Waste Management Planning in Two Areas of

Middle and South of Italy, based on

Material and Substance Flow AnalysisUmberto ARENA a,b and Fabrizio Di Gregorio a,b

a Department of Environmental, Biological and Pharmaceutical Sciences and Technologies – Second University of Naples, Caserta, ITALY

b AMRA s.c.a r.l. – Analysis and Monitoring of Environmental Risk, Napoli, ITALY

A SUSTAINABLE WM PLANNING

The decision making process over WM policy is a complex issue, which has to evaluate the environmental impacts, the technical aspects, the implementation and operating costs of each specific treatment and disposal option as

well as the social implications. The process often involves accurate as well as missing data, expert evaluations as well as ill-defined and changing public opinions, and sometimes it is guided by preconceptions for or against a specific WM solution.

The complexity of this framework greatly raised in the last two or three decades, as a consequence of increasing generation and complexity of solid wastes.

11 Elements

15 Elements

60 Elements

Growing complexity of goods (and waste) composition (e.g. information products)

Source: T. McManus, Intel

Corp., 2006 (Courtesy T. Graedel)

INTRINSIC TROUBLES for SUSTAINABLE RECYCLING

A SUSTAINABLE WM PLANNINGA comprehensive and systemic, goal-oriented approach is needed to design an integrated and sustainable WM system. There is a general accordance about the final goals:

i) protection of human health and the environment;

ii) conservation of resources, such as materials, energy, and land;

iii) after-care-free waste management, meaning that neither landfills nor WtE, recycling or other treatments leave problems to be solved by future generations;

iv) economic sustainability of the whole cycle of MSW management, also in a welfare economy perspective.

In this framework of increasing generation and complexity of solid waste composition, the combination of two valuable tools, the MFA and the SFA, together with an environmental assessment method such as LCA, can efficiently support waste management decisions on both strategic and operating levels.

In particular, it is greatly attractive the SFA ability to connect sources, pathways, and intermediate and final sinks of each chemical species in a specific process, as demonstrated by its utilization in the assessment of thermal treatments, recycling options and waste management scenarios.

A SUBSTANCE ORIENTED APPRAOCH

System definition

On site data and waste process data

(waste amount and composition,

air and water emissions,co-products, etc.)

Technical tools (material balances,

energy balance, allocation models, etc.)

Analytical tools

Material Flow Analysis

Substance Flow Analysis

Life Cycle AnalysisLife Cycle Costing

Health RAEnvironmental RAWM Planning

AIM of the WM PLANNING PROCEDURE

WASTE MANAGEMENT SCENARIOS

and INPUT DATA

The waste management system is defined and developed according to:

1. minimize use of landfill and ensure that no waste that is biologically active or that contains mobilizable hazardous substances is landfilled

2. minimize operations entailing excessive consumption of raw materials and energy without yielding a real environmental advantage

3. maximize recovery of materials4. maximize energy recovery, given that, in a LCA approach, energy recovery from waste allows decreasing consumption of fossil fuels and of overall emissions with respect to all energy conversion systems.

A SCENARIO ANALYSIS

WM systems that are operating successfully worldwide demonstrated that:• no one process is suitable for all waste streams• no single waste management practice can handle

the full array of waste types. The defined WM scheme should then utilize each of the fundamental waste management options for the extent that is adequate to the specific catchment area characteristics and compatible with the technical, economic and environmental performance of the

specific option. They should include only technologies that are state-of-the-art and have already proven high reliability and sustainability, with known total costs for treatment and aftercare.

A SCENARIO ANALYSIS

THE MSW WM SCHEME

MSW COMPOSITION

MSW composition

% C, % Cl, % F, % H, % O, % N, % S, %Cd,

mg/kgCr,

mg/kgHg,

mg/kgPb,

mg/kgash,

%moisture, %

LHV, MJ/kg

Organic fraction 35.0 15.49 0.20 0.00 2.51 13.62 0.76 0.03 1.80 12 0.057 11 4.89 62.49 4.85

Paper 25.0 30.97 0.11 0.00 4.65 34.07 0.37 0.03 1.90 25 0.047 11 7.80 22.00 10.84

Glass 6.0 0.43 0.03 0.02 0.01 1.08 0.87 0.13 2.60 370 0.007 430 96.43 1.00 -0.02

Plastics 15.0 60.61 0.67 0.00 9.29 8.21 0.72 0.04 16.00 120 0.072 170 6.45 14.00 25.63

Metals 3.0 0.42 0.18 0.01 0.02 0.83 1.04 0.08 4.40 800 0.23 2300 96.43 1.00 -0.02

Aluminum 1.0 0.42 0.18 0.01 0.02 0.83 1.04 0.08 0.95 80 0.26 37 96.43 1.00 -0.02

Wood and textiles 4.0 39.32 0.05 0.00 5.14 33.16 1.53 0.08 2.25 197.5 0.027 220.5 2.74 18.00 14.92

Bulky waste and WEEE 11.0 21.97 0.52 0.00 3.56 16.74 0.94 0.14 57.00 630 1.8 460 23.63 32.50 8.06

TOTAL 100.0 26.29 0.27 0.00 4.03 17.78 0.73 0.05 10.2 152.7 0.3 186.7 17.0 33.9 9.7

THE THREE MSW WM SCENARIOS

Waste fractions Organic fraction Paper Glass Plastics Metals Aluminum Wood +

Textiles Bulky waste

and WEEE Total

in MSW, % 35.0 25.0 6.0 15.0 3.0 1.0 4.0 11.0 100

SCENARIO SSL 35%Interception Efficiency, % 40.0 44.0 55.0 25.0 30.0 30.0 15.0 10.0 35%Separate Collection Waste, t/d 140.0 110.0 33.0 37.5 9.0 3.0 6.0 11.0 349.5

Unsorted Residual Waste, t/d 210.0 140.0 27.0 112.5 21.0 7.0 34.0 99.0 650.5

SCENARIO SSL 50%Interception Efficiency, % 65.0 50.0 65.0 45.0 35.0 35.0 20.0 17.5 50%Separate Collection Waste, t/d 227.5 125.0 39.0 67.5 10.5 3.5 8.0 19.3 500.3

Unsorted Residual Waste, t/d 122.5 125.0 21.0 82.5 19.5 6.5 32.0 90.8 499.7

SCENARIO SSL 65%Interception Efficiency, % 80.0 65.0 90.0 60.0 55.0 55.0 25.0 28.2 65%Separate Collection Waste, t/d 280.0 162.5 54.0 90.0 16.5 5.5 10.0 31.0 649.5

Unsorted Residual Waste, t/d 70.0 87.5 6.0 60.0 13.5 4.5 30.0 79.0 350.5

THE COMPOSITION of SSC and URW

SSC: Source Separation and Collection

URW: Unsorted Residual Waste

MFA and SFA of

WM OPTIONS

RECYCLING CHAIN – sorting&recycling residues

MSW fractions

SSL 35% SSL 50% SSL 65%

SR, % RR, % SR+RR, % SR, % RR, % SR +RR, % SR, % RR, % SR +RR, %

Organic fraction 20.0 9.7 25.7 22.0 9.7 27.6 24.0 9.7 29.5

Paper 5.0 11.0 15.4 6.5 11.0 16.8 8.0 11.0 18.1

Glass 6.0 0.0 6.0 14.0 0.0 14.0 16.0 0.0 16.0

Plastics 35.0 25.5 51.6 40.0 25.5 55.3 44.0 25.5 58.3

Metals 6.0 9.5 14.9 6.0 9.5 14.9 6.0 9.5 14.9

Aluminum 15.0 16.5 29.0 15.0 16.5 29.0 15.0 16.5 29.0

Wood and textiles 13.5 5.0 17.8 13.5 5.0 17.8 13.5 5.0 17.8

Bulky waste and WEEE 10.0 10.0 19.0 12.0 12.0 22.6 14.0 14.0 26.0

TOTAL 14.7 9.5 22.8 19.0 9.8 27.0 20.9 9.9 28.8

RECYCLING CHAIN MFA for plastic, metals and aluminium

RECYCLING CHAIN MFA for paper

INTEGRATED AD TREATMENT MFA for organic fraction

THERMAL TREATMENT Combustion MFA for unsorted residual waste

THERMAL TREATMENTGasification MFA for unsorted residual waste

THERMAL TREATMENT Combustion and Gasification SFA for zinc element

MFA and SFA of

ALTERNATIVE WM SCENARIOS

MFA of WM SCENARIOS

MFA of WM SCENARIOSScenario  SSL 35% SSL 50% SSL 65%Mass of Waste to Landfill, % entering MSW      from sorting&recycling chain 0.7 1.2 2.20from biological treatment 3.6 6.3 8.2from thermal treatment 17.0 13.8 10.7

Total 21.3 21.3 20.9Volume of Waste to Landfill, m3/d (% entering MSW)      from sorting&recycling chain 10.8 20.3 32.8from biological treatment 60.0 104.7 137.5from thermal treatment 101.4 82.4 64.0

Total 172.2 (8.3)

207.4 (10.0)

234.3 (11.2)

Energy Net Production, GWh/y      Electric energy 125.8 108.1 92.4Thermal energy (in cogeneration) 312.9 264.6 210.8

Total 438.7 372.7 303.2Lost and Available Feedstock Energy, GWh/y (% entering waste energy)

converted in electric and thermal energy 770.3

(78.1) 691.1 (70.1)612.5

(62.1)lost in landfill 44.6 (4.5) 68.5 (6.9) 84.9 (8.6)Recovered Materials, t/d (% entering MSW) Glass 31.0 33.5 45.4Plastics 19.5 32.5 41.2Metals 12.8 17.6 27.8Aluminum 2.7 3.4 5.3Paper 93.0 104.0 133.1

Textiles 2.5 3.3 4.1Wood 4.2 6.2 8.7Compost 24.3 38.5 46.1

Total 190.0

(19.0) 239.0 (23.9)311.7

(31.2)

WM SCENARIOSfeedstock energy analysis

6.9%

70.1%

23.0%

SFA of WM SCENARIOS – C analysis

8.4%

68.4%

23.1%

SFA of WM SCENARIOS – C analysis

Scenario SSL 35% SSL 50% SSL 65%Carbon to Landfill, t/d (% input C)

from sorting&recycling chain 0.8 (0.3) 1.4 (0.5) 2.2 (0.8)

from biological treatment 11.0 (4.2) 18.3 (7.0) 23.0 (8.7)

from bottom ash 2.0 (0.8) 1.7 (0.6) 1.5 (0.6)

from APC residues 0.9 (0.3) 0.8 (0.3) 0.7 (0.3)Total 14.7 (5.6) 22.2 (8.4) 27.4 (10.4)

The amount of greenhouse gas is reduced as a consequence of high recycling rates (which in turn depend on the SSL and the best practices of separate

collection and recycling process): the carbon that is reutilized in the form of compost (from integrated biological treatment), polymers (from plastic recycling chain) and cellulose (from paper recycling chain) is not landfilled and will not contribute to greenhouse gases.

The energy produced by thermal treatment and, for a lesser extent, by the AD process, replaces other energy sources so consequently reducing the related environmental burdens. Moreover, about a half of the energy produced by WtE and AD plants derives from non fossil fuels, and then does not contribute to climate change.

SFA of WM SCENARIOS – Cd analysis

Cadmium to Landfill, g/d (% input Cd) SSL 35% SSL 50% SSL 65%

from sorting&recycling chain 898 (8.9) 1,577 (15.6) 2,536 (25.1)

from biological treatment 249 (2.5) 405 (4.0) 499 (4.9)

partial total 1,147 (11.4) 1,983 (19.6) 3,035 (30.0)

from bottom ash 831 (8.2) 721 (7.1) 589 (5.8)

from APC residues 7,477 (74.0) 6,488 (64.2) 5,293 (52.4)

Total 9,455 (93.6) 9,193 (91.0) 8,917 (88.3)Cadmium in recycled product, g/d (% input Cd)

Glass 81 (0.8) 87 (0.9) 118 (1.2)

Plastics 312 (3.1) 521 (5.2) 660 (6.5)

Metals 56 (0.6) 78 (0.8) 122 (1.2)

Aluminum 3 (0.03) 3 (0.03) 5 (0.05)

Paper 177 (1.8) 198 (2.0) 253 (2.5)

Textiles 5 (0.05) 7 (0.07) 9 (0.09)

Wood 4 (0.04) 6 (0.06) 8 (0.08)

Compost 2 (0.02) 4 (0.04) 5 (0.05)

Total 640 (6.3) 903 (8.9) 1,179 (11.7)

SFA of WM SCENARIOS – Pb analysis

Lead to Landfill, g/d (% input Pb) SSL 35% SSL 50% SSL 65%

from sorting&recycling chain 10,181 (5.5) 16,316 (8.9) 26,699 (14.5)

from biological treatment 1,210 (0.7) 1,980 (1.1) 2,454 (1.3)

partial total 11,391 (6.2) 18,296 (10.0) 29,152 (15.8)

from bottom ash 64,943 (35.3) 51,778 (28.1) 26,414 (14.4)

from APC residues 53,064 (28.8) 42,308 (23.0) 21,583 (11.7)

Total 129,397 (70.3) 112,382 (61.1) 77,150 (41.9)Lead in recycled product, g/d (% input Pb)Glass 13,339 (7.2) 14,422 (7.8) 19,505 (10.6)

Plastics 3,316 (1.8) 5,532 (3.0) 7,008 (3.8)

Metals 29,334 (15.9) 40,533 (22.0) 63,922 (34.7)

Aluminum 6,137 (3.3) 7,878 (4.3) 12,192 (6.6)

Paper 1,023 (0.6) 1,144 (0.6) 1,464 (0.8)

Textiles 217 (0.1) 289 (0.2) 362 (0.2)

Wood 837 (0.5) 1,241 (0.7) 1,743 (0.9)

Compost 287 (0.2) 454 (0.2) 544 (0.3)

Total 54,489 (29.6) 71,493 (38.9) 106,740 (58.0)

WM SCENARIOS comparison

scenario SSL 35%

scenario SSL 50%

scenario SSL 65%

0.0%

5.0%

10.0%

15.0%

20.0%

25.0%

30.0%

35.0%

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ater

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, % tr

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SW

WM SCENARIOS comparison

scenario SSL 35%

scenario SSL 50%

scenario SSL 65%

0.0

5.0

10.0

15.0

20.0

25.0

30.0

35.0

40.0

45.0

50.0power production

in cogenerationRe

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Ener

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MSW

en

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scenario SSL 35%

scenario SSL 50%

scenario SSL 65%

0

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20000

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50000

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from sorting and recycling chainfrom biological treatment

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• A significant reduction in the requirement of landfill volume can only be achieved if the URW is sent to waste-to energy process. The scenarios with high energy recovery provide that• energy produced by carbon oxidation is full utilized• inorganic materials are mainly concentrated in the residues of

WtE plants• hazardous organic compounds are completely destroyed.

• The results suggest that the optimal source separation level should be lower than 65%, on the basis of the high amounts of toxic substances that can be found in the recycled products as well as the huge quantities of sorting and recycling residues, the difficulty of obtaining very high interception levels and the remarkable costs .

CONCLUSIONS

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• A procedure for goal-oriented WM planning has been proposed to provide a knowledge basis for MSW management decision makers. It is based on the extensive utilization of MFA and SFA, in the framework of a LCA approach and together with a scenario analysis.

• The proposed procedure appears as a powerful tool-box to compare alternative waste management technologies and scenarios, even though the obtainable results are just a part of the input data to the decision making process, which should further take into account a variety of economic and social aspects.

CONCLUSIONS

• The study shows the benefits afforded by the introduction of high quality household source separation and collection, biological treatment of the organic fraction coming from this separate collection and thermal treatment of unsorted residual waste: landfill mass and volume are drastically reduced, greenhouse gas emissions are reduced, toxic organic materials are mineralized, heavy metals are concentrated in a small fraction of the total former MSW volume, and the accumulation of atmophilic metals in the APC residue allows new recycling schemes to be designed for metals.

• The results also indicate that the MBT plant is a not sustainable choice, particularly in a catchment area where the landfill volume must be saved as much as possible.

CONCLUSIONS