The Thermal Waste Treatment Plant in Kraków, Poland: A Case Study

The thermal waste treatment plant (TWTP) in Kraków (eco-incinerator) was created as a response to the energy and ecological needs of Kraków as part of the project “Municipal Waste Management Program in Krakow.” The TWTP is able to process 220,000 tons of municipal waste during the year. Estimated values of the 65,000 MWh of electricity and 280,000 MWh of heat are produced as a result of the waste combustion. The energy obtained by way of the thermal transformation process is largely organic and renewable. The TWTP is equipped with a state-of-the-art exhaust purification system that meets strict emission standards for air. The emission standards will meet the requirements the Ordinance of the Minister of the Environment of November 4, 2014 on emission standards for certain types of installations, sources of fuel combustion and devices for incineration or co-incineration of waste (Journal of Laws of 2014, item 1546, including further amendments). The cleaning process takes place in the exhaust aftertreatment process and is based on the following steps: ( i ) denitrification of exhaust gases, ( ii ) flue gas cleaning by means of a semi-dry method and ( iii ) dust extraction. As the project’s general contractor was POSCO E&C from South Korea.


Introduction
The term "thermal treatment" is used to describe a range of technologies that use heat to degrade the constitution of solid matter. These include incineration and its variations, as well as advanced thermal conversion (ATC) technologies such as pyrolysis and gasification [1,2]. Incineration of waste has been practiced for more than a century in the industrialized world [3].
For many people, thermal treatment technologies for waste management represent an image of hell on earth [2]. In line with Moberg et al. [4], waste is generated as a consequence of most of our daily activities. Waste incineration is often (but not always) the preferable choice when incineration substitutes landfill disposal of waste [5]. According to Hauck et al. [6], modern WTE facilities process approximately 13% of the total municipal waste in the United States. There is potentially more than 16,000 MW of electric power that currently a "missed opportunity" in the United States alone. The average gross and net electrical power generation of

Example of Incineration plants. Literature review
In Europe, the recovery of EFW has been adopted by the European Commission as one of the sustainable waste management options, with the scope to decrease the amount of nonhazardous waste going to landfill [11]. In the context of waste-to-energy, it is worth noting the European Environmental Citizen Organization for Standardization (ECOS), nonprofit association established in 2002, funded by the European Commission and based in Brussels [12]. ECOS acknowledges that incineration of biomass contribute to climate protection, in addition ECOS admits that energy recovers only if performance is higher (LCA), and waste with low net calorific value or high level of pollutants shall not be used as "fuel" [12].
Waste incineration practices were discussed in the framework of project "QUOVADIS Waste-to-fuel Conversion -A Thinkshop," which took place in Ispra, Italy, between 28 April 2005 and 29 April 2005 [13]. Workshop was the forum for discussion and debate on the exchange of various experiences concerning the use of waste in waste-to-fuel conversion and its subsequent application [13]. In the draft paper untitled "Survey on the on-going scenario for SFR (solid recovery fuels) production and use in Italy" prepared by MP Maranzana presented 44 waste-to energy plants in Italy [13].
With the introduction of legalization, the situation in the EU has been improved markedly, but with pressure to minimize landfill and limited option for recycling, thermal treatment occupies a key role in waste management [14] (ENERGY]. The main challenges to incineration plant operation are maximizing thermal efficiency for energy recovery [14]. The Clean and Efficient Waste Incineration, Waste-to-Energy and Biomass Combustion (CLEANWEB) project addresses these challenges. The other project Performance, Reliability and Emission reduction in Waste INcineration (PREWIN) Network provides the forum for collaboration among pan-European organizations for waste incineration [14]. One of the objectives of the project is to improve the performance, efficiency and reliability of thermal treatment plant (Figure 1).

Figure 1.
Process flow diagram related to CLEANWEB and PREWIN projects [14]. Innovation in Global Green Technologies 2020 4

Maishima incineration plant
Maishima ("dancing island" in Japanese) is a man-made Island in the Bay of Osaka. Osaka is Japan's third largest city, with a population of 2.6 million and with seven completed Von Roll plants [15]. Impressed by a facility in Vienna that had been embellished by the world famous Austrian artist, Osaka's planners decided to entrust him with the design and ornamentation of the building, the stack and the surrounding area (Figure 2). The facility consist of two waste processing lines, each of which is able to incinerate 450 tons of MSW every 24 hours, and is typical of today's large scale.
The energy produced in the incineration process is used to generate power in the power generator with a capacity of 32 MW [15].

AVI Moerdijk incineration facility
The Dutch provinces of Zeeland, North Brabant and Limburg funded study in 1990 to determine how much waste was being generated in the southern Netherlands. Based on the 600,000 tons of waste, new waste incineration plant AVI Moerdijk linked to thermal power plant was built. The facility being operation since 1996/1997 and consists of three separate lines. Waste heat generated in a year amounts to 2,000,000 tons of high-pressure steam at temperature of 400°C. The photo and schematic of the AVI Moerdijk incineration facility are presented in Figures 3 and 4, respectively [16].

Bergen incineration facility
In the Bergen region on the western coast of Norway, the city Bergen and neighboring communities founded Bergensområdets interkomunale Renovasjonsselskap (BiR) company with the objectives of managing the waste generated by the region's 280,000 inhabitants. The contract for erecting waste incineration plant was awarded to Von Roll Inova in 1997. Start of operation was in 1999. Energy recovery based on 90,000 tons of waste is about 60 GWh of electrical energy and 430,000 tons of process steam. The photo and schematic of the BiR Bergen incineration facility are presented in Figures 5 and 6, respectively [17], as well as in Figure 7 [18].

KEBAG waste incinerator plant, Zuchwil
According to DOKA [19], Switzerland has 28 municipal solid waste incinerator (MSWI) plants in operation 1 (2000). The majority of them [23] have two or three furnace lines. All Swiss MSWIs utilize the energy contained in the waste to produce useful heat and/or electricity. In 2000, Swiss MSWIs gross production was 2,526,800 MWh heat and 1,284,200 MWh electricity, and the total energy input was 9,880,262 MWh [20]. Figure 8 displays the general photo of the KEBAG waste incinerator plant in Zuchwil, Switzerland. In its four incineration lines, Zuchwiler KEBAG treats 220,000 tons of flammable domestic waste a year from the cantons of Berne and Solothurn-i.e., from around 473,000 residents in 208 municipalities, as opposed     to 2002 year, when train 4 enters service, and the service area has around 350,00 habitants who generated some 200,000 tons of wastes. The energy produced in the incineration process is used to generate electricity and prepare hot water [21,22].

KVA Thun energy-from-waste plant
The KVA Thun energy-from-waste plant handles some 100,000 tons of combustible waste (domestic and bulky) a year. Thun is the city, located on Lake Thun, is the economic hub of the Bernese Mittelland and Oberland with the population of 300,000 residents in 150 communities. The facility produces about a third of the electricity consumed in the city of Thun, as well as provides district heating for different customers facilities (e.g., adjacent public sector facilities [23]). Energy recovery type is extraction-condensation turbine produced electric power of 12 MW (maximum) and district heating output about 25 MW (maximum) [23]. The photo and longitudinal section of the KVA Thun energy-from-waste plant are presented in Figures 9 and 10   Innovation in Global Green Technologies 2020 8

Forms of recycling in Poland
One recycling method is energy (thermal) recycling, understood as total or partial energy recovery. The waste incineration process must take place under certain conditions due to the toxic substances formed during combustion, such as dioxins or furans emitted and polluting the atmosphere.
The choice of recycling method depends on the type and properties of the post-consumer product. Due to changes in the prices of raw materials and energy, limited possibilities of using material recycling, as well as the fact that raw material recycling can already be considered cost-effective, the role and importance of this form of recycling should increase.   The thermal methods of waste removal that we can distinguish are as follows: combustion, pyrolysis (degassing/gasification), hydrogenation and bios drying. The main waste disposal system is of course incineration, which removes waste that is unusable and cannot be managed further.
Incineration is intended to make the waste residues neutral to the environment and minimize waste gas emissions. It is also important to reduce the volume and use the energy generated during combustion.
The industry must also be guided by several important principles related to the combustion of precipitation: • operational safety • investment value • land demand • process efficiency and efficiency.
The pyrolysis process breaks down organic waste under the influence of temperature. The product is energy carriers useful for storage. Most combustion technologies are still in the testing phase and are being gradually introduced to the market in mature forms.
Another thermal process to mention is hydrogenation, which uses refinery waste and in some cases plastic waste. However, the goal of the bios drying process is the production of alternative fuel from a biodegradable fraction segregated from mixed municipal waste. The biological drying process is preceded by separation of biodegradable fraction (0-60/80 mm) from mixed municipal waste, followed by mechanical treatment of the dried fraction to produce fuel.

The thermal waste treatment plant in Krakow (eco-incinerator)
The main objective of this study is to share the art knowledge about the TWTP (eco-incinerator) in Krakow, Poland, that has operated since 2016. Description of TWTP case study is based on the thermal waste treatment plant in Krakow presentations given in [25][26][27][28].
In recent years, waste incineration has been frequently preferred to other waste treatment or disposal alternatives due to advantages such as volume reduction, chemical toxicity destruction and energy recovery [29].
According to the study by Pfeiffer [30], energy recovery is a secondary goal of waste incineration: thermal waste treatment and energy recovery are "married" within the waste-to-energy plant [30]. From an economic point of view, a WTE plant treating MSW is an enterprise using a special fuel [1].
Thermal waste treatment plant (TWTP) in Krakow (eco-incinerator) is being constructed in answer to concepts link economic, ecological and social aspects and  Figures 12 and 13, respectively [27].
Eco-incinerator allows to process 220,000 tons of municipal waste a year. Selected by the inhabitants mixed municipal solid waste (MSW) and other waste (e.g., resulting from mechanical processing of municipal waste) and following waste recovery processes (i.e., material waste, bulk, rubble) are subject to thermal processing. The wastes are collected only from the municipality of Kraków.
The emissions come from TWTP production process meet the requirements of the best available techniques (BAT), guaranteeing the highest standards of environmental protection.   On October 1, 2016, the educational pathway, an integral part of the ecoincinerator, was launched in the eco-incinerator area with the goal of increasing the ecological knowledge of the inhabitants as well as bringing the technology and thermal plant operation processes closer to them. This educational pathway is the tour throughout the plant, showing the key steps of the system such as delivery and unloading of waste into the bunker, the process of thermal conversion of municipal waste, the flue gas scrubbing process, the electricity and heat production process and the process of managing residue after incineration [27].

The TWTP-a cost-effective and safe solution
Naturally, very stringent environmental regulations are applied to the process. Using BAT, the TWTP in Krakow meets the highest environmental and legal standards applicable in the European Union. The amount of waste is limited, and thus securing energy to the city has increased.
In the line of [27], energy security signifies a prospective condition of meeting consumer demand (including the citizens of Krakow) for fuel and energy through alternative sources of acquiring gas [27].

Emission standards
According to [28], the plant is equipped with a state-of-the-art exhaust purification system that meets strict emission standards for air.
The exhaust aftertreatment process consists of the following stages: • Denitrification of exhaust gases • Flue gas cleaning by means of a semi-dry method • Dust extraction. The emission standards comply with the Ordinance of the Minister of the Environment of 4 November 2014 on emission standards for certain types of installations, sources of fuel combustion and devices for incineration or co-incineration of waste (Journal of Laws of 2014, item 1546, including further amendments).
Below you can find in Table 1 [28] a sample of selected emission values derived from measurements of 27 July, 13 August and 20 August this year.
As mentioned above, the eco-incinerator was created as a response to the ecological and energy needs of Krakow as part of the project "Municipal Waste Management Program in Krakow" (TWTP). It is the latest and most important part of this system; it enables to utilize municipal waste generated by the inhabitants of Krakow and the recovery of energy from it.
The thermal recycling technology is the most mature and environmentally esponsible solution to waste. This is confirmed by many years of European experience in which thermal processing of waste with recovery of energy forms the basis of the entire waste management system.
The eco-incinerator allows to process 220,000 tons of municipal waste during the year. Approximately 65,000 MWh of electricity and 280,000 MWh of heat are produced as a result of the combustion. The energy obtained by way of the thermal transformation process is largely organic and renewable [27].

Green energy factory
The thermal waste treatment plant in Krakow called Green-energy factory [26] provides background material for this part.
Concept of the furnace-grate furnace integrated into the boiler.

The TWTP receives
• Municipal solid waste mixed with secondary raw materials separated.
• Combustible ballast from other installations for processing municipal [26].

Selection of waste, unloading and loading in the combustion chamber
The overall objectives of the TWTP are to increase thermal efficiency and heat recovery, as well as reduce emissions through improving and developing a better plant characteristics. For this purpose, the wastes are discharged in the unloading hall of the bunker that ensures stocking waste for 5 days. To obtain a uniform mixture, which improves incineration efficiency, the waste is mixed together in the bunker. Next the waste is mixed together in the bunker, and then the cranes equipped with 6-teeth grapple buckets transport mixed waste to feed hoppers where it feeds into the loading shaft [25].
In the TWTP were installed radioactive material detectors so as to protect the installations against damage. The TWTP also monitors waste delivered for thermal processing [26].

Emission treatment process
In line with [26], carbon dioxide, carbon monoxide, sulfur dioxide, oxides of nitrogen, steam and unburned or partially burned hydrocarbons are generated during the waste combustion process. Pollution may be expressed both in the form of gas and dust [26].
Pollution control plays an important role in waste incineration. All existing emission limits are complied. Combustion gases pass first to the heat recovery steam generator. Next via emission treatment installation are transferred to gas exhaust fan and finally are removed to stack.
Procedure of the emission treatment consists of the following steps [26]: • Exhaust gases denitrification used by primary and secondary methods based on the application of the selective nitrogen oxides reduction (SNCR) via the injection of aqueous urea solution containing 25% urea by weight.
• Semi-dry method based on the use of lime slurry, together with the dry entrained flow method with activated carbon. These methods reduced acidic impurities, as well as heavy metals, dust, furans and dioxins.
• Fabric filtration for the effective dedusting exhaust gases by means of fabric filtration [26].
Post-processing waste disposal: According to the [26], by-products created during thermal processing of waste are as follows: • slag and bottom ash • boiler dust • fly ash • solid residues from the emission treatment.
Each residue resulted from thermal waste processing shall be received by authorized external entities in accordance with the provisions of the IPPC standards [26].

Conclusions
1. The use of waste as a fuel leads to saving of primary resources and the reduction of CO 2 emissions.
2. From an economics point of view, it is clear that waste incineration is costly for society.
3. The use of waste as alternative fuels is carried out in total compliance with permits issues by relevant authorities and meets rigorous requirements according to EU and national law and regulations as well as according to the IPPC Directive.