WORKPACKAGE 3 Economic aspects

1. AWAST WP 3 • WORKPACKAGE 3 • Economic aspects

2. AWAST WP 3 • Participants • Cemagref (France)Water and environmental engineering departmentResearch Unit : Livestock and municipal wastes Management – Rennes • Universitaet Stuttgart (Germany) • Institute for Sanitary Engineering, Water Quality and Waste Management : ISWA

3. AWAST WP 3 • Objectives •  Providing the economic aspects of the decision support system which will help decision makers to know which kind of system should be developed, respective of the local conditions. •  A more accurate undestanding and control of municipal waste management service costs will be available and proposed to decision-makers. •  Help waste management authorities maximize long term efficiency of MSW management system by minimizing its costs.

4. AWAST WP 3 • Work description •  Task 1 : state of the art and data acquisition(Month 3 to 24) •  Task 2 : definition of production cost models(Month 6 to 14) •  Task 3 : calibration and validation of the models(Month 13 to 19)

5. Thematic approach by facility - MSW Operations WP 4 WP 5 WP 6 Collection Sorting Landfill BiologicalTreatment ThermalTreatment Data acquisition (production factors : Quantity, Unit costs) Production costs by facility

6. Economic modelling Inputs Outputs FacilityDirect costs Revenues(compost, energy, sale materials) MSW • Production factors • Operating : - Labour - Energy - Supplies • Maintenance Residustreatment Diagram of economics models

7. Definition of components costs • Bibliography • Cases studies • Questionnairesurvey • Mathematical modelling (writing) • Mathematical equations estimated Methodology of modelling costs Phase 1 Phase 1 Phase 1

8. Flowsheet of economic evaluation Capital cost CK Product sales revenue : S Q : Flow waste 1 Treatment plant CN Nominal capacity(tph, tpd, tpy) Operating costs Co 3 2 - Labour : L- Energy : E- Reagents : R- Maintenance : M 4 5 6 Residues disposal : D

9. Estimation of capital costs •  Direct plant costs (DPC)  Indirect plant costs (IPC) • (Equipment costs) (Land, start- up, supervision) • (Building and civil works costs) • Total capital cost = CI = DPC + IPC • CI = Fonction (CN, process) • Existing models costs Model cost Data acquisition on plants • and actualisation • Annual capital cost = Ck = CI /T T : life plant • /

10. Capital cost of incineration plant CI = 275,7 x CN + 18 277 000 CN : tpy CI : in euros h t Source data : France : 15 plants Norway : Trondheim Austria : Vienna

11. Estimation of operating costs • Factor method : relation between component costs and basic variables • Co = fonction (CN, Q, process) • Co = aL + bE + cR + d.IE • L : direct labour costs L, E, R, IE : basic variables • E : energy costs • R : reagent costs • IE : equipment costs a, b, c, d, : processing factors are summed • d. IE : maintenance costs

12. Incineration : decomposition of the operating costs(Dry scrubber) Operating cost model Co = F + P + M – Sor Co = (1,36 x L + 0,005 x IE) + 1,10 x R + (0,023 x IE + 20 x Q) – 620 x PU x Q

13. Incineration : symbols explanation

14. Standards et variables locales

15. TYPES OF MRFs • (1) Design capacity is determined for 3 000 hours per year running • (2) Type 4 is particular to american regions Trondheim - 20/21 June 2002 - Cemagref - ISWA

16. MRFCAPITAL COSTS • Methods for fixed-capital cost estimation • 1st method : • CFC = k. IEC • 2nd method : • CFC = h. CN, , h is a cost in € / 1000 t/y IEC, the installed equipment cost, can be: • calculated as a sum of equipment items costs, IEC = ΣiIECi • estimated as IEC = f. CN , f is a cost in € / 1000 t CN is the design capacity. Trondheim - 20/21 June 2002 - Cemagref - ISWA

17. MRF OPERATING COSTS • Methods for operating costs estimation: • 1st method : CO= k (α. L + β. CFC) • 2nd method : CO=λ L k is > 1, it accounts for overhead expenses α. L represents Direct Cost, that includes Labour, utilities and repairs β. CFC represents Maintenance This method is used when no sufficient data are available (types 3,4) L is labour cost, it depends on type of MRF and number of shifts per day. L= Σk wklk where k= sorters, conductors, foreman, etc. l = number of k workers w = unit cost of a k worker Trondheim - 20/21 June 2002 - Cemagref - ISWA

18. AWAST Flowsheet to calculate the collection cost WP3 WASTE STREAM TECHNICAL ANALYSIS LOCAL AUTHORITIES COST ANALYSIS Residual waste Dry recyclables Biowaste Collection data France / Germany Waste collection on area Collection data by collection system Crew efficiency Rc = f (CL) Waste quantity Qs Components costs by data processing Vehicle efficiency Requirements : vehicles crews containers Collection cost model Cp = Cc + Co TOTAL PRODUCTION COST UNIT PRODUCTION COST (per waste stream) Trondheim - 20/21 June 2002 - Cemagref - ISWA 1

19. AWAST Cost determining factors WP3 Trondheim - 20/21 June 2002 - Cemagref - ISWA 2

20. AWAST Work time and number of trips to facility assessments WP3 • 1. Definition of the work time per day : • Tc : collection available time • Tj = Tc + (Nt x Th) + Tb Th : haul time • Tb : break time • 2. Definition of the work per week and per year : • T =  Tj = j x Tj(France : T = 5 x 7 = 35) • 3. Number of trips per day determination : • Nt = Tc / TvTv : vehicle loading time Trondheim - 20/21 June 2002 - Cemagref - ISWA 3

21. AWAST The different collection systems WP3 Trondheim - 20/21 June 2002 - Cemagref - ISWA 4

22. Crew efficiency graphs AWAST WP3 KERBSIDE COLLECTION BRING COLLECTION Emptying rate : t = emptying time / container (2 - 6 min) Qj = Re x Tc Rc = f (CL) Trondheim - 20/21 June 2002 - Cemagref - ISWA 5

23. AWAST Model of waste collection cost WP3 • Capital cost : CC = Iv / d • Operating cost : CO • Production cost : • CP = CC + CO • Wages :L = Σ lk wk • Energy : E = Ce  Dy Collection follow-ups : determination of , ,  Trondheim - 20-21 June 2002 - Cemagref - ISWA 6

24. AWAST PRODUCTION COSTS WP3 • COLLECTION :CP= 1.7572  L + 1.287  E + (0.0805+1/d)  Iv • Take into account the utilization rates for : • - the vehicle : d = (35  7) / (Tj  j) • - the crew : full-time : L • share-time : L1, L2 L1 + L2 = L • under-time : L  [ T / (Tj  j)] • PRECOLLECTION : C’P = Nw  I’r (2’+ 1/n’) • required containers / week / crew: Nw = (Nj  j) / f = (Nr  Nt  j) / f Trondheim - 20/21 June 2002 - Cemagref - ISWA 7

25. AWAST Example of collection costs calculation WP3 • Hypothesis : - vehicle : Vv ; n = 7 ; Nt = 1 • - crew : full-time work ; Rc • - one waste stream of annual quantity : Qs • - number of vehicles = number of crews = Ns • Collection data : • Equipment / crews required : - collection time : Ts = Qs / (52 x j x Rc) • - number of crews : Ns >= Ts / Tc • Annual production cost :Cp = .Ns.L + .Ce.Dy + .Ns.Iv Trondheim - 20/21 June 2002 - Cemagref - ISWA 8

26. AWAST WP 3 Global approach – Integrated MSW management Local Authority Collections SortingComposting Incineration Landfill General administrationExecutive oversight + Direct costs Indirect costs Full cost of MSW Service

27. AWAST WP3 Materials flow’s synoptic : the case of Orléans OM 93 568,07 Déchetteries 51 252,61 Eaux traitées 495,41 Tout venant 14 961,65 OM tri 5 001,24 OMR 79 347,4 DEM 1 500,53 JM 7 718,9 Verre 6 083,89 DAS 2 161,98 DIB 3 942,72 Graisse 669,28 Gravats 16 186,49 ? 40 79 347,4 Papiers 874,56 Compostage 5 001,24 Refus = 1 899,66 Incinération 2 161,98 + 3 942,72 +133,87 = 7 238,57 Centre de tri sélectif ? 1 300,21 Cartons 1 313,6 Refus = 261,45 Evaporation 1 101,08 Verre 6 083,89 Végétaux 14 175,01 4 356,44 val. Papier 4 628,48 Verre 849,379 Acier 2 824,82 2 824 val. 272,04 stocks Ferrailles 2 503,46 Al 47,82 Carton et Tetra-pack 2 168,1 1 908,93 val. 47,82 val. Compost 2 000,5 259,16 stocks Plastiques 23,8 Energie 35 254 MWh 28 944 à EDF 6 310 MWh auto-consommation Flaconnages plastics 578,76 477,75 val. Huiles 120,07 101,01 stocks REFIOM 1 414,08 Mâchefers 20 289,52 Pneus 55,6 494,04 val. Acier 526,42 -3 192,48stocks 32,38 stocks CET1 Maturation 20 289,52 Batteries 34,66 23 482 val. Al 17,46 14,24 val. 3,52 stocks D.M.S 154,33 Trondheim -20/21 June 2002 - Cemagref

28. AWAST WP3 Method of knowledge costs Illustration with the thermal path Waste collection Q1 Activity Other authorities Q2 Incineration plant Q1+Q2 A Local authority B C Stream Level Boundaries Costs A Plant Production cost by activity B Stream Production cost by stream C Local authority Providing cost of local authority Fly Ash Landfill 1 Bottom Ash Landfill 2 Trondheim -20/21 June 2002 - Cemagref

29. AWAST WP3 Production cost per activity (Level A) : the case of Orléans, year 2000 Trondheim -20/21 June 2002 - Cemagref

30. AWAST WP3 Cost per path or stream (level B) : the case of Orléans (France), year 2000 Trondheim -20/21 June 2002 - Cemagref

31. AWAST WP3 Full cost providing for local authority (level C) : the case of Orléans, year 2000 Trondheim -20/21 June 2002 - Cemagref

32. AWAST SCIENTIFIC ACHIEVEMENTS WP3 Trondheim - 20 - 21 June 2002 - Cemagref

33. AWAST PROBLEMS ENCOUTERED WP3 • Requirements : availableactual data, updated data, updatable data • Modelling waste collection : limited to main waste stream(residual, packaging, biowaste) • Sorting, composting : necessary to define a typology of the technologies • Landfill, anaerobic digestion : available data from only litterature review • Full cost : identification of indirect costs components on case studies • Difficulty to obtain data : in spite of the achievement of questionnaire of collection data ( operating plant by private firms ) • Deliverable D6 ( Methodology ) : we have a delay on the deliverable D6 (provisional draft) • Full cost of the service : will be achieved in year 3 (with the analysis of case studies) Trondheim - 20 - 21 June 2002 - Cemagref 7

34. AWAST ECONOMIC ASPECTS - FOR THE NEXT 6 MONTHS WP3 • Collection : validation of the model of waste collection with data of Stuttgart ( urban area) • Composting : data costs collection in France, Portugal, Germany ( in waiting) • : Modelling production cost • Landfill and transfer station : modelling production cost( with litterature review ) • Deliverable D6 : achievement the writing «  Methodology of production cost models and the full cost providing by local authority » • Beginning the transfer of models for WP7 ( integration simulator) • Beginning the determination of the full cost on case studies : • ( Orleans with BRGM, Lisbon with LQARS, Stuttgart with USTUTT ) Trondheim - 20 - 21 June 2002 - Cemagref 7