22,4 12 26 D19/3.2/1D20/3.2/2D21/3.2/3
WP4 Methodology for the use oflong chain polymers
LICENERGY 96 9 36
WP4.1 Simulation and optimisationsoftware requirements
LICENERGY 5,3 9 12 D22/4.1/1D23/4.1/2
WP4.2 Oil Pipeline Simulat ionPackage
LICENERGY 31,6 12 32 D24/4.2/1D25/4.2/2D26/4.2/3
WP4.3 Algorithms for Installat ionDesign
LICENERGY 22,0 19 33 D27/4.3/1D28/4.3/2
WP4.4 Algorithms for OptimalOperation
AICIA 23,5 19 33 D29/4.4/1D30/4.4/2
WP4.5 Integration of simulation andoptimization software
LICENERGY 5,5 33 35 D31/4.5/1D32/4.5/2
WP4.6 Guidelines for the use of long-chain polymers and resultdissemination
SPMR 8,2 34 36 D33/4.6/1D34/4.6/2D35/4.6/3D36/4.6/4
WP5 Project Management CLH 3 0 36
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WP1:Assessment of effect on fuel performance for high additive concentrations
WP2:Experimental field studies of flow improvers
WP3:Effectiveness model development
WP4:Methodology for the
use of long chain polymers
WP
5: Project M
anagem
ent
Partner’s Previous Experience
WP Global StructureWP Global Structure
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1.2 Laboratory test for polymer shearing
1.1 Laboratory analysis of oil product
specifications with DRA
WP2
WP 1 Assessment of effect on fuel performance for high additive concentrations
1.3 Assessment of effect on engine
behaviour
1.4 Assessment of effect on injectors
1.5 Database of fuel performance
WP1WP1
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WP3, WP4
WP1
WP2 Experimental field studies of flow improvers
2.1 Test Design 2.2 Conditioning of installations
2.3 Effectiveness analysis of long chain polymer
2.4 Length and Discontinuity
Influence
2.5 Influence on Measurement
Equipment
2.6 Database of experimental field
tests
WP2WP2
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3.1 Model of
polymer efficiency3.2 Model of
polymer degradation
WP3 Effectivity model development
WP4WP1, WP2
WP3WP3
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WP4WP4
4.2 Pipelinesimulation package
4.3 Installationdesign algorithms
4.4 Optimaloperation algorithm
WP4 Methodology for the use of polymers
4.6 Guidelines for theuse of polymers
WP1WP2WP3
4.1 Softwarerequirements
4.5 Softwareintegration
WP1WP2WP3
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Deliverables IDeliverables IDeliverable
No.Deliverable Title Deliverable
DateRespons.
D1/1.1/1 Document with laboratory analysis results 7 CLHD2/1.2/1 Report with polymer shearing results. 13 CSLD3/1.2/2 Prototype of ultrasonic shearing equipment 13 CSLD4/1.2/3 Set of recommendations about polymer shearing 13 CSLD5/1.3/1 Document with effect on engine results. 13 CRFD6/1.4/1 Document with effect on injectors 13 CLHD7/1.5/1 Database of fuel performance results 15 AICIAD8/2.1/1 Document describing the set of experiments 3 CLHD9/2.2/1 Working experimental sites 5 CLH
D10/2.2/2 Documents with modifications in the systems 5 CLHD11/2.3/1 Document with polymer effectiveness tests and results 18 CLHD12/2.4/1 Document with flow improvers degradation tests and results. 18 CLHD13/2.5/1 Document with measurement equipment influence test and
results28 SPMR
D14/2.5/2 Documents with a set of calibrating instructions 28 SPMRD15/2.6/1 Database of experimental field results 28 AICIAD16/3.1/1 Effectiveness model validated by experiences 25 AICIAD17/3.1/2 Document describing the effectiveness model 25 AICIAD18/3.1/3 Document with the effectiveness model validation procedure
and validation results.25 AICIA
D19/3.2/1 Polymer degradation model validated by experiences 27 CRFD20/3.2/2 Document describing the polymer degradation model 27 CRF
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Deliverables IIDeliverables IIDeliverable
No.Deliverable Title Deliverable
DateRespons.
D21/3.2/3 Document with the polymer degradation model validationprocedure and validation results
27 CRF
D22/4.1/1 Document with users and global specifications 13 LICENER.D23/4.1/2 Document with a software quality plan 13 LICENER.D25/4.2/1 CAD package with the oil pipeline simulation software 33 LICENER.D25/4.2/2 Test and validation report with validation results 33 LICENER.D26/4.2/3 Oil pipeline simulator users’ guide 33 LICENER.D27/4.3/1 Software package for installation design 34 LICENER.D28/4.3/2 Installation design software users’ guide 34 LICENER.D29/4.4/1 Software for optimal operation of oil pipeline systems using
flow improvers34 AICIA
D30/4.4/2 Optimal operation software users’ guide 34 AICIAD31/4.5/1 Report with software integration results 36 LICENER.D32/4.5/2 Reports containing validation procedure and results 36 LICENER.D33/4.6/1 Document with guidelines for an optimal use of polymers in
oil pipelines36 SPMR
D34/4.6/2 Technical requirements of specific equipment andinstrumentation
36 SPMR
D35/4.6/3 Web node with the main public results of the project 36 SPMRD36/4.6/4 Document with the main public results of the project 36 SPMRD37/TIP/1 Draft Version of the Technological Implementation Plan 18 ??D38/TIP/2 Final Version of the Technological Implementation Plan 36 ??
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MilestonesMilestonesTYPE NAME TIMING
(month )ASSESSMENT CRITERIA
Kick off M1 0Technical M2 5 Tests designed and installations conditionedTechnical M3 13 Tests for polymer shearing and assessment of effect
on injectorsAnnual Report 1 M4 13 Review of the progress project during the first yearTechnical M5 18 Assessment on effectiveness of DRA and length and
discontinuity influenceTechnical M6 20 Assessment of effect on engine behaviourAnnual Report 2 M7 25 Review of the progress project during the second
yearTechnical M8 27 Models of polymers efficiency and degradationTechnical M9 28 Assessment of influence on measurement equipmentTechnical M10 29 Software developed and integratedFinal review M11 36 Optimisation algorithm and methodology to operate
pipelines using flow improvers.
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ConclusionsConclusions
•Expected results:
*reduction of more than 25 % in the energy required for ton-km of the base products.
*increase in the capacity of more than 30 % in terms of ton-km.
•Reduction of the price of energy: this will contribute towards the competitiveness of the oil pipeline partners.
•An important social benefit can be obtained combating the saturated European road and highway system.
EXIT