DE102019216564A1 - Modular waste treatment plant - Google Patents

Abstract

A modular waste treatment plant (1) is proposed which comprises several modules (M0, ..., M7) for waste treatment, which are designed as mobile transport containers, with each of the modules (M0, ..., M7) having an interface ( 100, ..., 106), which enables a connection to one or more of the further modules (M0, ..., M7) for waste treatment. The invention also relates to a method for treating waste with a waste treatment plant (1).

Description

The invention relates to a modular waste treatment plant with several modules for waste treatment. The invention further relates to a method for waste treatment with a modular waste treatment plant according to the present invention.

Due to inadequate waste management in numerous developing and emerging countries, some of the waste finds its way into the environment through a wide variety of entry routes. Another part of the waste is typically landfilled or incinerated in an uncontrolled manner, i.e. without exhaust gas cleaning and without energy use. The resulting pollution has a negative impact on human health and the local economy. In view of the general infrastructure deficit in the regions mentioned, for example, energy is mostly generated by diesel generators and water is supplied by means of delivery of water tanks or water bottles.

In urban regions, due to the higher population density and the resulting larger amounts of waste, large stationary plants are operated for the material or energetic recycling of waste. In semi-urban and rural areas, additional challenges arise, in particular small amounts of waste (with regard to the catchment area), a low calorific value of the waste due to an increased organic content, a lower heat utilization potential, for example due to the geographical location, and hard-to-reach places due to poorer transport infrastructure.

Furthermore, a significant part of the waste is plastics, which, in contrast to organic waste, remain in the environment for much longer (up to 450 years), accumulate there and have therefore become a real problem for the local population, local tourism and in recent years / or have been fishing. Typically, there is no technical solution on site to recycle or recycle the smaller quantities of plastic materially or energetically.

The basic goal of waste treatment, recycling or waste management is to impair the environment as little as possible and to derive the greatest possible benefit from the waste. A distinction can be made between material and energetic recycling of the waste. In the case of material recycling, the materials are transformed into the waste without chemical changes (material recycling) or with chemical changes (raw material recycling), for example to manufacture new products. In the case of energy recovery, the chemical energy of the waste is at least partially converted into heat and electrical energy.

The typical form of waste treatment is the energetic recovery of the waste, that is, its incineration in large-scale plants. Modern large-scale plants have a throughput of around 100,000 tons per year, with a minimum lower calorific value of 7 megajoules per kilogram of waste to be incinerated. Furthermore, there are small combustion systems with a minimum throughput of 16,500 tons per year and a lower calorific value of 11 to 20 megajoules per kilogram. Smaller systems are characterized by a throughput of less than 10 tons per day.

In the case of large-scale systems, the loading is typically carried out by means of a crane, which feeds the waste from a refuse bunker (fuel bunker) into a furnace via a lock. Household refuse or garbage-like waste is typically burned by means of grate firing systems, for example by means of a wall grate, a roller grate, a moving grate or a counter-rotating grate. The combustion grate is constructed in such a way that preheated combustion air flows through it from below. The mobility of the grate bars or rollers not only enables the waste to be transported from the task to the ash discharge, but also enables the fuel (waste) to come into close contact with the combustion air. The partially burned-out flue gases are then mixed by adding secondary and, if necessary, tertiary air, so that complete burn-out is guaranteed. The flue gas is cooled in the connected waste heat steam generator (waste heat boiler). The steam generated is used to generate electricity or as process or heating steam. The flue gases are then passed on to exhaust gas cleaning (flue gas cleaning).

Furthermore, electrical energy can be generated from the combustion by means of the large-scale plant's steam generator, steam turbine and generator. The steam generator (or waste heat boiler) uses the heat contained in the flue gas. Typically, a waste heat boiler comprises a heat exchanger (evaporator) with which heat is transferred to a supplied feed water, which then boils. This generates saturated steam, which ultimately drives one or more steam turbines.

The present invention is based on the object of providing a mobile waste treatment plant with improved flexibility.

The task is achieved by a waste treatment plant with the features of the independent patent claim 1 and solved by a method for waste treatment with the features of independent claim 10. Advantageous configurations and developments of the invention are specified in the dependent claims.

The waste treatment plant according to the invention comprises several modules for waste treatment (treatment of waste), which are designed as standardized mobile transport containers, each of the modules having an interface that enables a connection to one or more of the further modules for waste treatment.

Waste treatment can be a material or energetic recovery of the waste, for example by recycling or incineration of the waste.

The transport containers are standardized, for example, if they have uniform and / or predetermined external dimensions. This enables effective production of the modules and simple transport of the modules.

According to the present invention, the waste treatment plant has a modular structure. This advantageously enables the waste treatment plant to be configured. In other words, this can be tailored as best as possible to the waste to be treated and / or to its place of use. This is possible because the modules can be connected to one another in a wide variety of ways via the interface according to the invention. In this case, the waste passes through one or more of the modules in series, that is to say one after the other and / or one or more modules in parallel, that is to say the waste is treated in parallel by the modules.

Due to the modular structure of the waste treatment plant according to the invention, environmentally harmful plastics, municipal waste and / or household waste can be efficiently treated and recycled in a particularly advantageous manner. It is conceivable that the waste treatment plant is tailored to the specific household waste in a residential area. Furthermore, the thermal energy released during combustion can be used efficiently depending on the region / location of use, for example for heat supply, power generation, cooling and / or seawater desalination. The use of the released thermal energy can thus be tailored to the local or regional demand for heat, electricity, cold and / or drinking water thanks to the large number of possible combinations of the modules. Furthermore, the waste is in particular not released into the environment in an uncontrolled manner, but rather burned in a controllable manner on site and controllable flue gas cleaning can take place.

Furthermore, the waste treatment plant according to the invention has a broader range of applications due to its mobility and modularity. In particular, the range of applications is covered more cost-effectively and efficiently due to the modularity. Due to the standardization of the modules, they can be manufactured more efficiently and in large numbers. The interface that enables modularity according to the invention can also be easy to assemble, for example by means of a screw connection and / or a clip connection. The individual modules are preferably designed less for particularly high efficiency and more for reliability and robustness. This is advantageous since the locations or areas of use or regions of use of the waste treatment plant according to the invention are typically remote and can only be reached with difficulty for repairs and / or maintenance. Furthermore, the amount of energy supplied is proportional to the waste disposed of or treated, so that higher energy consumption does not have any disadvantage in most applications.

The modularity also has the advantage of easier mobility of the waste treatment plant. This is the case because the waste treatment plant according to the invention can thereby be broken down into individual modules according to the invention. The modules are designed as standardized transport containers, so that after the interfaces have been released, they can be transported away without the modules themselves having to be dismantled and / or packaged.

Furthermore, the waste treatment plant according to the invention enables continuous charging and / or waste heat utilization, for example electricity generation and / or generation or provision of heat. The generated heat can be used as local or district heating, for example by means of a local heating network or district heating network.

According to an advantageous embodiment of the invention, the modules are designed as a fuel bunker, a waste sorting module, a shredder module, a waste incineration module, a recycling module, a generator module, a desalination module, a storage module and / or a cooling module.

The fuel bunker advantageously enables fluctuations in the fuel logistics chain to be compensated for. The fuel bunker can collect organic waste and inorganic waste via one or more input interfaces take in (inputs) and issue or provide organic and inorganic waste via one or more output interfaces (outputs), for example for further treatment by one or more of the modules.

The waste sorting module enables the separation of recyclable substances / materials, a mixture of inorganic and organic waste and / or the sorting out of critical materials for incineration and / or flue gas cleaning. Furthermore, the waste sorting module can also serve as a storage bunker. The waste sorting module can receive organic waste, inorganic waste and / or electrical energy (inputs) via one or more input interfaces. By means of one or more output interfaces, the waste sorting module can output recyclable waste / waste materials, organic and / or inorganic waste and non-recyclable fuels, together or separately from one another (outputs).

The shredder module is intended to shred and homogenize the mixed waste from the waste sorting module. In other words, the shredder module is connected or can be connected to the garbage sorting module via one or more interfaces, so that an output of the garbage sorting module is an input of the shredder module. Using one or more input interfaces, the shredder module can thus take up organic and / or inorganic waste and / or electrical energy (inputs). The shredder module provides combustible waste, in particular fuel pellets, via one or more output interfaces (outputs).

The waste incineration module is intended for the combustion of fuel (waste) and / or the fuel pellets of the shredder module. The combustion takes place within a defined temperature range. Furthermore, the waste incineration module can be provided for generating steam by means of the thermal energy released during the incineration. The generated steam can be provided for a steam turbine. In other words, the waste incineration module is connected or can be connected to the shredder module via one or more interfaces, so that an output of the shredder module is an input of the waste incineration module. The waste incineration module can thus receive the fuel pellets (inputs) by means of one or more input interfaces. Via one or more output interfaces of the waste incineration module, it provides thermal energy or heat, steam, for example saturated steam, slag and / or ash (outputs).

The recycling module is intended for material-specific sorting and / or material compression. The recycling module can absorb inorganic substances (inputs) using one or more input interfaces. This material is made available for a secondary raw material market (outputs) via one or more output interfaces of the recycling module.

The generator module is intended to generate electricity. For this purpose, for example, the steam generated by means of the waste incineration module, for example saturated steam, is used. In other words, the generator module is connected or can be connected to the waste incineration module via one or more interfaces, so that an output of the waste incineration module is an input of the generator module. The generator module can thus receive the steam or saturated steam (inputs) by means of one or more input interfaces. The generator module provides electrical energy and / or steam, in particular saturated steam, via one or more output interfaces of the generator module (outputs).

The desalination module is intended for the generation, provision and / or production of fresh water or drinking water. For example, a multi-effect distillation (MED) or reverse osmosis is used for this. The desalination module receives electrical energy, salty and / or contaminated water and steam, in particular saturated steam, by means of one or more input interfaces (inputs). This provides fresh water (treated water), drinking water and / or brine (outputs) via one or more output interfaces of the generator module.

The storage module is designed to store electrical energy, in particular to stabilize a higher-level power grid. In this way, load peaks and generation peaks can advantageously be reduced. The storage module is particularly preferably designed as a battery storage module. The storage module takes electrical energy, in particular electricity and / or electricity generated by the waste treatment plant, by means of one or more input interfaces from renewable sources. The memory module provides electrical energy (outputs) via one or more output interfaces.

The cooling module is intended to convert heat and / or electricity into cold. In other words, the cooling module provides cold, for example for air conditioning. The cooling module receives electrical energy, in particular electricity generated by the waste treatment plant and / or electricity from renewable generation sources, by means of one or more input interfaces. This provides cooling (outputs) via one or more output interfaces of the cooling module.

In an advantageous development of the invention, the waste treatment plant comprises a waste sorting module, a shredder module, a waste incineration module and a recycling module.

This can be called the basic configuration of the modular waste treatment plant. As a result, the waste treatment plant can advantageously be used for waste recycling or waste disposal without using a fuel for energy. The basic configuration enables the volume of non-recyclable materials / substances to be reduced. As a result, landfills can advantageously be avoided or their size can be reduced. The basic configuration thus comprises at least four transport containers and a sufficient number of fuel bunkers.

According to an advantageous embodiment of the invention, the waste treatment plant is designed as a basic configuration and additionally includes a generator module. The waste treatment plant thus comprises at least five transport containers and a sufficient number of fuel bunkers.

As a result, the waste treatment plant can also be used to generate electricity, for example for feeding into a power grid, for island operation and / or for storage by means of an electricity storage system. This advantageously enables a simple energetic use / conversion of waste to electricity and a stable feed into a higher-level existing power grid.

In an advantageous development of the invention, the waste treatment plant additionally comprises a storage module, in particular a battery module.

As a result, the electricity generated can advantageously be temporarily stored at least partially. Furthermore, a higher-level power grid can be stabilized in an improved manner, in particular when there is a high proportion of renewable electricity and / or an island grid can be set up and / or supported. The waste treatment plant thus comprises at least six transport containers and a sufficient number of fuel bunkers.

In an advantageous development of the invention, the waste treatment plant also includes a desalination module.

As a result, the waste treatment plant can generate or provide fresh water or drinking water in addition to generating electricity. In other words, the generated thermal energy and / or the generated electricity is used to produce fresh water or drinking water. Excess electrical energy can be fed in and / or one or more battery modules can be charged. The number of memory modules used here can be scaled depending on the application and requirement, in particular customer-specific. The waste treatment plant thus comprises at least seven transport containers and a sufficient number of fuel bunkers.

Furthermore, alternative or additional combinations of the modules mentioned are provided and conceivable. Several basic configurations could be used or set up in parallel. As a result, the capacity of the waste treatment plant can advantageously be scaled or operated redundantly. In the event of a malfunction or during maintenance work, the generation of electrical power, heat and / or fresh water could thus be maintained.

The mentioned combinations or configurations of the waste treatment plant can also each include a suitable or sufficient number of fuel bunkers.

In other words, according to a further embodiment of the invention, the waste treatment plant comprises a plurality of fuel bunkers.

Typical fuel bunkers have a capacity of 10 tons to 20 tons, although this depends on the composition of the waste to be stored, i.e. on its density. A fuel bunker could thus provide waste for the waste treatment plant for a few hours to two days. Stacking of the fuel bunkers and / or the modules is also possible and advantageous, for example for their transport.

According to an advantageous embodiment of the invention, the modules are designed as ISO standard containers, in particular as 10 feet, 20 feet, 40 feet, 45 feet and / or 53 feet ISO containers.

This advantageously enables efficient transport of the modules, for example by means of trucks, trains and / or ships, to their intended place of use. The waste treatment plant, which is made up of the modules transported to the place of use, can be set up on site, i.e. at the place of use. Particularly preferred here are 20 foot containers that for example open at the top, or horizontally halved 20 foot containers. Furthermore, modules that are designed as 40 foot containers are of particular advantage. The number of containers required can vary depending on the application; for example, longer logistics routes require more transport containers / fuel bunkers. Furthermore, the number of fluctuations in the fuel supply depends, since larger and / or more fuel bunkers are required if the fuel supply fluctuates significantly. This is the case, for example, with seasonal different occupancy rates, for example in tourist regions / areas. Due to the modular structure of the present waste treatment plant, the storage capacity is more scalable.

It is preferred if the modules can be transported by truck, train and / or ship.

As a result, a large number of locations can be reached, so that the present waste treatment plant can be set up and used almost anywhere.

In an advantageous development of the invention, the modules are only connected to the waste treatment plant via their respective interfaces at the intended place of use of the waste treatment.

According to an advantageous embodiment of the invention, the waste treatment plant is set up at the sea or on the sea surface.

In other words, the modules of the waste treatment plant at the sea or on the sea surface are preferably connected to one another via their interfaces to the waste treatment plant.

The place of use by the sea or near the sea or on the sea surface has the advantage that there is typically a large amount of waste (fuel) in the sea that can be used. This results in the further advantage that the sea can be at least partially cleaned of waste, in particular plastic (marine plastic).

It is particularly preferred here to use marine plastic as fuel for the waste treatment plant, that is to say that marine plastic is preferably treated, in particular banned, by means of the waste treatment plant. The present waste treatment plant is advantageous here because there is typically not a sufficient amount of marine plastic for efficient operation of larger or known waste treatment plants on site. Furthermore, electrical energy and / or heat can also be provided for remote and / or difficult to reach or difficult to access areas. The electrical energy and / or heat generated by the treatment / incineration of the marine plastic is preferably used for a desalination plant. The incineration of marine plastic can thus be combined synergistically with the operation of a desalination plant, in particular a desalination module of the waste treatment plant.

In an advantageous development of the invention, the waste treatment generates electrical power and / or heat that is used for island operation of an island network and / or for seawater desalination, preferably for a desalination module of the waste treatment plant.

As a result, drinking water or treated water can advantageously be provided and at the same time the sea can be cleaned of marine plastic, so that the combustion of the marine plastic works synergistically with the desalination plant or with the desalination module of the waste treatment plant.

According to an advantageous embodiment of the invention, the waste is at least partially comminuted, ground, agglomerated, briquetted, pelletized, classified, sorted, dedusted, dewatered, mixed, equalized and / or burned.

As a result, the waste is advantageously treated, with a module of the waste treatment plant being able to carry out one or more of the above-mentioned treatments or treatment steps, that is to say is designed to do so.

Furthermore, a material-specific preparation / treatment of the waste is necessary for the best possible material or energetic recovery of the waste. The better the waste is shredded or agglomerated, classified and sorted, the better the recycling or incineration behavior of the waste.

Further advantages, features and details of the invention emerge from the exemplary embodiments described below and with reference to the drawing. The single FIGURE shows a schematic Sankey diagram of a waste treatment plant according to an embodiment of the present invention.

Identical, equivalent or equivalent elements can be provided with the same reference symbols in the figure.

The figure shows a Sankey diagram of a waste treatment plant 1 according to an embodiment of the present invention.

The waste treatment plant 1 comprises several modules M0 , ..., M7 . The modules M0 , ..., M7 are designed as ISO standard containers. Furthermore, the modules M0 , ..., M7 each has an interface that relates to the treatment of waste 100 modular merger / connection of the modules M0 , ..., M7 enables.

The zeroth module M0 is designed as a fuel bunker. Thus is the zeroth module M0 for receiving and storing waste 100 intended. Furthermore, depending on the volume of waste 100 several zeroth modules M0 be provided.

The first module M1 is designed as a waste sorting module. The trash 100 is from one or more of the zeroth modules M0 (Fuel bunker) via an interface to the first module M1 guided. In other words, they are the zeroth module M0 and the first module M1 via the interface for exchanging waste 100 connected with each other. The first module M1 is intended, for example, to separate recyclable materials and / or to sort out critical materials. With others is done by means of the first module M1 an initial sorting of the waste 100 . To operate the first module M1 is typically electrical energy / electricity 103 required so the first module M1 also has a corresponding interface for this purpose. In the present exemplary embodiment, the first module separates M1 trash 100 from the zeroth module M0 in two material flows, namely in plastics 102 and in a sorted garbage 106 .

The plastics 102 (Secondary plastic) become the fourth module M4 guided. In other words, are the first module M1 and the fourth module M4 connected to each other via an interface for transporting plastics. The fourth module M4 is designed as a recycling module. This will make the plastic 102 inside the trash 100 reusable.

The sorted garbage 106 becomes the second module M2 continued. In other words, are the first module M1 and the second module M2 via an interface for exchanging sorted waste 106 connected or coupled to one another. The second module M2 is designed as a shredder module. Thus, by means of the second module M2 the sorted garbage 106 crushed and homogenized. The shredded and homogenized waste is in the form of fuel pellets through the second module M2 provided. To operate the second module M2 is still electrical energy 103 required.

The fuel pellets from the second module M2 become the third module M3 guided. In other words, are the second module M2 and the third module M3 connected to each other via an interface for exchanging the fuel pellets. The third module M3 is designed as a waste incineration module. In other words, the fuel pellets are made by means of the third module M3 burned. Here is heat 105 and / or steam generated by the fifth module M5 is fed. The flue gas generated during combustion can also be fed to a flue gas cleaning system.

The fifth module M5 is designed as a generator module, in particular as a steam turbine module. Creates the fifth module M5 As in the present case, the steam, so must water 101 the fifth module M5 are fed. Out of the water 101 and the heat released when the fuel pellets are burned 105 steam is generated that drives a steam turbine. In other words, are the third module M3 and the fifth module M5 connected to one another via an interface for exchanging heat, for example via a heat exchanger. The fifth module M5 thus generates electricity 103 . Furthermore, there is a residual waste heat 105 . The generated electric current 103 as well as the remaining waste heat 105 are through the fifth module M5 provided.

The one through the fifth module M5 generated electric power 103 becomes the sixth module M6 and to the seventh module M7 guided. In other words, it is the fifth module M5 with the sixth module M6 and the seventh module M7 via an interface, for example a power cable, for exchanging electrical power 103 connected with each other.

The sixth module M6 is designed as a battery storage. This allows the through the fifth module M5 generated electric power 103 be cached. In particular, the sixth module M6 an interface for exchanging electrical power 103 to the first module M1 and to the second module M2 on. In other words, represents the sixth module M6 at least partially for the operation of the first and second modules M1 , M2 required electrical power 103 at least partially ready. This enables isolated operation, that is to say operation of the waste treatment plant and / or further energy conversion plants (at least over a period of time) that is independent of a higher-level power grid. Alternatively and in addition, the sixth module M6 an interface for the exchange of electrical energy with a superordinate and with regard to the waste treatment plant 1 external power grid 2 exhibit. This means that excess electricity can be fed in and, for example, as control power for the higher-level power grid 2 be used.

The seventh module M7 is designed as a desalination module. For desalination of water 101 or sea water, for example by means of reverse osmosis or by means of thermal processes, heat and electricity is typically required, at least partially through the fifth module M5 to be provided. In other words, it is the fifth module M5 via one or more interfaces for exchanging heat and electricity with the seventh module M7 connected. The through the fifth module M5 generated heat 105 (Waste heat or residual heat) that originally resulted from the combustion of the fuel pellets, as well as that from the fifth module M5 generated electric power 106 are thus used for the desalination or treatment of water 105 used. The treated water 104 can be provided as drinking water, or again to the fifth module M5 to be supplied for steam generation. This has the advantage that clean water with a low salt content is typically advantageous for steam generation, since this means that the steam turbines and other components of the system or of the module show less wear.

The present waste treatment plant 1 thus enables an extensive and holistic treatment of waste, whereby electrical energy 103 , Warmth 105 or waste heat 103 as well as drinking water or treated water 104 can be generated and provided. As a result, the essential energy quantities can be generated from waste and made available on site, especially in regions that are difficult to reach and isolated. The waste treatment plant is particularly advantageous here 1 to be used for the treatment / incineration / recovery of marine plastic. As a result, the cleaning of the oceans of marine plastic is advantageously combined synergistically with the need for electricity, heat and drinking water on site. This is made possible by the modules designed as mobile transport containers and the modular design of the waste treatment plant 1 according to the present invention and / or one of its configurations.

Although the invention has been illustrated and described in more detail by the preferred exemplary embodiments, the invention is not restricted by the disclosed examples or other variations can be derived from them by the person skilled in the art without departing from the scope of protection of the invention.

List of reference symbols

M0

zeroth module (fuel bunker)

M1

first module (garbage sorting)

M2

second module (shredding)

M3

third module (waste incineration)

M4

fourth module (recycling)

M5

fifth module (power generation)

M6

sixth module (desalination)

M7

seventh module (power storage)

1

Waste treatment plant

2

power grid

100

waste

101

water

102

plastic

103

electrical power

104

Recycled water

105

Heat / waste heat

106

Sorted waste

Claims (15)

Waste treatment plant (1), comprising several modules (M0, ..., M7) for waste treatment, which are designed as standardized mobile transport containers, each of the modules (M0, ..., M7) having an interface (100, ..., 106), which enables a connection to one or more of the further modules (M0, ..., M7) for waste treatment. Waste treatment plant (1) according to Claim 1 , characterized in that the modules (M0, ..., M7) as a fuel bunker (M0), as a waste sorting module (M1), as a shredder module (M2), as a waste incineration module (M3), as a recycling module (M4), as a generator module (M5 ), as a desalination module (M6), as a storage module (M7) and / or as a cooling module (M8). Waste treatment plant (1) according to Claim 1 or 2 , characterized in that it comprises a waste sorting module (M1), a shredder module (M2), a waste incineration module (M3) and a recycling module (M4). Waste treatment plant (1) according to Claim 3 , characterized in that it further comprises a generator module (M5). Waste treatment plant (1) according to Claim 4 , characterized in that this continues a storage module (M6), in particular a battery module. Waste treatment plant (1) according to Claim 5 , characterized in that it further comprises a desalination module (M7). Waste treatment plant (1) according to one of the Claims 3 to 6th , characterized in that it further comprises several fuel bunkers (M0). Waste treatment plant (1) according to one of the preceding claims, characterized in that the modules (M0, ..., M7) as ISO standard containers, in particular as 10 feet, 20 feet, 40 feet, 45 feet and / or 53 feet ISO Containers, are formed. Waste treatment plant (1) according to one of the preceding claims, characterized in that the modules (M0, ..., M7) can be transported by means of trucks, trains and / or ships. Method for waste treatment with a waste treatment plant (1), wherein the waste treatment plant (1) comprises several modules (M0, ..., M7) which are designed as standardized transport containers, and in which each of the modules (M0, ..., M7 ) can be connected via an interface (100, ..., 106) to at least one of the further modules (M0, ..., M7) for waste treatment. Procedure according to Claim 10 , characterized in that the modules (M0, ..., M7) are only connected to the waste treatment plant via their respective interfaces (100, ..., 106) at the intended location of the waste treatment. Procedure according to Claim 10 or 11 , characterized in that the waste treatment plant (1) is built on a sea or on the sea surface. Method according to one of the Claims 10 to 12th , characterized in that marine plastic is treated, in particular incinerated, by means of the waste treatment plant (1). Method according to one of the Claims 10 to 13th , characterized in that the waste treatment generates electrical power that is used for island operation of an island network and / or for seawater desalination. Method according to one of the Claims 10 to 14th , characterized in that the waste is at least partially crushed, ground, agglomerated, briquetted, pelletized, classified, sorted, dedusted, dewatered, mixed, equalized and / or burned.

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