Abstract

Decision makers for waste management are confronted with the problem of selecting the most economic, environmental, and socially acceptable waste treatment process. This paper elucidates evaluation methods for waste treatment processes for the comparison of ecological and economic aspects such as material flow analysis, statistical entropy analysis, energetic and exergetic assessment, cumulative energy demand, and life cycle assessment. The work is based on the VDI guideline 3925. A comparison of two thermal waste treatment plants with different process designs and energy recovery systems was performed with the described evaluation methods. The results are mainly influenced by the type of energy recovery, where the waste-to-energy plant providing district heat and process steam emerged to be beneficial in most aspects. Material recovery options from waste incineration were evaluated according to sustainability targets, such as saving of resources and environmental protection.

1. Introduction

In 2014 megagrams (Mg) of Municipal Solid Waste (MSW) were generated in the 28 EU countries [1]. This equals 475 kg MSW per capita, 23 kg MSW per 1000 Euros of Gross Domestic Product (GDP), and 36 kg MSW per Mg of Domestic Material Consumption (DMC, the total amount of material directly used in an economy). The amount of MSW rose from  Mg in the year 1995 to  Mg in 2008. Since then falling numbers are observed in Europe. The applied treatment options differ substantially between the EU countries as can be seen from Figure 1 [1].

On EU average 28% of MSW are recycled, 16% composted, and 27% incinerated. Nevertheless 28% are still landfilled, mostly without any pretreatment. Landfilling falls under the lowest treatment category of the EC waste hierarchy [2]. The lowest share of landfilling is from the following six countries: Austria, Belgium, Denmark, Germany, The Netherlands, and Sweden, each tallying below 5%. The waste treatment processes for recycling, composting, and incineration are manifold. Figure 2 displays flows of MSW in Germany (data from [3]). Here the waste management consists of composting for garden waste and biowaste, mechanical-biological treatment (MBT) of mixed waste, combustion of waste wood and Refuse-Derived Fuels (RDF) in cogeneration plants (Combined Heat and Power, CHP), incineration of mixed waste in waste-to-energy (WtE) plants, and recycling of waste materials from separate collection organized by curbside pickup or bring-systems [4]. Recycling includes treatment resulting in materials and energy recovery as well as in thermal treatment in WtE plants (e.g., sorting residues) [5].

A sustainable waste management system aims at maximizing materials and energy recovery while minimizing environmental impacts and societal cost associated with all treatment and collection steps [6]. The decision regarding which treatment process is used for what kind of waste fulfilling certain sustainability objectives is often difficult and depends on various boundary conditions. Sustainability objectives could be maximum materials recovery to save natural resources, minimum emissions to the environment, lowest treatment cost, highest concentrating efficiency for pollutants, and so on. Evaluation methods are therefore required to assess various waste management strategies.

With more than 152,000 members, VDI (Verein Deutscher Ingenieure, German Association of Engineers) is one of Western Europe’s biggest science and technology associations and, next to the German Institute for Standardization (DIN), the most important source of technical guidelines and standards in Germany. Given its wide-ranging base of technical expertise, VDI decided in 2008 to adopt the evaluation of waste treatment processes as an interdisciplinary topic. The objective was to describe available evaluation methods in waste management together with their opportunities and limits [7]. The outcome of this work was VDI guideline 3925. The final version of descriptive part 1 of this standard was released in September 2016 [4]. In part 2 the methods were applied to a practical example, the process comparison of two alternative waste-to-energy plants. The draft version of VDI 3925, part 2, appeared in July 2016 [8]. The results of the comparison and the interlinkage to sustainability assessment will be discussed in the present work.

2. System Boundaries and Input Data

An adequate methodology has to be selected to respond to the questions of which waste treatment option is the best with respect to sustainability, which is the most profitable investment, and so on. The accuracy of the results however depends strongly on the input parameters and the boundary conditions.

To evaluate the various evaluation methods outlined earlier, two WtE plants were chosen, based on real plant data, but with some modifications which will be explained in later sections. In Figure 3, an overview of various evaluation methods is shown; part of them will be explained in this paper to support the understanding of results.

The first main column comprises the mass and material balances for the processes including the climate change relevant CO2 balance. If the mass balance is not equalized the resultant enthalpy flows and all connected aspects like exergy analysis and efficiencies would be erroneous. The waste composition data for this paper is based on the average German waste composition concerning the main elements like carbon, hydrogen, and oxygen. Sulfur, chlorine, and trace elements were set in accordance with VDI 3460 [9]; see Table 1. The net calorific values (NCV) of the waste were proposed to be 9.72 MJ/kg and adapted by changing the water content of the waste, while the ash content (sum of bottom ash and fly ash) should be constant at 27.5 wt.%.

The second column presents the energy balance. From the energy balance the required amounts of feeding water for the boiler were calculated. Based on mass and energy balance the distribution of materials could be calculated not only by the state-of-the-art balancing scheme for each species but also by entropy analysis which points out sources and sinks of pollutants of each process. The life cycle assessment emphasizes the impacts of certain species on the environment with, for example, the global warming potential (GWP), the acidification potential (AP), or the human toxicity potential (HTP).

The eco-efficiency analysis emphasizes the monetary weighting of the life cycle assessment. The economy of the processes is evaluated by the cost-benefit analysis. Social aspects are included by the social-eco-efficiency analysis.

To balance the single processes local and time-dependent boundary conditions exist: The local system boundary is the delivery of the waste to the WtE plant (including operating consumables) and on the output side the ash discharger for solid residues and the smokestack for the flue gas. Time-dependent boundary is the operating life of 20 years.

To wrap up the main differences on the plants, Figure 4 displays the WtE process chains. The heat-conducted WtE plant generates heat and electricity and the power-conducted WtE plant generates electricity only.

The first WtE plant in this comparison is heat conducted with minor production of power and the second WtE plant is power conducted with no heat outcome. The main thermal process and the combustion conditions like air ratio, temperatures, and so on are assumed to be identical. The flue gas treatment however differs: While the heat-conducted process is based on a wet flue gas treatment with two scrubbers with the possibility of discharging the purified waste water into receiving water, the second plant is operated waste-water-free. Both plants are using a SCR technology for reduction.

To calculate all characteristic parameters for the discussed methods in Figure 3 the necessary input data are summarized in Table 1. The operation time of both the plants is about 7,600 hrs per year for a capacity of 212,800 Mg of waste (corresponding to a waste flow of 28 Mg/hr).

3. Evaluation Methods

3.1. Material Flow Analysis

The material flow analysis is a methodology to model and evaluate complex systems for the optimization of ecological and economical aspects in private and public sector. The material flow analysis reduces complex systems to relevant goods and processes for further measurements [10]. Examples are material balances in sorting processes or as described in this paper in different waste treatment processes. The material flow analysis employed in this paper was developed in Switzerland and is described in two regulations in Austria (ÖNORM S 2096-1 and -2). A software tool for modelling was developed at the Vienna University of Technology [10]. In a first step the system boundaries have to be defined as it is already mentioned in the earlier section. In a second step the processes have to be defined, such as the incinerator and flue gas treatment as “black boxes” with input mass flows () and output mass flows (). The decision on which species the material flow analysis should focus on is given by the research question. In the outlined examples in Section 4, the distribution of Hg, Zn, and Cl in input and output flows is presented. The distribution of the elements in the output is based on transfer coefficients for each process which are known from literature or have to be experimentally determined. The transfer coefficient is defined asAs an example, for Hg, in wt.% is given in Table 2 for both processes.

3.2. Statistical Entropy Analysis

Based on the material flow analysis in Section 3.1 a statistical entropy analysis can be performed to assess the ability of a system to concentrate or dilute substances [11]. In this case the entropy is a measure for the dispersion of any distribution. Hence it could be applied for the distribution of materials in processes. One of the main questions in waste management processes is how to recycle as many as possible from the wastes with low effort of energy. From the thermodynamic point of view much more effort (e.g., energy) is needed to concentrate or extract a material when it is highly diluted than when it is less diluted in a volume or mass flow. For a dilution of material, the statistical entropy is increasing, while concentrating the statistical entropy is decreasing. For a circular economy, it could be stated that the statistical entropy should be as low as possible for certain processes [4, chapter 7.2].

The statistical entropy is defined aswhere is concentration of species in the mass and is normalized mass flow.

The relative statistical entropy refers then to a maximum statistical entropy and is determined from the difference between input and output entropies for each species:

3.3. Energetic and Exergetic Assessment

Along with clean and hygienic treatment of waste the fundamental aim of waste management is to recover as much materials and energy as possible. Therefore, the energy conversion efficiencies of waste treatment processes are essential in the evaluation. The efficiencies are defined as ratio of useful output divided by the input. Input here is the chemical energy content of the waste; output is either thermal or electrical energy. The quality of both energy forms is different. This is considered in the so-called formula [2] where recovery option in Annex II of the Directive 2008/98/EC on waste (use of fuel to generate energy) can be distinguished from disposal operation D10 in Annex I of the same directive (incineration on land). Here thermal energy is multiplied by a factor of 1.1 and electrical energy by a factor of 2.6

The -formula above is a simplified equation without the use of imported energy and auxiliary fuels [12] with NCV, the net calorific value (see Table 1), and , the mass flow of MSW incinerated.

The calculation of the exergy leads to similar results. The exergy factor of electricity is 1, whereas thermal energy is taking into account the Carnot factor only (with the temperature of the thermal process and the surrounding temperature) [13].

3.4. Cumulative Energy Demand

The cumulative energy demand (CED) states the sum of the entire demand expressed as primary energy which arise from production (), use (), and end-of-life processes () of a product or service [14]. For the process thermal waste treatment, is dominated by the cumulative energy demand for the materials such as steel, copper, concrete, and plastic used for building and facilities. is composed of the demand for operating consumables for combustion startup and flue gas cleaning (fuel oil, limestone, caustic soda, activated carbon for adsorption of organic pollutants, ammonia solution, precipitation agent TMT15® (trimercapto-s-triacin, 15% aqueous solution of an organosulfide to capture heavy metals like Pb, Cd, Cu, and Hg), etc.), the plant’s own use of electricity and steam, and useful energy to the grid. accounts for energy expenses for dismantling and final disposal of the plant.

3.5. Life Cycle Assessment

Life cycle assessments (LCAs) systematically analyse the environmental influences of products and processes as they span across multiple processes and the life cycle. LCAs should follow the norms ISO 14040 and ISO 14044, which describe the methodological foundation for carrying out life cycle assessments [15, 16].

A life cycle assessment consists of four stages (see Figure 5):(i)Goal and scope definition(ii)Inventory analysis(iii)Impact assessment(iv)Interpretation.

Further guidance for LCA practitioners can be found in the International Reference Life Cycle Data system (ILCD) Handbook published be the JRC [17].

3.5.1. Goal and Scope Definition

The first stage defines the goals of the life cycle assessment being prepared. The study purpose and the intended audience or client for the study shall be named together with a clear definition of the goal. This clarifies, for example, whether this is a study to analyse representative questions for a particular region, or if the subject of the study is a specific product from a particular manufacturer. This piece of information then simultaneously serves to specify the temporal and spatial system boundaries and constrain the product system being studied.

In general, the goal of a life cycle assessment is to compare different products, processes, or services with the goal of supporting a decision to be made. Such comparisons require equivalent use of the functions of the products, processes, or services being compared. The ISO norm defines this requirement using a so-called functional unit, which quantitatively defines the benefit to which all results must bear reference. Such a function may exist, for example, in the packaging of a particular volume of a drink, in the transport of products over a specific distance, or in the treatment of a particular quantity of waste.

3.5.2. Inventory Analysis

In consensus with the defined goal and scope, the inventory analysis or life cycle inventory (LCI) stage is based on the model of the technical system to be analysed, the “product system.” When carrying out a life cycle assessment in a complex product system, it is not always possible to determine all material and energy flows. Nevertheless, all “relevant” flows must be examined.

An additional methodological problem in the inventory analysis occurs for so-called multiproduct systems, for example, refining ores containing multiple different metals. In such cases, the input and output flows of the technical processes must be divided (“allocated”) between the products involved.

3.5.3. Impact Assessment

Evaluation of the material flows determined in the inventory analysis with respect to their environmental influence takes place in the Life Cycle Impact Assessment (LCIA).

The ISO impact assessment rests upon the concept of category indicators, that is, on the determination of a quantitative indicator along the impact chain from material flows to potential harm to the environment. Table 3 summarizes the impact category “global warming” of the defined environmental problem “greenhouse effect” as an example.

DIN EN ISO 14040 specifies that “the impact categories, category indicators and characterisation models should be internationally accepted, i.e., based on an international agreement or approved by a competent international body.” In practice, frequently used impact categories include climate change, stratospheric ozone depletion, formation of photochemical oxidants (summer smog), acidification, and eutrophication as well as human and environmental toxicity. A quality assessment of different impact assessment methods can be found in the ILCD Handbook “Recommendation for Life Cycle Impact Assessment” [18]. Furthermore, abiotic resource consumption and CED (VDI 4600, see Section 3.4) are often specified as “input-related impact categories.”

3.5.4. Interpretation

Life Cycle Interpretation, the important fourth and final stage, transforms the detailed and often complex results of the life cycle analysis and impact assessment into a message clearly comprehensible to the target audience. The ISO standards do not prescribe a mandatory procedure to be followed for the interpretation but do highlight the following important points: The results should bear clear reference to the goal and scope definition. Limitations should be explained and important points affecting the results or the choice of method should be described. DIN EN ISO 14044 lists the following components of the interpretation stage:(i)Identification of the significant issues based on the results of the LCI and LCIA stage of LCA(ii)Evaluation that considers completeness, sensitivity, and consistency checks(iii)Conclusions, limitations, and recommendations.

3.6. Cost-Benefit Analysis and Eco-Efficiency Analysis

The cost-benefit analysis (CBA) is an instrument used to analyse action alternatives (e.g., when selecting projects) on a monetary basis [19]. In a CBA private monetary cost/benefit for the market participant themselves and social cost/benefit borne by the environment, which is not monetary in nature, can be accounted forThe eco-efficiency analysis evaluates ecological and economic aspects of product or process sustainability on equal footing [20]. The results are displayed in a portfolio with (normalized) costs and environmental burden which are derived from CBA and LCA, respectively.

4. Results and Discussion

4.1. Material Flow Analysis

In Figure 6, the flow charts of the total mass flows, the mass flows of mercury, zinc, and chlorine, are presented for both thermal waste treatment process chains as Sankey diagrams. Largest output fraction with solid residues is the bottom ash. Although the majority of zinc (72%) is transferred to the bottom ash the concentrations of Zn in fly ash are higher (5800 mg/kg versus 14000 mg/kg in the heat-conducted plant and 9300 mg/kg in the power-conducted plant, resp.) because the fly ash fraction is smaller by factor of 4–7. In the heat-conducted plant the waste-water fraction is the main output flow for chlorine. While the oceans are the final sink for the salts, minor part of chlorine is transferred to the fly ash. For the power-conducted plant, chlorine is mainly separated as alkaline earth chloride together with the fly ash by the fabric filter.

Due to the addition of TMT15, during waste-water treatment in the heat-conducted plant mercury is concentrated in the neutralization sludge, while in the power-conducted plant the mercury is adsorbed in activated carbon and separated in the fabric filter together with fly ash and reaction product. The other heavy metals, like Ni, Zn, Cu, Cr, Cd, Pb, and As, are mainly distributed in the bottom ash and the fly ash.

4.2. Statistical Entropy Analysis

According to the definition of the relative statistical entropy with regard to the lowest concentration of the species in the earth crust, the first concentrating step took place in the waste generation itself. During the combustion of the waste in the WtE plant the species are concentrated in certain mass flows (see results of the material flow analysis). So in both cases is lower than in the waste flow. Differences result only for chlorine and mercury due the varying flue gas treatment technologies. Chlorine is concentrated in the waste-water discharge system in the case of the heat-conducted plant, where the concentration is higher than in the receiving river. In the power-conducted plant, mercury and chlorine are concentrated in the fly ashes and the reaction products. If the concentration of each species is high but the normalized mass flow is high, too, will be higher than in the case where the concentration is high but the mass is low. For the power-conducted plant the normalized mass for the fly ashes and the reaction products is more than 20 times higher compared to the neutralization sludge in the heat-conducted plant while the concentration of mercury in both cases is more or less the same.

To wrap up the outcome of the statistical entropy and the material analysis, the heat-conducted plant has the ability to minimize the dissipation into environment for most of the mentioned species (Figure 7), by concentrating them in a certain mass flow or fraction. Although the mass flow of mercury in the flue gases and the bottom ash of both concepts is the same (Figure 6, gray flow sheets), is still lower because mercury is concentrated in the sludge with a very small mass flow of about 0.04 Mg/h (Figure 6, black flow sheet, in (b)) compared, for example, to the much higher mass flow of fly ash and FGT residues with 1.5 Mg/h (Figure 6, black flow sheet, in (a)) for the power-conducted plant.

4.3. Energetic and Exergetic Assessment

For the comparison in the present work a net calorific value of 9720 kJ/kg was established; see Table 1. This (chemical) energy content can only partly be utilized by the combustion process as thermal or electrical energy. The combustion parameters are of an overall air ratio of 1.6, a thermal boiler efficiency of 86.2%, and a net electrical efficiency of 6.6% for the heat-conducted plant and of 19.7% for the power-conducted WtE plant; the generated heat is exported into the grid with 5 bar and a feed temperature of 170°C and a return temperature of 55°C. Thermal efficiencies are 63.8% (heat-conducted) and 1.6% (power-conducted), resulting in total efficiencies of 70.4 and 21.3%, respectively. These results are in good agreement with a recent survey on efficiencies of European WtE plants [21]. According to this study, the average efficiency of power-conducted plants is 21.6% and 77.2% for a heat-conducted plant (100% heat production). Combined heat and power (CHP) installations exhibit an average efficiency of 15% (power) and 37.1% (heat).

The large difference between the calculated total efficiencies suggests a clear superiority of the heat-conducted WtE plant over the power-conducted plant. This is still true for the formula. for the heat-conducted WtE plant is calculated as 0.961, and for the power-conducted plant is 0.599, even though the share of electricity was multiplied by 2.6. The values for exergetic efficiencies are not surprisingly lower. The amount of generated electricity is multiplied by a factor of 1, the amount of generated district heat with 0.35 (using the Carnot factor for a temperature of 170°C; = 15°C). The results show exergetic efficiencies of 28.7% (heat-conducted) and 20.25% (power-conducted), respectively. The recovery of the elemental metals Fe, Al, Cu, and brass alloys (see Table 1) can be attributed to an extra 1.6% for both processes.

4.4. Cumulative Energy Demand

was calculated for a waste incinerator in Germany with an annual capacity of 107000 Mg per year [22] with a result of 47 MJ per Mg of waste treated. More than 50% (24.4 MJ/Mg) is attributed to steel used in components of the WtE plant (e.g., boiler or turbines), followed by steel for the building envelope (14.2 MJ/Mg). This figure is smaller than CEDU related to operating consumables with 100 and 170 MJ/Mg waste for the heat-conducted and power-conducted plant, respectively. The discrepancy arises from the different flue gas cleaning system (CED for limestone and coke). Plant’s own use of energy is in both alternatives on the same level (heat-conducted: 3335 MJ/Mg; power-conducted: 3165 MJ/Mg). Useful energy to the grid differs largely: 10029 MJ/Mg for the heat-conducted plant and 4338 MJ/Mg for the power-conducted plant. Primary energy conversion factors for heat and electricity were retrieved from literature: 1.31 MJ/; 2.31 MJ/ [23, 24]. CEDE was estimated to be negligible. The bottom line is a negative value for total CED in both alternatives: −6672 MJ/Mg waste for the heat-conducted plant; −1472 MJ/Mg for the power-conducted plant. The results show that the outcome of the CED analysis is dominated by the use phase. The impact related to facilities and equipment () is small. The effect of such capital goods has only rarely been addressed systematically in LCA studies on WtE technologies [25]. From the results in the present work, neglecting the environmental impact related to capital goods seems to be justified.

4.5. Life Cycle Assessment
4.5.1. Goal and Scope Definition

The aim of the present life cycle assessment is to compare two WtE plants which differ with respect to the parameters for the energy output (power-conducted or heat-conducted) and the applied flue gas cleaning processes. The system boundaries include a WtE plant with the flue gas and waste-water treatment, the complete energy conversion part, and the entire upstream chains for the provision of all required resources, starting with the extraction from the ecosphere. The construction of the WtE plants along with their infrastructure was considered negligible and is therefore not included in the balance sheet. The functional unit includes the treatment of 1 Mg of municipal waste in the WtE plant. It is important to make sure that the benefits/performances of both compared systems are the same. Since both studied options have different “added values” (in the case of the present study—electricity or heat generation), the equivalent processes will be deducted from the environmental impact as environmental credits.

4.5.2. Life Cycle Inventory

The life cycle inventory (LCI) includes all relevant materials and energy flows from both compared processes (see Figure 4). The processes are modelled as a single chart without separate representation of the individual plant components (among which are combustion, energy conversion, and gas treatment)—the so-called “black box” modelling. The models are developed with the open source LCA software OpenLCA (http://www.openlca.org).

4.5.3. Impact Assessment

The present LCA aims to provide an example depiction of the processes. Therefore, only the GWP (global warming potential) measured in kg CO2-eq./Mg will be taken into consideration as impact category. Two other impact categories, that is, acidification potential and human toxicity potential, have been calculated as well. Figure 8 depicts the GWP of both WtE plants calculated using the impact assessment method developed at Centrum voor Milieukunde, Leiden University, in The Netherlands (the CML impact assessment method), which analyses effects of the greenhouse gas (GHG) emissions over a time span of 100 years.

Concerning the amount of GHG emissions, both processes come up with similar GWP values (845 kg CO2-eq./Mg for power-conducted WtE plants versus 851 kg CO2-eq./Mg for heat-conducted WtE plants). While the major part of the emissions comes from the biogenic fraction of combustion (501 kg CO2-eq./Mg of waste), only a very small part of GHG emissions (0.46 kg CO2-eq./Mg waste) results from the combustion of fuel oil required for the operation of the WtE plants.

The generated amounts of heat and electricity as well as the produced substitutes for primary materials during the metal manufacturing (iron, copper, and aluminum) will be taken into consideration by deducing of the emission credits (depending on the electricity mix of the providing power plant parks). The data for the electricity mix were obtained from Itten et al. [26]. According to that work, the German electricity production is mainly powered by fossil fuels (22% lignite, 18% coal, and 13% natural gas), by nuclear power (22%), and by renewable energy sources (6% of the total amount, mainly by wind power plants), while 7% of the electricity is imported from the neighboring countries. Proceeding from these assumed data, the impact assessment returns the GWP value of 671.5 g CO2/kWh for the German electricity mix. For comparison, the values are 109.0 g CO2/kWh for the electricity mix in France and 1209.0 g CO2/kWh for Poland. The data for the heat mix were obtained from the AGFW [27]. According to these data, the heat mix consists of natural gas (46,25%) and other heat sources like coal, biomass, and so on (53.75%). The GWP calculations of the heat production in Germany based on these data result in 250 g CO2/kWh. The GHG avoided corresponds to 611 kg CO2-eq./Mg waste for the heat-conduction WtE and 424 kg CO2-eq./Mg waste for the power-conducted WtE, respectively.

For the case where only gas power plants are taken into account (and not the plants powered by the German heat mix), the power-conducted WtE plant compensates only 4.36 CO2-eq./Mg of waste and the heat-conducted alternative compensates 171.85 kg CO2-eq./Mg of the municipal waste (see Figure 9). Should coal power plants be considered as the only heat suppliers, the heat-conducted option would compensate 817.18 kg CO2-eq./Mg of waste and the power-conducted WtE plant would compensate 20.78 kg CO2-eq./Mg of waste. This means that the credit values vary depending on the chosen heat source, so the comparison methodology for environmental credits should always be chosen as close as possible to the actual situation. For example, the choice of coal plants as the only source of heat would mean a higher credit value. This choice is however not justified since the German heat mix has a significantly different composition.

The importance of the substituted energy is also shown in the work of Jeswani and Azapagic [28] comparing waste incineration with landfilling. The credits for replaced greenhouse gas emissions are lower if the WtE plant substitutes cleaner electricity. The global warming potential of the WtE plant therefore shows emissions instead of savings in the case of substituted energy from the UK grid, from natural gas, or from nuclear power. Greenhouse gas savings occur looking at the use of heavy fuel oil and coal.

4.5.4. Interpretation, Data Analysis, and Evaluation

There are several ways to depict the coproducts in the model (among which are mainly electricity and heat in the present study). One possibility is the allocation (distribution) of the environmental impacts within a particular aspect for different products (e.g., physical or economical aspects). Since the disposal of 1 Mg of waste in the described WtE plants cannot be allocated directly to electricity or heat, the modelled systems should be extended by using the environmental credits. This means that the environmental impacts of the German power plants are credited by the generation of, for example, electricity.

The availability of data forms the boundaries of the LCA. The data gaps for certain emissions or critical processes may lead to completely false results for the associated impact categories or the entire life cycle assessment (e.g., if there is no data on GHG emissions, one cannot carry out the assessment of the global warming potential). Regarding all these limitations, the heat-conducted WtE plant should be preferred from the climate perspective (see Figure 9).

4.6. Cost-Benefit Analysis and Eco-Efficiency Analysis

Cost-benefit analysis revealed that at similar treatment cost (fixed cost for, e.g., debt service and variable cost for consumables) for both options of around 130 Euros/Mg the revenues from energy production are much higher for the heat-conducted plant (155 Euros/Mg) than for the power-conducted plant (65 Euros/Mg) even though the return per MWh is higher for electricity (115 Euros/MWh compared to 75 Euros/MWh, see the same discussion for efficiencies in Section 4.3). This leads also to a better eco-efficiency of the heat-conducted plant: better environmental performance regarding greenhouse gas emission (see Figure 8) and lower overall cost or, as in this case, higher revenues (−27 Euros/Mg compared to 67 Euros/Mg).

Monetization factors for external effects can be used from existing models, for example, from the EPS method (Environmental Priority Strategy) [29]. Here CO2 is valuated with 108 Euros/Mg, and emissions from Particulate Matter (PM10) are valuated with 36000 Euros/Mg. The monetized environmental burdens from both alternatives are almost identical (40.5 Euros/Mg waste power-conducted; 39.2 Euros/Mg waste heat-conducted). However, in total with the credits from energy production the result is different: −17.5 Euros/Mg waste for the power-conducted plant and −49.8 Euros/Mg waste for the power-conducted plant (i.e., net environmental benefits).

Not surprisingly the results for the eco-efficiency analysis are similar. Because the heat-conducted plant is in most LCA impact categories the superior alternative and is economically more favorable, in the eco-efficiency portfolio, this alternative is placed in the upper right quadrant (low normalized cost and low normalized environmental impact). The power-conducted plant is more expensive and has a higher environmental impact. Therefore, the power-conducted plant ends up in the lower left quadrant; see Figure 10.

5. Discussion and Conclusions

“What is the best way to manage urban waste?” was asked in a special issue of EU’s DG Environment News Alert Service [30]. The question is not easy to answer. This is the reason why hundreds of LCA case studies of solid waste management systems or WtE technologies have been performed. At least it is clear that landfilling without any energy recovery such as biogas utilization is the worst option. For a sustainable waste management 5 main targets can be defined [31]: (1) protection of man and environment, (2) conservation of resources, (3) waste disposal in regional and temporal responsibility, (4) organization of waste management in an economically acceptable way, and (5) social compatibility of waste management. Protection of man and environment can be achieved with technical systems. Even when waste is landfilled, emissions to groundwater or air can be prevented with technical barriers composed of geotechnical products [32]. For thermal waste treatment the best available techniques have been compiled in a reference document (WI BREF [33]). Application of these techniques in waste incineration ensures protection of man and environment.

Conservation of resources is possible in various ways in waste treatment. Specific waste streams such as paper, plastic, metals, or glass can be separated at the source (see Figure 2) for recycling [34]. For paper and glass there is consensus that this is preferable compared to thermal waste treatment of nonseparated solid waste [25]. Management of plastic waste is controversial [35]. Collection and recycling of plastic waste are most probably beneficial when monofractions can be generated. However, waste incineration with energy recovery could be a better option for contaminated polymers with impurities [36]. Recovery of elemental metals, that is, ferrous and nonferrous metals, is easier subsequent to thermal waste treatment because plastic-metal composites and all kinds of coatings are effectively removed by the incineration process. The metals can then be separated almost completely from the bottom ash [37]. Here the revenues are much higher than the treatment cost.

However, for the recovery of chemical bound metals from waste incineration residues the situation is different. This was evaluated in the case of zinc. With material flow analysis (see Section 3.1) it was shown that, from a flow of 50 g/h Zn, 26% (13 g/h) are transferred to the fly ash and 72% to the bottom ash (residual 2% to other output fractions). The Zn concentration in the fly ash can then be calculated from the mass balance of the process (see Figure 6) to 14,000 mg/kg fly ash (heat-conducted). In the power-conducted plant the concentration in the fly ash is lower because also the reaction products from flue gas cleaning are contained in this fraction and cause a dilution. Concentrations of Zn in fly ash of electrostatic precipitators (ESP) in WtE plants can be as high as 42,000 mg/kg [38]. Zinc can be recovered from the ash with the hydrochloric acid (HCl) which is produced in the first step of a wet flue gas cleaning system (see Figure 4). For this scenario, HCl utilization from wet flue gas cleaning system and high concentrations in ESP fly ash, the production cost of Zn is in the range of the market price. With dry or semidry flue gas cleaning systems, the production cost of secondary Zn is higher than the market price by a factor of up to 10 [38, 39]. Zn recovery from fly ash is applied in Switzerland although the process is hardly economical [38]. Obviously, the goals of conservation of resources and waste disposal in regional responsibility (see sustainability targets (2) and (3) above) are there considered as high priority.

The present study shows that WtE plants generating district heat or process steam have economic and ecological advantages compared to power-conducted WtE plants. One reason for this is falling earnings from electricity as a result of increasing share of renewable energy in electricity generation, for example, in Germany. However, a stable demand for district heat (which requires appropriate infrastructure) or process steam is a prerequisite for the operation of a heat-conducted WtE plant. The infrastructure and market for heat and steam are not available everywhere [40]. In contrast, electricity generated in a power-conducted plant can be easily transferred to the grid.

As long as avoidance of waste and reuse is not completely achievable, thermal waste treatment with recovery of energy and secondary raw materials is a necessary waste management option. It was shown that methods for the evaluation of to what extent sustainability goals are achieved by a certain waste management option exist.

Conflicts of Interest

The authors declare that they have no conflicts of interest.