EP4345147A1 - Continuous process for the recovery of secondary resources from waste containing organic compounds by means of oiling - Google Patents

Abstract

The invention relates to a continuous process for the extraction of secondary resources from waste containing organic compounds in a mass fraction of at least 60% as starting material (A) by oilification to obtain a product oil (P) in a two-part reactor (R) with a first, lower region (I), in which a start-up oil is introduced up to a height of at least half the total height of the same, and with a second upper region (II), which is connected to the lower region (I) and which contains no liquid during start-up, into which the reactor contents (RI) are pumped from the lower end of the first, lower region (I) of the two-part reactor (R) via one or more external pipelines (1) by means of one, two or more pumps (2) with a ratio of directed to undirected pulse power in the range of 1/6 to 1/2, with product vapor being withdrawn from the upper end of the second upper region (II) of the two-part reactor (R), which is then quenched with a cold partial flow of product oil (P), wherein the product oil (P) is obtained by first heating the start-up oil to an operating temperature in the range from 280 to 420 °C by pumping it through one, two or more pumps (2), whereupon the previously prepared starting material (A) is continuously fed into the first, lower region (I) of the two-part reactor (R) below the liquid level, and wherein the reactor contents (RI) are pumped from the lower end of the first, lower region (I) of the two-part reactor (R) into the second, upper region (II) of the two-part reactor (R) in such a way that the ratio of the feed residence time of the starting material (A) to the pumping residence time of the reactor contents (RI) is in the range from 250:1 to 5000:1.

Description

The invention relates to a process for the recovery of secondary resources from waste containing organic compounds.

The state of the art in the thermal treatment of residual waste is waste incineration.

However, especially in the wake of growing ecological problems and resource scarcity, it is becoming increasingly urgent not only to dispose of waste or to use it thermally, but also to make it usable as a source for secondary resource extraction.

The so-called oiling process, also known as catalytic pressureless oiling (KDV) or thermocatalytic low-temperature conversion (NTK), has proven to be particularly advantageous for this, i.e. a technical depolymerization process according to which artificial or natural polymers and long-chain hydrocarbons are processed with the addition of a zeolitic catalyst at temperatures of less than 400 °C without excess pressure into shorter-chain aliphatic (more preferred, others such as aromatic ones will also be formed in traces) hydrocarbons, comparable to synthetic light oil. (see "Oilation", retrieved from Wikipedia on January 25, 2022).

An overview of processes currently offered or operated in Germany can be found, for example, in the final report of the Federal Environment Agency on "Evaluation of new developments in alternative thermal waste treatment plants with a focus on oiling processes" by M. Pohl and P. Quicker (Texts 77/2018, project number 82615, UBA-FB 002679). According to the process examined in detail there, also known as "Catalytic Tribochemical Conversion" (CTC), operated by Dieselwest GmbH (renamed CARBOWEST GmbH in 2021), residual waste is first processed in several stages, i.e. crushed, sieved to a grain size of a maximum of 2 mm, iron - and non-ferrous metals separated, additives in the form of synthetic or natural zeolites as catalysts and quicklime as a neutralizer are added and dried to a water content of less than 2%. The oiling process itself is carried out in the liquid phase in a reactor which is formed from two cylindrical vessels which taper conically at the bottom and which are arranged one above the other. Starting oil is presented. Before the processed residual waste is fed in, this is first heated to the reaction temperature (320 to 420 ° C depending on the starting material) by several energy input devices, in particular turbines and/or pumps, with which the reactor contents are constantly mixed and pumped around. The processed residual waste is fed into the lower area of the reactor using a screw below the liquid level. This ensures that the material supplied mixes with the oil supplied and a suspension is created, which is sucked in at the lower end of the reactor via the turbines or pumps and injected back into the upper part of the reactor via external lines and connected nozzles. The intensive mixing breaks up the polymers and evaporates as soon as the chain length is sufficiently short. The vapors are drawn off at the top of the reactor using a slight negative pressure and condensed using a spray cooler to obtain the product oil. However, this does not have a constant quality and the ability of the system to operate continuously could not be demonstrated.

In contrast, the object of the invention was to provide an oil conversion process for the extraction of secondary resources from waste containing organic compounds as starting material, which can be operated continuously and which ensures a uniform quality of the product oil with regard to the maximum permissible oxygen and nitrogen content as well as the minimum calorific value, provided that the starting material used contains organic compounds in a mass fraction of at least 60%. In particular, the oxygen content in the product oil should not exceed a mass fraction of 4% and the nitrogen content a mass fraction of 1.2%, and the minimum calorific value of the same should be 41 MJ/kg.

• und mit einem zweiten, oberen Bereich, der mit dem unteren Bereich verbunden ist und der beim Anfahren keine Flüssigkeit enthält, in welchen über jeweils eine oder mehrere externe Rohrleitung(en) mittels jeweils einer, zweier oder mehrerer Turbinen oder Pumpen mit einem Verhältnis von gerichteter zu ungerichteter Impulsleistung im Bereich von 1/6 bis 1/2 der Reaktorinhalt vom unteren Ende des ersten, unteren Bereichs des zweigeteilten Reaktors umgepumpt wird,
• unter Abzug von Produktdampf vom oberen Ende des zweiten, oberen Bereichs des zweigeteilten Reaktors, der anschließend mit einem kalten Teilstrom von Produktöl abgequencht wird, wobei das Produktöl erhalten wird,
• indem das Anfahröl zunächst durch Umpumpen über die eine, zwei oder mehreren Pumpen oder Turbinen auf eine Betriebstemperatur im Bereich von 280 bis 420°C aufgeheizt wird, worauf das aufbereitete Ausgangsmaterial kontinuierlich in den ersten, unteren Bereich des zweigeteilten Reaktors unterhalb des Flüssigkeitsspiegels zugeführt wird,
• und wobei der Reaktorinhalt vom unteren Ende des ersten, unteren Bereichs des zweigeteilten Reaktors in den zweiten, oberen Bereich des zweigeteilten Reaktors umgepumpt wird, dergestalt, dass das Verhältnis der Zulaufverweilzeit des Ausgangsmaterials zur Umpumpverweilzeit des Reaktorinhalts im Bereich von 250 zu 1 bis 5000 zu 1 liegt.

This object is achieved by a continuous process for the recovery of secondary resources from waste containing organic compounds in a mass fraction of at least 60% as starting material by oilification to obtain a product oil in a two-part reactor with a first, lower region, in which a start-up oil is introduced up to a height of at least half the total height of the same,

• and with a second, upper area, which is connected to the lower area and which does not contain any liquid when started up, into which the reactor contents are pumped from the lower end of the first, lower section of the two-part reactor via one or more external pipelines by means of one, two or more turbines or pumps with a ratio of directed to undirected pulse power in the range of 1/6 to 1/2,
• withdrawing product vapour from the upper end of the second, upper section of the two-part reactor, which is then quenched with a cold partial stream of product oil to obtain the product oil,
• by first heating the start-up oil to an operating temperature in the range of 280 to 420°C by pumping it through one, two or more pumps or turbines, whereupon the processed starting material is continuously fed into the first, lower section of the two-part reactor below the liquid level,
• and wherein the reactor contents are pumped from the lower end of the first, lower region of the two-part reactor to the second, upper region of the two-part reactor such that the ratio of the feed residence time of the starting material to the pumping residence time of the reactor contents is in the range from 250 to 1 to 5000 to 1.

The invention is based on known oiling processes for processing waste containing organic compounds, in particular the so-called "Dieselwest" process, which was presented in the above-mentioned final report of the Federal Environment Agency "Evaluation of new developments in alternative thermal waste treatment plants with a focus on oiling processes" by M. Pohl and P. Quicker (Texte 77/2018, project number 82615, UBA-FB 002679).

Any waste can be used as starting material, provided it contains organic compounds in a mass proportion of at least 60%. Starting materials with organic compounds in a mass fraction of at least 80%, more preferably at least 90%, are preferred, in particular starting materials containing artificial organic compounds in a mass fraction between 60 and 80% and natural organic compounds in a mass fraction between 0 and 30%.

These are usually long-chain organic compounds, in particular petrochemical waste materials, organic municipal waste, sewage sludge, plant biomass, especially waste from agriculture and forestry, biologically renewable fats and oils and animal biomass.

Long-chain organic compounds are usually understood to be polymers that are made up of several hundred to 4000 similar molecular units, the monomers. The artificial polymers in this case are in particular mixtures of low-density polyethylene, high-density polyethylene, polypropylene, polystyrene, polyisobutene, polyethylene terephthalate, polyamide 6, polyamide 6.6 and/or plastic waste based on isocyanates, which, due to their material properties and the associated production, are formed from around 2000 to 4000 of the respective monomer units.

In one embodiment, the starting material can contain municipal waste, in particular non-sortable plastic parts thereof, in particular sorting fractions which are separated due to their dimensions and/or film residues and/or black sorting residues which cannot be detected by near-infrared spectroscopy, and/or commercial waste, in particular production waste, preferably waste from the recycling of passenger cars, in particular lightweight car shredder material.

The waste used as starting material often contains, in addition to organic compounds, inert substances, fillers, metals and/or residual moisture, in particular inert substances and/or fillers in a mass proportion of 0 to 10%, preferably less than 1%, metals in a mass proportion of 0 to 1%, preferably less than 1%, and residual moisture in a mass fraction of 0 to 10%, preferably less than 1%.

In addition, the starting material (A) can additionally contain, as inert materials, silicon dioxide in the form of quartz sand or building materials and/or aluminum oxide and/or calcium hydroxide and/or hollow glass and/or ceramic spheres, glass and/or carbon fibers and/or rubber particles as fillers also contain metallic materials, in particular magnetic and non-magnetic metal composite materials and/or aluminum-coated materials.

In a preferred embodiment, the above inert and/or fillers are added to the waste used as starting material in order to adjust various properties, such as strength and extensibility.

Before being fed into the reactor, the starting material is processed in several stages in advance in a known manner, in particular as in the "Dieselwest" process described above, i.e. crushed, sieved to a grain size of a maximum of 2 mm, ferrous and non-ferrous metals are separated, additives in the form of synthetic or natural zeolites as catalysts and quicklime as a neutralizer are added and the starting material is finally dried to a water content of less than 2%.

The oiling process is carried out in a two-part reactor with a first, lower and a second, upper area, which is preferably directly connected to the first, lower area. Advantageously, the first, lower and/or the second, upper area each taper at the bottom to allow the fluid to drain off during cleaning work and downtimes.

The opening connecting the two regions preferably has a diameter of at least 1/5 of the diameter of the second, upper region, preferably of at least 1/3 of the diameter of the second, upper region.

In one embodiment, both reactor regions can be integrated into a common reactor shell.

Advantageously, the first, lower region of the two-part reactor can have a height to diameter ratio of 3:1 to 1:3, preferably 1.5:1, and can in particular be designed as a standing or lying cylinder.

In the second, upper area, the reactor contents are fed from the lower end via one or more external pipelines using one, two or more pumps or turbines with a ratio of directional to non-directional pulse power in the range of 1/6 to 1/2 the first, lower area of the two-part reactor.

For commissioning, a starting oil is placed in the first, lower area up to a height of at least half of the total height of the same, preferably up to a height of at least 2/3 of the total height of the same.

The starting oil is advantageously a mixture of product oil and a mineral oil with a boiling point greater than 280 ° C, preferably in a mass ratio of 10% mineral oil to 90% product oil to 90% mineral oil to 10% product oil, in particular 50% Mineral oil to 50% product oil is used.

The start-up oil is first heated by pumping over one, two or more pumps to an operating temperature in the range of 280 to 420 ° C, whereupon the previously prepared starting material is continuously fed into the first, lower region of the two-part reactor below the liquid level, preferably above one or more snails. Alternatively, the pre-processed starting material can also be fed via one or more extruders.

The reactor contents are continuously transferred from the lower end of the first, lower region of the two-part reactor into the second, upper region of the two-part reactor via the one or more external pipelines by means of one, two or more pumps and/or turbines Ratio of directional to non-directional pulse power pumped in the range of 1/6 to 1/2.

Preferred pumps are liquid ring vacuum pumps, impeller pumps with a recessed impeller, rotary piston pumps and screw spindle pumps. The directed pulse power is determined by the delivery pressure (pressure loss) and the volume flow in relation to the pump power applied. The undirected pulse power is also referred to by experts as dissipated power.

The advantage of this energy input is the homogeneous heating of the fluid from the inside to the outside; there are no hot walls as with external heating methods via the wall. The second significant advantage of the direct dissipative energy input is the high mixing and stress on the starting material.

The required heat of fusion is provided by the surrounding fluid. The high mixing performance of the pumps causes the introduced solid particles to be crushed and torn apart in the pumped flow. The catalyst particles are also mixed and crushed with the introduced and melted solid particles. The high shear forces and cavitation caused by peripheral speeds of around 15 to 20 m/s and the sudden evaporation and condensation on the pumping elements cause the original long-chain organic compounds to crack from the introduced solid particles in the liquid phase. The high shear rates also mean that the active centers of the catalysts are continuously renewed. As a result, For example, low-density polyethylene waste with originally typically 2000 to 4000 monomer units is cracked to an average of 3 to 16 monomer units.

What is essential to the invention is that the process is carried out in such a way that the ratio of the feed residence time of the starting material to the pumped residence time of the reactor contents is in the range from 250 to 1 to 5000 to 1, i.e. H. The pumping of the reactor contents takes place much faster than the supply of the starting material. This is crucial in order to achieve the high shear rates required for the depolymerization processes explained above.

The feed residence time is defined by the ratio of total reactor volume to the feed volume flow of the feed materials.

The pumping residence time is defined by the ratio of the total liquid reactor volume to the total pump volume flow. The total liquid reactor volume as well as the total pump volume flow are determined by mass flow meters (mass flow meters), for example standard Coriolis mass flow meters. The pumping residence time is divided into the pumping residence time in the first, lower region of the two-part reactor and the pumping residence time in the second, upper region of the two-part reactor.

Ratios of the feed residence time of the starting material to the circulation residence time of the reactor contents in the range from 250 to 1 to 5000 to 1 are preferred.

The process is preferably operated in such a way that the pumping residence time of the reactor contents is in the range from 15 to 55 seconds, more preferably in the range from 25 to 40 seconds. Accordingly, the feed residence times of the starting material are preferably in the range from about 2 hours to about 75 hours.

The liquid pumped flow is slightly overheated as it flows through due to the undirected energy input through the pumps and is expanded into the second, upper region of the two-part reactor by a small pressure difference. The liquid jet bursts and spreads over the existing wall surface in the second, upper area of the two-part reactor, and the low boilers can escape more easily.

The surface load B is understood to be the throughput of the pumped volume flow based on the area, in this case the area of the inner walls in the second, upper region of the two-part reactor.

By advantageously adjusting the surface load B of the pumping flow in the second, upper region of the two-part reactor via the volume flow of the same and via the geometry of the second, upper region of the two-part reactor to a value in the range of 25 m3 / m2 / h to 250 m3 / m2 /h, preferably to a value of around 100 m3/m2/h, optimal results are achieved with regard to the physical-chemical processes described above, and thus the splitting of the long-chain polymers.

It is further preferred that the inner walls of the two-part reactor in the second, upper region thereof are partially or completely heated and/or wetted with product oil. This supports the evaporation of more volatile hydrocarbons.

The vapors are continuously removed from the second, upper area of the two-part reactor and condensed in a known manner, in particular in a spray cooler, to obtain the product oil. A multi-stage spray cooler is particularly advantageous.

The residue from the first, lower section of the two-part reactor is advantageously discharged and allowed to settle as needed or at regular intervals and the supernatant oil mixture is returned to the first, lower section of the two-part reactor.

The reactor contents or a partial stream of the reactor contents are advantageously pumped back tangentially into the upper third of the second, upper region of the two-part reactor. As a result, a high distribution on the surface of the second, upper region of the two-part reactor and thus good outgassing of the products produced can be achieved.

In a preferred embodiment, only a first partial flow of 20 to 80% of the reactor contents is pumped from the lower end of the first, lower region of the two-part reactor into the second, upper region of the two-part reactor and a second partial flow of 80 to 20%, preferably 60 up to 70% of the reactor contents from the lower end of the first, lower area of the two-part reactor into the first, pumped back to the lower area of the two-part reactor. This driving style results in better mixing and better distribution of the input starting material between the pumps.

In an advantageous embodiment, the second, upper region of the two-part reactor can be used as a single-stage or multi-stage separation column by providing a separable flange over which one or more horizontal perforated plates can be inserted. Perforated plates with an opening ratio of 20 to 40% are advantageously used.

In a further advantageous embodiment, a central pipe via a separable flange can be used to supply the pumped flow. This can prevent unwanted foaming.

The continuous process according to the invention makes it possible, in particular, for the oxygen content in the product oil to be lower by 40 to 90%, in particular by 80%, compared to the starting material, and for the nitrogen content in the product oil to be lower by 50 to 80%, in particular by 70%, compared to the starting material.

Likewise, the continuous process according to the invention makes it possible in particular to obtain a product oil having a calorific value between 41 and 46 megajoules per kilogram, preferably of about 45 megajoules per kilogram.

According to the continuous process according to the invention, the formation of polycyclic aromatic hydrocarbons, in particular naphthalene, acenaphthalene, acenaphthene, fluorene, phenanthrene, anthracene, fluoranthene, pyrene and/or benzo(a)pyrene, is minimized, in particular in the product oil, and the sum of the polycyclic aromatic hydrocarbons is between 100 and a maximum of 1000 ppm, preferably a maximum of 600 ppm.

The invention is explained in more detail below using embodiments and a drawing.

The drawing shows in detail:
Figure 1 a schematic representation of a preferred reactor for carrying out the process according to the invention and the Figures 2A and 2B Cross-sectional representations through two preferred embodiments of reactors for carrying out the process according to the invention.

Figure 1 shows a two-part reactor R with a first, lower area I and a second, upper area II.

The starting material A is continuously fed via a conveyor screw into the first, lower section I of the two-part reactor R below the liquid level therein.

The reactor contents RI are pumped from the first, lower region I of the reactor R into the second, upper region II of the reactor R via an external pipeline 1 using a pump 2. Product vapor is withdrawn from the upper end of the second, upper region II of the reactor R and quenched with a partial stream of cold product oil, obtaining the product oil P, which is withdrawn.

In the cross-sectional views in the Figures 2A and 2B A version with 4 pumps and two spray coolers (in Figure 2A ) or a version with 4 pumps and a spray cooler (in Figure 2B ) is shown.

Example 1:

As starting material A, a total of 25 tons of a substitute fuel according to RAL 724 with the material data according to column 1 of Table 1 below were used in a two-part reactor R as in Figure 1 The pumping residence time was on average 41 s at a reactor temperature of 360 °C.

Column 2 lists the corresponding material data for the product oil (P) obtained Table 1: Source material Product oil Calorific value in megajoules per kilogram 39.1 44.9 Moisture in percent by weight 2 0.25 Inert substances in percent by weight 3 0.1 (bulk) density in kilograms per cubic meter 38 822 C (measured value) in percent by weight 77.10 83.3 H (measured value) in percent by weight 12.90 13.2 N (measured value) in percent by weight 1.72 1.11 O (measured value) in percent by weight 7.0 1.7 Plastic in percent by weight 86.1 Biomass in percent by weight 13.9 Metals in percent by weight 0.0

The material data shows a significant reduction in the nitrogen and especially the oxygen content in the product oil as well as a significant increase in the calorific value.

Example 2:

As starting material A, a total of 20 tons of a substitute fuel according to RAL 724 with the material data according to column 1 of Table 2 below were used in a two-part reactor as in Figure 1 The pumping residence time was on average 35 s at a reactor temperature of 380 °C.

Column 2 of Table 2 lists the corresponding material data for the product oil obtained Table 2 Source material Product oil Calorific value in megajoules per kilogram 39.1 44.7 Moisture in percent by weight 2.0 0.25 Inert substances in percent by weight 1.5 0.1 (bulk) density in kilograms per cubic meter 38 822 C (measured value) in percent by weight 77.10 84.0 H (measured value) in percent by weight 12.90 13.3 N (measured value) in percent by weight 1.72 1.18 O (measured value) in percent by weight 7.0 1.3 Plastic in percent by weight 66.7 Biomass in percent by weight 30.2 Metals in percent by weight 0.9

The material data show a significant reduction in the nitrogen and especially the oxygen content in the product oil as well as a significant increase in the calorific value.

Claims (17)

Continuous process for the extraction of secondary resources from waste containing organic compounds in a mass fraction of at least 60% as starting material (A) by oiling to obtain a product oil (P) in a two-part reactor (R) with a first, lower region (I), in which a start-up oil is presented up to a height of at least half of the total height of the same, and with a second upper area (II), which is connected to the lower area (I) and which does not contain any liquid when starting up, in which one or more external pipes (1) are in each case by means of one, two or more Pumps (2) with a ratio of directional to non-directional pulse power in the range of 1/6 to 1/2 of the reactor contents (RI) are pumped from the lower end of the first, lower region (I) of the two-part reactor (R), with product vapor withdrawn from the upper end of the second upper region (II) of the two-part reactor (R), which is then quenched with a cold partial stream of product oil (P), whereby the product oil (P) is obtained, by first heating the start-up oil to an operating temperature in the range of 280 to 420 ° C by pumping it over one, two or more pumps (2), whereupon the previously prepared starting material (A) is continuously pumped into the first, lower region (I). is fed into a two-part reactor (R) below the liquid level, and wherein the reactor contents (RI) are pumped from the lower end of the first, lower region (I) of the two-part reactor (R) into the second upper region (II) of the two-part reactor (R), such that the ratio of the feed residence time of the starting material (A) for the circulation residence time of the reactor contents (RI) is in the range from 250 to 1 to 5000 to 1. Continuous process according to claim 1, characterized in that the waste used as starting material (A) contains organic compounds in a mass fraction of at least 80%, preferably of at least 90%, in particular artificial organic compounds in a mass fraction between 60 and 80% and natural organic compounds in a mass fraction between 0 and 30%, contain. Continuous process according to claim 1 or 2, characterized in that the waste used as starting material (A) contains, in addition to organic compounds, inert substances, fillers, metals and/or residual moisture, in particular inert substances and/or fillers in a mass fraction of 0 to 10%, preferably less than 1%, metals in a mass fraction of 0 to 1%, preferably less than 1%, and residual moisture in a mass fraction of 0 to 10%, preferably less than 1%. Continuous process according to one of claims 1 to 3, characterized in that the starting material (A) additionally contains, as inert materials, silicon dioxide in the form of quartz sand or building materials and/or aluminum oxide and/or calcium hydroxide and/or hollow glass and/or ceramic spheres, glass as fillers - and/or carbon fibers and/or rubber particles, as well as metallic materials, in particular magnetic and non-magnetic metal composite materials and/or aluminum-coated materials. Continuous process according to one of claims 1 to 4, characterized in that the pumping residence time of the reactor contents (RI) is in the range of 15 to 55 seconds, preferably in the range of 25 to 40 seconds. Continuous process according to one of claims 1 to 5, characterized in that the starting oil is a mixture of product oil (P) and a mineral oil with a boiling point greater than 280 ° C, preferably in a mass ratio of 10% mineral oil to 90% product oil (P) up to 90% mineral oil to 10% product oil (P), in particular in a mass ratio of 50% mineral oil to 50% product oil (P), is used. Continuous process according to one of claims 1 to 6, characterized in that the surface loading B of the pumped flow in the second, upper region (II) of the two-part reactor (R) is set to a value in the range from 25 m3/m2/h to 250 m3/m2/h, preferably to a value of about 100 m3/m2/h, via the volume flow of the same and the geometry of the second, upper region (II) of the two-part reactor (R). Continuous process according to one of claims 1 to 7, characterized in that the inner walls of the two-part reactor (R) in the second, upper region (II) of the same are partially or completely heated and / or wetted with product oil (P). Continuous process according to one of claims 1 to 8, characterized in that the residue from the first, lower region (I) of the two-part reactor (R) is discharged as required or at regular intervals and allowed to settle and the supernatant oil mixture is returned to the first, lower region (I) of the two-part reactor (R) and the residue is separated off via a separation unit, in particular a filter or a separator. Continuous process according to one of claims 1 to 9, characterized in that only a first partial stream of 20 to 80% of the reactor contents (RI) is pumped from the lower end of the first, lower region (I) of the two-part reactor (R) into the second, upper region (II) of the two-part reactor (R) and a second partial stream of 80 to 20%, preferably of 60 to 70% of the reactor contents (RI) is pumped from the lower end of the first, lower region (I) of the two-part reactor (R) into the first, lower region (I) of the two-part reactor (R). Continuous process according to one of claims 1 to 10, characterized in that the reactor contents (RI) or a partial stream of the reactor contents (RI) is pumped back into the upper third of the second, upper region (II) of the two-part reactor (R). Continuous process according to one of claims 1 to 11, characterized in that the second, upper region (II) of the two-part reactor (R) is used as a single-stage or multi-stage separation column by providing a separable flange (F) via which one or several horizontal perforated plates and/or grids can be used. Continuous process according to one of claims 1 to 12, characterized in that the oxygen content in the product oil (P) compared to the starting material (A) is 40 to 90%, in particular 80%, and that the nitrogen content in the product oil (P) compared to the starting material (A) is 50 to 80%, in particular 70% lower. Continuous process according to one of claims 1 to 13, characterized in that the calorific value of the product oil (P) is between 41 and 46 megajoules per kilogram, preferably 45 megajoules per kilogram. Continuous process according to one of claims 1 to 14, characterized in that in the product oil (P) the formation of polycyclic aromatic hydrocarbons, in particular naphthalene, acenaphthalene, acenaphthene, fluorene, phenanthrene, anthracene, fluoranthene, pyrene and / or benzo (a) pyrene , is minimized and the sum of the polycyclic aromatic hydrocarbons is between 100 and a maximum of 1000 ppm, preferably a maximum of 600 ppm. Continuous process according to one of claims 1 to 15, characterized in that the starting material (A) contains municipal waste, in particular non-sortable plastic parts thereof, in particular sorting fractions which are separated due to their dimensions and/or film residues and/or black sorting residues which cannot be detected by near-infrared spectroscopy, and/or commercial waste, in particular production waste, preferably waste from the recycling of passenger cars, in particular lightweight car shredder material. Continuous process according to one of claims 1 to 16, characterized in that the first, lower region (I) of the two-part reactor (R) has a height to diameter ratio of 3:1 to 1:3, preferably 1.5:1, and is designed in particular as a standing or horizontal cylinder.

Images