EP3259334A1 - Apparatus and process for separating asphaltenes from an oil-containing fuel - Google Patents

Abstract

The invention relates to an apparatus (1, 91) for separation of asphaltenes from an oil-containing fuel (3), comprising a mixing element (11, 95) for intensive mixing of the oil-containing fuel (3) with a solvent (5, 93) to form a solution supersaturated with asphaltenes, a vessel (15, 97) for reducing the oversaturation by depositing the asphaltenes out of the supersaturated solution, a growth zone (23, 111) formed within the vessel (15, 97) for growth of asphaltene particles present via the asphaltenes separated out of the supersaturated solution, and a classifying unit (25) connected in terms of flow to the vessel (15, 97) for separation of the asphaltene particles grown in the growth zone (23, 111) in terms of their particle size, wherein the vessel (15, 97) is formed and set up such that a stream (79, 113) containing asphaltene particles circulates between the mixing element (11, 95) and the growth zone (23, 111) of the vessel (15, 97). The invention further relates to a corresponding process in which a stream (79, 113) containing asphaltene particles circulates between the mixing element (11, 95) and the growth zone (23, 111) of the vessel (15, 97).

Description

description

Apparatus and method for separating asphaltenes from an oily fuel

The invention relates to a device for separating asphaltenes from an oil-containing fuel. Furthermore, the invention relates to a corresponding method for the separation of asphaltenes from an oil-containing fuel.

In the context of energy production is often resorting to oily fuels, such as crude and heavy oils, which are available as low-cost fuels for energy production by gas turbines. However, such crude and heavy oils contain asphaltenes, which in turn contain chemically bound heavy metals. When the oils are burned, heavy metals such as vanadium or nickel are released as metal oxides. The Me ^¬-metal oxides alloyed with the metals of the turbine blades and corrode and weaken.

In addition, regardless of their metal content, asphaltenes have the property of precipitating as a solid under severe pressure or temperature changes. These solid asphalt particles can influence lines or fine nozzles of the torch used clog fen and the mixture formation in the turbine, whereby the efficiency of the turbine is geschmä ^¬ lert.

Accordingly, oils containing vanadium are added with an inhibitor which prevents alloying of the metal oxides with the metal of the turbine blade. When using a standard as InHi ^¬ bitor, but high-priced magnesium additive, a refractory Magnesiumvanadat forms instead of low melting Alkalivanadate. However, there is the danger of crust formation on the turbine blades by layered deposition of magnesium vanadate. To safeguard ^¬ position of the function of the turbine and to maintain the aerodynamic quality / efficiency, the deposits or type of connection must crusts are removed from the turbine blades, which requires a regular time-consuming and costly service effort. In particular, such a cleaning is associated with a turbine stoppage of several hours.

For more sensitive turbines with, for example, gas-cooled blades, the problem of blockages of the burner nozzles due to undesirable asphaltene deposits or the blockage of the cooling channels by vanadates has not yet been solved.

Furthermore, so-called deasphalting processes are known, which are based on an extraction of asphaltenes with saturated aliphatic hydrocarbons as precipitants. However, these asphaltene reduction methods are only used in the refinery sector. The use in a power plant environment is not effective since, for example providing for "classical" deasphalting means of the so-called ROSE process an asphalt extraction with low-molecular Ali triphosphates, which require residence times partially to meh ^¬ eral hours. Such a deasphalting is just at ROSE- Process associated with high temperatures and pressures in the "critical" range of solvents. Also, classical methods are to be dimensioned differently in terms of a typical power plant requirement, which require an oil feed of 200 t / h and low operating costs, as in a refinery. On the one hand short residence times are required for throughput platforms ^¬ tion, on the other hand is in the typically to be considered single-cycle gas turbine power plants enough "free" waste heat available to be able to operate to ^¬ sätzlichen fuel costs associated with it the process without external heating and. The Invention is based on a first object, a

Specify device by means of which the Asphaltenabschei- tion can be achieved from an oil-containing fuel efficiently and inexpensively. As a second object of the invention is to provide a method that allows a correspondingly simple and kos ^¬ tengünstige asphaltene separation.

The first object of the invention is inventively achieved by a device for the removal of asphaltenes from an oil-containing fuel comprising a mixing element for intensive in ^¬ mixing of the oil-containing fuel with an solu- solvents to form a supersaturated with asphaltenes solution, a container for desupersaturation by deposition of the asphaltenes from the supersaturated solution, a growing ^zone formed inside the container for growing asphaltene particles through the asphaltenes separated from the supersaturated solution, and a fluidically connected classifier for separating the asphaltene particles grown in the growth zone into their particle size according to, wherein the Behäl ^¬ ter is designed and arranged such that a

Asphaltene particles containing stream between the Mischele ^¬ ment and the growth zone of the container circulates.

The invention faces two fundamental problems that arise in the precipitation of asphaltenes from an oily fuel. On the one hand there is the risk of uncontrolled early precipitation of asphaltene particles in the addition of precipitants or solvents, as is customary in the case of deasphalting, since the solvents used in the deasphalting and the respective oil-containing fuels are not completely miscible. The phase interface, which arises despite the mixing, favors the spontaneous and uncontrolled precipitation of the

Asphaltenes. The particles formed in a precipitation are usually ultrafine particles whose separation from the respective mother solution, that is to say in the present case the oil-containing fuel, is scarcely possible. This gives rise to the second problem. Available to the precipitated fines growth nuclei or correspondingly large upper surfaces ^¬ available, then the particles separate out there. With regard to the devices used for deasphalting, these surfaces are provided by the walls of the individual device components or by growth nuclei contained in the fuel, at which the asphaltene particles deposit and grow. This applies ever ^¬ but in terms of unwanted deposits and blockages, called fouling, and to prevent the associated From ^¬ effects on a downstream gas turbine process.

Taking this problem into account, the invention now recognizes that precipitation and separation for the subsequent separation of the asphaltene particles from the oil-containing fuel can be implemented in a controlled manner, especially when rapid mixing takes place in combination with a targeted provision of growth nuclei.

The device used for the separation comprises for this purpose a mixing element for intensive mixing of the oil-containing fuel with a solvent to form a

Asphaltene supersaturated solution and a container to reduce supersaturation by deposition of asphaltenes from the supersaturated solution. Within the vessel, a wax ^¬ tumszone is formed separated in the existing asphalt particles by the from the supersaturated solution

Asphaltenes grow. The container is in this case such forms ^¬ out and arranged such that a circulating asphalt particles contained ^¬ tender flow between the mixing element and the growth zone of the container.

By circulating the asphaltene particle-containing stream between the growth zone and the mixing element, two effects are simultaneously achieved. On the one hand, through the use of a mixing element, which is a fast and inten ^¬ sive mixing of the oil to be cleaned containing fuel ensures the formation of a metastable, supersaturated solution, which prevents the formation of a phase interface between the two components and thus prevents premature precipitation of asphaltene particles during the mixing process with the ensured used to precipitate the asphaltenes.

On the other hand, is ensured by the circulation of the asphalt particles that are gebil- det at each point where the particles and begin to precipitate, that is already on the separation process abge ^¬ true even after the mixing process growth nuclei for the deposition and growth of the asphaltenes are available , The particles thus formed do not separate out as ultrafine particles, but instead have the opportunity to grow on an existing particle provided. Accordingly, the following separation is simplified by means of the classifier. Overall, existing asphalt particles are in the process so ^¬ used with targeted as growth nuclei that favor Abschei ^¬ dung of asphaltenes and at the same deposition dung caused contamination of walls, pipes or the like of an in-accordance to the deasphalting translated prevent device.

The stream containing the asphaltene particles circulates here between the mixing element and the growth ^zone in such a way that the volume elements contained in the asphaltene particles pass through both the growth zone and the mixing element several times. Thus, in the deposition of the asphaltenes, existing particles preferentially enlarge instead of forming the new microfine particles. The particles accumulate within the container and can then be separated from the oil-containing fuel by the classifier connected to the container according to their particle size. Preferably, a mixing pump is used as the mixing element, which has a high shear rate. Upon termination of the mixing process, so if supersaturated Lö ^¬ solution leaves the Mischzo ^¬ ne or the mixing element of oily fuel and solvents, the deposition of asphaltenes starts. Thanks to the asphaltene particles present in the mixing zone or at the mixing point as a result of the circulation of the stream, the asphaltenes which precipitate out of the solution can deposit thereon and grow there. The supersaturation of the solution can thus be reduced in a controlled manner thanks to the presence of the asphaltene particles present in the stream. The growth of asphaltene particles continues within the container. Here, the particles may grow so far that they Errei ^¬ chen the desired particle size for separation. The separation of the particles takes place via the classifier connected to the container.

The fuel to be purified by asphaltenes is, in particular, a heavy oil whose main constituents, in addition to the asphaltenes (highly condensed aromatic hydrocarbons), are above all alkanes, alkenes, cycloalkanes. In addition there alipha ^¬ tables and heterocyclic nitrogen and Schwefelverbin ^¬ decisions occur.

Suitable solvents are in particular short-chain hydrocarbons, such as butanes (C4), pentanes (C5), hexanes (C6) and / or heptanes (C7). The solvent in this case serves to dissolve soluble constituents contained in the oil-containing fuel, for example aliphatics. The asphaltenes contained in the oil-containing fuel are insoluble in the solvent used, so that the solvent respect ^¬ Lich of the asphaltenes can be ^¬ is characterized as a sort of an "anti-solvent".

Particularly preferably, a supply line for the oil-containing fuel and / or a supply line for the solvent are connected to the mixing element. If both supply lines are connected to the mixing element, the two components are mixed directly in the mixing element. Such an staltung is particularly preferred because of ensuring fast and good mixing.

Alternatively, a possible "in-contacting" of oily fuel and solvents prior to entering the mixing element, which may be necessary, for example due to structural conditions. The streams are then fed together to the mixing element, which then mix by rapid Ver ^¬ a supersaturated solution results.

The container itself is in particular designed such that it allows a sufficiently large residence time for the growth of the asphaltene particles. Thus, the required for the separation solids accumulation is ensured in the container. Within the container, the precipitated asphaltene particles continue to grow before their separation. The growth will be affected by the balance between the quantity of the lingering in the loading container ^¬ particles and the amount of circulating particles or limited. In this case, the higher the residence time, the higher the deposition rate and thus, due to the improved separation, the cleaning performance of the device used for the separation. Among the growth zone of the container, the zone such is understood ^¬, in which the asphalt particles grow by the deposition of white ^¬ more excellent asphaltenes from the mixture, thus the supersaturated solution. The growth zone may in this case be limited to a volume within the container. Alternatively, the entire container volume as a growth zone for the

Asphaltene particles are available.

The particle growth and thus the separation of the asphaltenes from the liquid phase take place on the surface of the asphaltene particles. Small particles have a high specific surface, but are difficult to separate. A container with a growth zone in which a high mass of particles per volume is provided allows this Growth of large and easily separable particles while providing a high absolute surface for a high

Abscheideleistung available. In order to separate the asphaltene particles present in the container and in particular in order to keep the particles required for growth in the container, the container is the

Classifier connected. The separation takes place here according to the particle size, with small and large

Asphaltene particles are separated. The classifier ^¬ device preferably comprises for this purpose a number of

Separating stages, each of which a partial flow is supplied with particles. The average diameter of the separated particles is in this case, for example, depending on the oil used, the set separation grain size and the speed of the asphalt Wachstumsge ^¬ particles.

By the classification within the classifier or within the separation stages, the desired accumulation of asphaltene particles in the container can be achieved. By adjusting the amount of solids present in the container, which can be achieved by the targeted control of the two partial streams taken from the container, the desired adaptation of the available surface to the process requirements is possible.

Due to the particle growth within the container and the associated increasing accumulation of particles and the available surface decreases the required volume of the container. The particles in this case have a ^¬ interpreting Lich higher residence time and thus growth within the container as the liquid flowing through, whereby large and well-separable particle arise. In other words, due to the accumulation of solids within the container, it is possible to specify different residence times for the liquid and the solid. As a result, the requirements for the growth time of the solid particles, as well as the short Flüssigkeitsverweilzeit, which allows the use of a container of small size, glei ^¬ chermaßen taken into account.

Increases the particle concentration at a long residence time within the container for example by a factor of 3 in, the available surface for the Parti ^¬ kelwachstum is also about 3 times greater. As a result, the volume-specific separation capacity (kg of asphaltenes / hm ³ ) of the container increases by a factor of 3, so that the container volume can be reduced by a factor of 3 with the same separation performance compared to non-successful particle enrichment with a low residence time. In other words, a particle enrichment within the container or within the corresponding growth zone allows the use of a container with structurally smaller dimensions.

Basically, small asphaltene particles in the present case are understood as meaning those particles which have not yet grown sufficiently to be able to be retained by a classifier, ie kept in the process. For

Finest particles that are not classified, the hyd ^¬ rodynamische residence time is about 1 τ.

The mean diameter of the small asphaltene particles is typically below 5 μm. Large asphaltene particles are understood to be the particles which, owing to their significantly larger average diameter, can be easily separated off by the classifier and fed to a further utilization as a solid. Preferably, such isolated as large asphalt particles whose mittle ^¬ rer diameter is above 25 ym.

Between the mixing element and the growth zone of Be ^¬ hälters circulating stream preferably contains asphaltene particle medium size. In particular, the current-saving circuiate ^¬ asphalt particles having an average diameter containing in a range between 5 .mu.m and 20 .mu.m. The amount of asphaltene particles circulating in the partial flow is through the residence time in the container - depending on the classification of the particles - determined.

Of course, the specified particle sizes of the small, medium and large asphaltene particles are not limited to the ranges indicated. Depending on the design of the device, the desired residence time within the vessel or within the growth zone and to clean ^¬ constricting oil-containing fuel, the particle sizes of the designated values or the area may be different.

The medium-sized asphalt particles flow from the wax ^¬ tumszone the mixing element to stand there as growth nuclei for the deposited from the mixture asphaltenes available. By means of the mixing element of the stream is mixed with a solvent and the oily ^¬ set to be cleaned fuel. Those contained in the mixture

Asphaltenes then divorce to the already present as a solid ^¬ particles in the mix asphalt particles, and grow on to you in addition.

In order to create the best possible growth conditions for the asphaltene particles and at the same time to be able to react flexibly to various oil-containing fuels, a two-stage classifier, ie a classifier with two separation stages, is preferably used. By means of the separation stages, preferably small and large asphaltene particles are separated from one another and at the same time from the "mother solution", ie the mixture of fuel and solvent.

The circulation of the asphaltene particle-containing stream is achieved in an advantageous embodiment of the invention via a fluidic connection of the mixing element with the container. For this purpose, the container for circulating the asphaltene particle-containing stream is expediently fluidly connected to the mixing element. About this fluidic connection containing the asphaltene particles stream is supplied from the container to the mixing element and mixed here with oily fuel and solvent. The resulting mixed stream is fed to the container, for which purpose the mixing element is preferably fluidly connected via a discharge line to a supply line of the container.

Within the container, the asphaltene particles contained in the mixed flow grow. The large asphaltene ^{particles are} separated off. Small particles are ^¬ carry out the oil flow. The stream containing essentially asphalt particle medium size is again ge ^¬ leads into the mixing element. To remove the stream with substantially medium-sized asphaltene particles from the container, the latter is preferably connected via a discharge line in terms of flow to a supply line of the mixing element.

The stream supplied from the container to the mixing element is mixed again within the mixing element with the freshly supplied oily fuel and the solvent. The asphaltene particles contained in the stream serve as growth nuclei. They provide the surface necessary for growing the asphaltene particles. This is where a large part of the mix, so the Asphal ^¬ tenpartikel containing stream, out repeatedly in a loop.

The amounts of each circulating streams can be described by mass flow conditions. A mass flow is the mass of a medium which moves through a cross-section per unit of time. In the present case the mass flow ratio between the asphalt particles is preferably containing stream and the mixed stream (me sum of the feed streams of the oil containing fuel and Lö ^¬ sungsmittels) is considered. The ratio of the flow supplied by the container to the mixing element to the sum of the inlet flow Depending on the concentration of solids present, it is preferably in a range between 0.1: 1 to 100: 1.

In this case, a lower ratio of the mass flows can be set with a higher solids concentration. A low mass flow ratio is desirable, in particular due to cost reasons, since higher KreislaufVerhält ^¬ nisse require larger pumps and larger pipe diameter, which are recorded pressure losses.

A mass flow ratio in a range between 10: 1 and 10: 5 is advantageous here. Particularly preferred is a mass flow ratio of 10: 1. A ratio of 10: 1 be ^¬ indicated that the mass of the asphalt particle-containing stream flowing in the direction of the mixing element, times greater than about 10, the sum of the feed streams of the oil containing fuel and the solvent to the mixing element.

An alternative embodiment of the invention provides that the mixing element is arranged within the container. In the arrangement of the mixing element within the container ^¬ which the oil-containing fuel and the solvent via ent ^¬ speaking leads dosed into the container, where they are mixed vice ^¬ starting intensive. For mixing a mixing element is preferably used, which operates on the rotor-stator principle and has a high shear rate. Also possible here is the use of a mixing pump whose static part is arranged, for example, on the wall of the container.

The mixing is preferably carried out in a so-called mixing zone or at a mixing point within the container. The mixing zone is expediently located in the vicinity of the container wall, so that thorough mixing takes place immediately after inflow of the feed streams, ie of the oil-containing fuel and the solvent, to form a supersaturated solution. The mixture flows through a suitable flow guide within the container in the growth zone of the container where the asphaltenes precipitate. As growth germs they are also available here in the container asphaltene particles available. As well as in a structurally separate arrangement of the mixing element and vessel, the circulation of the asphalt particles containing stream between the wax ^¬ tumszone the container and the mixing element is carried out. Overall, circulation of an asphaltene-containing stream between the growth zone of the container and the mixing element - regardless of whether the mixing element is formed as a separate component or disposed within the Behäl ^¬ ters - provide a provision for the

Deasphalting of an oil-containing fuel required large surface area for selective separation of the asphaltenes and at the same time prevention of crust formation by fouling.

The asphaltene particles grown within the growth zone of the container undergo a separation of their particle size. By the connected to the container classifying a targeted enrichment of solids Parti ^¬ angles is possible, which increases the deposition rate and thus the cleaning ^¬ cleaning performance in the separation.

Particularly advantageous is the use of a classifier, which includes several separation stages, so as to achieve the bestÖg ^¬ lichster separation performance. In the present case, the term separation stage is to be understood as meaning, in particular, those structural components which permit a targeted separation of the asphaltene particles according to their particle size.

The separation stages used in each case are preferably designed as hydrocyclones. A hydrocyclone is a centrifugal separator for liquid mixtures. With a hydrocyclone solid particles contained in suspensions can be separated or classified. The discharged from the container, enriched with large asphaltene particles first partial flow is through passed the hydrocyclone and this separated the large asphaltene particles from the mother solution.

The use of a hydrocyclone is advantageous here, since it consists of a container without moving parts and has a low volume due to the short residence time of the first partial ^flow . An alternative embodiment of the invention provides for the use of decanters and / or self-cleaning edge gap filters, alternatively or in addition to the hydrocyclones as separation stages.

Preferably, the classification ^device used for the separation comprises a first separation stage for separating large ones

Asphaltene particles from a first partial flow. For the supply of the first partial stream to the first separation stage, the container is suitably ^¬ flow-connected to a supply line of the first separation stage via a first discharge line. The first discharge line of the container is vorzugswei ^¬ se arranged at the bottom thereof, so that the first partial stream withdrawn at the bottom of the container and the first separation stage is supplied ^¬ leads.

The separation within the first separation stage takes place taking into account a preset separation grain size.

Asphaltene particles with a mean diameter greater than a pre-set size of separation particles are discharged from the process and removed. With a cut-off particle size of 25 μm, particles having an average diameter greater than 25 μm are thus discharged.

For recycling a abgerei- cherten of large asphalt particles first retrace, the first separation stage ^¬ advantageous way legally is fluidically connected via a return line to a supply line of the container. In other words, as a result of the separation of the large asphaltene particles, a reflux is formed which comprises asphaltene particles whose size falls below the set separation particle size. This return is returned to the container, with the in Return still contained asphaltene particles within the Be ^¬ container or serve within the growth zone of the container as growth nuclei. Conveniently, the first separation stage is a Aufberei ^¬ processing device fluidically connected downstream. For example, a centrifuge can be used as the treatment device, by means of which the large asphaltene particles separated off in the first separation stage are finally separated, freed from adhering mother solution and removed from the separation process. The large asphaltene particles can then be used for further use, such as for processing in road construction. For separation of small asphaltene particles from a second partial stream, the classifier preferably comprises a second separation stage. The container is for supplying the second partial flow to the second separation stage advantageously via ei ^¬ ne second discharge line fluidly connected to a supply line of the second separation stage. The second discharge line of the container is expediently arranged on its head, so that the second partial stream is supplied from the top of the container to the second separating stage. The asphalt particles contained in the discharge line of the container through the second out ^¬ transmitted second part stream are separated in the second separation stage from the solution. The small particles that are not yet grown sufficiently to ^¬ to be separated finally be held in the process. For this purpose, it is particularly advantageous if the second separation stage is connected to return a small asphaltene particles enriched second return via a return line to a supply line of the container. The small asphaltene particles are returned to the container and can continue to grow there.

Conveniently, the second separation stage is a Aufberei ^¬ processing device fluidically connected downstream. In the Separation of the small asphaltene particles from the second partial stream results in a clear run, which is essentially free of asphaltene particles. Starting from the second separation stage, this clear-run is fed as a flow stream to the treatment device. The treatment device can be designed, for example, as a solvent treatment, in which the solvent or, based on the asphaltenes, the so-called "anti-solvent", ie the short-chain alkane used, is recovered by evaporation zu ^¬ out and used for renewed Deasphaltierung.

In a further preferred embodiment of the container for classifying the asphalt particles is designed according to their particle size ^¬. For this purpose, the container preferably comprises a classifying zone, within which the asphaltene particles are separated according to their particle size. The classification zone is so ^¬ with integrated in the container and suitably provided in the edge region of the container ^¬. When using a container with a built-in classification zone is insbeson ^¬ particular, the ability to dispense with the first separation stage, as the classifying discharge of large particles is already achieved by the design of the container and the flow guide within the container.

Of course, it is also possible, in addition to a container with a classifying function as previously described internally additional external separation stage einzuset ^¬ zen, which made further separation of the asphalt particles ^¬ light.

Overall, it is possible to use such a device on an industrial scale in the power plant environment, since the size of the plant and the investment and operating costs compared to conventional devices for deasphalting are significantly reduced. Deasphalting is possible as an oil pretreatment, which permits the use of heavy fuel oil containing more than 100 ppm of vanadium for power generation by E-class gas engines. allowed. Also, crude oil (Crude) Oil with significantly height ^¬ ren vanadium concentrations than 10 ppm in E-class gas turbines are used, the previously economically through large amounts of magnesium inhibitors and the enormous effort service associated with vigorous Pressure is.

Furthermore, light crude oils, such as Arabian Extra Light Crude with 1 ppm vanadium or Arabian Light Crude with> 10 ppm vanadium can be used in very efficient, but also sensitive F and H class gas turbines. Such use has hitherto been severely limited due to not negligible asphaltene concentrations and even completely excluded at vanadium concentrations above 0.5 ppm.

The second object of the invention is achieved by methods for the separation of asphaltenes from an oil-containing fuel, wherein the oil-containing fuel is mixed intensively by means of a mixing element with a solvent, wherein during the mixing process on

Asphaltenes supersaturated solution is formed, the supersaturation by deposition of the asphaltenes from the supersaturated solution in a container is reduced, whereby existing asphaltene particles grow in a growth zone of the container by deposited from the supersaturated solution asphaltenes, the attached in the growth zone ^¬ grown Asphaltene particles are separated by a classifier according to their particle size, and wherein a

Asphaltene particles containing stream between the growth zone of the container and the mixing element circulates.

By circulating the stream containing asphaltene particles asphaltene particles are already available when mixing the oil-containing fuel to be cleaned with the solvent, which serve as growth nuclei. Here be ^¬ already existing asphalt particles grow, rather than that new fines need to make. Such fine particulate formation takes place only once at the beginning of the process, al- so when starting the system. These ultrafine particles then serve as growth ^germs present in the process and they ^enable a reduction of the supersaturation by precipitation of asphaltene particles from the supersaturated solution.

Accordingly, a large part of the mixture, ie the asphalt particles containing stream, ge in a circuit ^¬ leads. Furthermore, the targeted enrichment of hard ^¬ substance particles, ie the particles to be separated asphalt to increase the deposition rate and thus used to improve the cleaning performance.

In a particularly advantageous embodiment, the stream containing asphaltene particles flows from the container into the mixing element. Here are the for the separation of

Asphaltenes required particles provided. Conveniently, the asphalt is mixed particles containing stream in the mixing element with the oil-containing fuel and the solution ^¬ medium.

When mixing a supersaturated solution from which the asphaltenes are precipitated on the surface and which acts as a growth nucleus asphalt particles abschei ^¬ formed. Preferably, the mixture of the asphaltene particle-containing stream, the oily fuel and the solvent is supplied to the container. Within the Behäl ^¬ ters grow asphalt particles to grow.

In an alternative preferred embodiment of the oil-containing fuel and the solvent are mixed within the Behäl ^¬ ters. The mixing element is hereby arranged zweckmäßigerwei ^¬ se within the container. The oleaginous internal ^¬ material and the solvent are mixed directly into the container do ^¬ Siert and at the entry point. The entry point is thus preferably designed as a mixing point or as a mixing zone. The mixing is preferably carried out ^¬ by means of a working according to the rotor-stator principle mixing element with a high shear rate. Preferably, a first partial stream for separating large asphaltene particles of a first separation stage of Klassierein ^¬ direction supplied. The first partial stream is expediently withdrawn from the bottom of the container from this and flows from there into the first separation stage. In the first separation stage the large asphalt particles that exceed a certain set before ^¬ cut size are separated and thus removed from the process.

It is particularly advantageous when a large asphaltene particles ^¬ depleted first return is supplied to the container. The return includes asphalt particles un ^¬ terhalb the separation grain size of the first separation stage are. The particles serve within the container again as growth ^¬ germs and improve the solids accumulation within the container.

The large asphaltene particles separated from the first partial stream are expediently fed to a treatment device. By way of example, the treatment device can be designed as a centrifuge, by means of which the large particles are separated. One possible use of the separated asphaltene particles is in road construction.

It is also advantageous if a second partial stream for separating small asphaltene particles is fed to a second separating stage of the classifying device. The second partial stream is expediently withdrawn therefrom at the top of the container and fed to the second separation stage.

Within the second separation stage essentially small asphaltene particles are separated, one with small

Asphaltene particles enriched second reflux arises. Preferably, the asphalt with small particles angerei ^¬-assured second return is supplied to the container. This allows the small particles within the container to continue growing up. The effluent freed from small asphaltene particles, the clear flow, is preferably fed to a treatment device. In this case, it is preferred if the ^outflow stream is fed to a solvent recovery in which the solvent is evaporated and regenerated. Finally, the regenerated solvent can be in this way, be re-used for mixing with the oil-containing fuel at ^¬ play a pentagonal section. In a further advantageous embodiment of the invention, the asphaltene particles are separated within a classification of the container according to their particle size. In other Wor ^¬ th of the container acts as a classifier, in which the particles are pre-separated according to their particle size. It is therefore an internal classification zone within the Behäl ^¬ ters, which is expediently provided in the edge region of the container in the form of a quiet zone.

The advantages referred to preferred embodiments of the device can be applied analogously to corresponding Substituted ^¬ staltungen of the process in this case.

In the following, embodiments of the invention will be explained in more detail with reference to a drawing. Showing:

1 shows a device for separating asphaltenes from an oil-containing fuel with a mixing element fluidically connected container, as well as

2 shows another device for the separation of

Asphaltenes from an oil-containing fuel with an arranged mixing elements ^¬ within a container.

1 shows a device 1 for the separation of asphaltenes from an oil-containing fuel 3. As fuel 3, a heavy oil is used. The heavy oil 3 will be together with pentane supplied as a solvent 5 via corresponding supply lines 7, 9 designed as a mixing pump mixing element 11. Within ^¬ within the mixing element 11, the heavy oil 3 and the solvent 5 are mixed ultrafast.

A rapid mixing produces a metastable, supersaturated solution, which avoids the formation of a phase interface between the heavy oil 3 and the pentane 5 and thus prevents premature precipitation of asphaltene particles during the mixing process.

The resulting mixture 13 is supplied to a mixing element 11 connected to the mixing tank 11, to which the mixing element 11 is fluidly connected via a discharge line 17 with a supply line 19 of the container 15. Already at the supply to the container 15, so after completion of the mixing process, the precipitation process of asphaltenes begins. The precipitating from the solution asphaltenes failed ^¬ off to existing in the process asphalt particles.

Within the container 15 is a growth zone 23, in which grow the asphaltene particles. The required for the subsequent separation of the growth of solid enrichment within the container 15 is ensured by a sufficiently long residence time of the asphalt particles in Behäl ^¬ ter 15th The longer the residence time of the

Asphaltene particles, the higher the deposition rate and thus, due to the improved separation of the particles, and the cleaning performance of the separation device 1 used.

To separate the asphaltene particles grown in the growth zone 23 according to their particle size, a classifying device 25 is fluidically connected to the container 15. The classifier 25 for this purpose comprises two plates 27, 29. The coupling of the first separation stage 27 to the Behäl ^¬ ter via the connection of a first discharge line 31 of the container 15 to a supply line 33 of the first separation stage 27 via lines 31, 33 the first Trennstu ^¬ fe 27, a first portion stream 35 is supplied. The discharge line 31 of the container 15 is connected to the bottom 37 thereof.

In the first separation stage 27, which is designed as a hydrocyclone, are large asphalt particles 39 that exceed a set before ^¬ separation grain size of 25 ym, removed from the process. They are fed via a discharge line 41 to a treatment device 43 and can subsequently be supplied to a further use, for example in road construction.

As a result of the separation of the large asphaltene particles 39, a solution is produced which is returned to the container 15 as a first return 45. The first return 45 now contains only those asphalt particles whose average diam ^¬ ser is below 25 .mu.m. To return the return flow 45, that is to say the partial stream depleted of large asphaltene particles, the first separation stage 27 is connected to a return line 47, which is fluidically connected to a supply line 49 of the container 15. The asphalt particles now still contained in the return 45 are within the container 15 or within the growth zone 23 of the Be ^¬ hälters 15 as a growth germ. The second separation stage 29 of the classifier 25 is used to separate smaller asphalt particles 51 from a second part flow 53. In order to supply the second partial stream 53 to the second separation stage 29, the container 15 via a second Ab ^¬ conduit 55 fluidly connected to a supply line 57 of the second separation stage 29 , The second discharge line 55 of the container is arranged on the head 59. The second partial flow 53 essentially comprises small

Asphaltene particles 51 which are to be kept in the process in order to continue to grow there. Accordingly, in the second separation stage 29 which is also formed as a hydrocyclone off asphalt particles 51 separated by an average ym By ^¬ diameter above 5 from the liquid and returned to the container 15th The return of the enriched with small asphaltene particles 51 second return 61 via a connection of a return line 63 of the second separation stage 29 with a feed line 65 of the container 15th

Furthermore, the second separation stage 29 is a Aufberei ^¬ processing device 67 downstream of flow. The processing device 67 29 is connected discharge pipe 69 of the formed in the Abtren ^¬ drying the asphalt particles 51 flow stream 71, a clear effluent is fed via one of the second separation stage. Within the treatment ^device 67, the solvent 5 can be recovered and returned to the mixing element 11.

Within the container 15 are located during the Prozes ^¬ ses asphalt particles 73 having an average diameter in a range between 5 .mu.m and 25 .mu.m, which can be performed in a circuit 75 miles. A partial flow 79 with these asphaltene particles 73 is fed to the mixing element 11 via a return line 77 connected to the container 15.

For this purpose, the return line 77 of the container 15 is connected to a feed line 81 of the mixing element 11. Thus, in addition to the feed line 7 for the heavy oil 3 and the feed line 9 for pentane 5, the feed element 81 is also connected to the mixing element 11, via which the feed or the circulation of growth nuclei for the asphaltene separation is ensured.

By the asphaltene particles 73 contained in the circulating stream 79 are already at the time of Mixing of the oil-containing fuel 3 and the ^{Lösungsmit ¬} tel 5 growth ^nuclei for the asphaltenes available. The asphaltenes contained in the supersaturated solution, ie the mixture 13, are deposited only on the asphaltene particles 73 already present and grow there. In other words, the precipitate, which occurs substantially immediately after the mixing of the oily fuel 3 and the solvent 5, by the circulation of the

Asphaltene particles between the mixing element 11 and the growth zone 23 of the container 15 are selectively controlled.

Within the container 15 may further be formed a classifying zone 83, which alternatively or in addition to the first separation stage 27 separates large asphaltene particles. The position of the classifying zone 83 within the container 15 is indicated here by an arrow.

FIG. 2 shows a further device 91 which likewise serves to separate asphaltenes from an oil-containing fuel 3 by means of a solvent 93, in the present case hexane.

The structural difference between the device 91 and the device 1 according to IG 1 is that the mixing element 95 used is not connected upstream of the container 97, as is the case with the device 1, but instead is arranged inside the container 97.

In the arrangement of the mixing element 95 within the Behäl ^¬ ester 97 are the heavy oil 3 and the solvent 93 or that contained in the oil-containing fuel 3

Asphaltenes-related "anti-solvent" via lines 99, 101 dosed directly into the container 97. The mixing takes place within the container 97 in a formed on the wall 103 mixing zone 105 by means of the mixing element formed as an internal mixing pump 95 immediately upon entry of the heavy oil 3 and the solvent 93. By the mixing ^¬ element 95, the necessary ultrafast mixing of the two components 3, 93 ensured. The mixture 109 resulting from the mixing flows through a suitable flow guide within the container 95 into the growth zone 111 of the container 95, where the asphaltenes precipitate or those which have already precipitated

Asphaltene particles continue to grow. As growth nuclei, they are also available here in the container 95 asphaltene particles 113 medium size available. Zirku ^¬ thus also prominent between the mixing element 95 and the growth zone 111 due to the flow conditions, an Asphal ^¬ tenpartikel 113 containing partial stream 115. The asphalt particles 113 provide as growth nuclei a surface be ^¬ riding that favors the deposition of asphaltenes and at the same deposition caused contamination of Wandun ^¬ conditions, pipelines or the like of a device used for Deasphaltierung 1 prevents.

As in FIG 1, the container 97 may be a classifying zone 117, whose position is indicated by an arrow out ^¬ forms which serves as an alternative or in addition to the first separation stage 27 of the classifying large asphalt particles.

With regard to the function of the further device components encompassed by the device 91, the detailed description of the device 1 according to FIG. 1 can be transferred to the device 91 according to FIG.

Claims

claims

1. Device (1, 91) for separating asphaltenes from an oil-containing fuel (3), comprising a mixing element (11, 95) for intensive mixing of the oil-containing fuel (3) with a solvent (5, 93) to form egg ^¬ ner with asphaltenes supersaturated solution, a container (15, 97) for reducing the supersaturation by deposition of

Asphaltenes from the supersaturated solution, a growth zone (23, 111) formed within the container (15, 97) for growing asphaltene particles through the asphaltenes separated from the supersaturated solution, and a classification device (25, 97) fluidically connected to the container (15, 97) ) for the separation of the asphaltene particles of their grown in the growth zone (23, 111)

Particle size, wherein the container (15, 97) such ausge ^¬ forms and is arranged such that an asphaltene particles ent ^¬ holding stream (79, 113) between the mixing element (11, 95) and the growth zone (23, 111) of the container ( 15, 97) circulates.

2. Device (1, 91) according to claim 1, wherein the container (15, 97) for the circulation of the asphaltene particle-containing stream (79, 113) is fluidly connected to the mixing element (11, 95).

3. Device (1, 91) according to claim 1 or 2, wherein the mixing element (11, 95) via a discharge line (17) flow ^¬ technically with a supply line (19) of the container (15, 97) is connected.

4. Device (1, 91) according to any one of the preceding claims, wherein the container (15, 97) via a return line (77) fluidly connected to a feed line (81) of the mixing element (11, 95).

5. Device (1, 91) according to claim 1, wherein the mixing element (11, 95) within the container (15, 97) is arranged.

6. Device (1, 91) according to any one of the preceding claims, wherein the classifying device (25) comprises a first separation ^¬ stage (27) for separating large asphaltene particles from a first partial flow (35).

7. Device (1, 91) according to claim 6, wherein the container (15, 97) for supplying the first part flow (35) to the first separation stage (27) via a first discharge line (31) fluid ^¬ technically with a supply line (33). the first separation stage (27) is connected.

8. Device (1, 91) according to claim 7, wherein the first discharge line (31) of the container (15, 97) at the bottom (37) is arranged.

9. Device (1, 91) according to any one of claims 6 to 8, wherein the first separation stage (27) for returning a depleted of large asphaltene particles first return (45) via a return line (47) fluidly with a feed line (49) of the container (15, 97) is connected.

10. Device (1, 91) according to any one of claims 6 to 9, wherein the first separation stage (27) is a processing device (43) fluidly connected downstream.

11. Device (1, 91) according to one of the preceding claims, wherein the classifying device (25) has a second

Separation stage (29) for separating small asphaltene particles from a second partial stream (53).

12. Device (1, 91) according to claim 11, wherein the container (15, 97) for supplying the second partial flow (53) to the second separation stage (29) via a second discharge line (55) flows. mentally with a feed line (57) of the second

Separation stage (29) is connected.

13. Device (1, 91) according to claim 12, wherein the second discharge line (55) of the container (15, 97) at the head

(59) is arranged.

14. Apparatus (1, 91) according to any one of claims 11 to 13, wherein the second separation stage (29) for returning a small asphaltene particles enriched second return (61) via a return line (63) with a feed line (65) of the container ( 15, 97) is connected.

15. Device (1, 91) according to any one of claims 11 to 14, wherein the second separation stage (29) is a Aufbereitungsvorrich- device (67) fluidly connected downstream.

16. Device (1, 91) according to any one of the preceding claims, wherein the container (15, 97) has a classifying zone (83, 117) for separating the asphaltene particles according to their

Particle size includes.

17. A process for the separation of asphaltenes from an oil-containing fuel (3), wherein the oily fuel (3) by means of a mixing element (11, 95) with a solvent (5, 93) is intensively mixed, wherein during the Mischvor ^¬ gang an As supersaturated solution is formed asphaltenes, wherein the supersaturation is degraded by deposition of asphaltenes from the supersaturated solution in a container (15, 97), wherein in a growth zone (23, 111) of the container

(15, 97) existing asphalt particles grow by deposited from the pregnant ^¬ saturated solution asphaltenes, said in the growth zone (23, 111) grown

Asphaltene particles are separated by means of a classifying device (25) according to their particle size, and wherein a stream containing asphaltenes ^¬ particles (79, 113) between the growth zone (23, 111) of the container (15, 97) and the mixing element (11, 95) circulates ,

A method according to claim 17, wherein the asphaltene particle-containing stream (79, 113) flows from the container (15, 97) into the mixing element (11, 95).

19. The method of claim 17 or 18, wherein the

Asphaltene particles containing stream (79, 113) in the mixing ^¬ element (11, 95) with the oily fuel (3) and the solvent (5, 93) is mixed.

20. The method according to claim 19, wherein the mixture of the asphaltene particle-containing stream (79, 113), the ölhalti ^¬ gen fuel (3) and the solvent (5, 93) to the container (15, 97) is supplied.

21. Device (1, 91) according to claim 17, wherein the oily fuel (3) and the solvent (5, 93) within the container (15, 97) are mixed.

22. The method according to any one of claims 17 to 21, wherein a first partial stream (35) for separating large asphaltene particles of a first separation stage (27) of the classifying device (25) is supplied.

23. The method of claim 22, wherein the first substream

(35) at the bottom (37) of the container (15, 97) from this abgezo ^¬ conditions.

24. The method according to any one of claims 17 to 23, wherein a depleted of large asphaltene particles first return

(45) is supplied to the container (15, 97).

25. The method according to any one of claims 22 to 24, wherein the separated from the first partial flow (35) large

Asphaltene particles of a treatment device (43) are supplied.

26. The method according to any one of claims 17 to 25, wherein a second partial stream (53) for the separation of smaller

Asphaltene particles of a second separation stage (29) of

Classifier (25) is supplied.

27. The method of claim 26, wherein the second partial flow (53) at the head (59) of the container (15, 97) is withdrawn from this.

28. The method according to any one of claims 17 to 27, wherein an enriched with small asphaltene particles second return (61) to the container (15, 97) is supplied.

29. The method according to any one of claims 17 to 28, wherein a freed from small asphaltene particles flow stream (71) of a treatment device (67) is supplied.

30. The method according to any one of claims 17 to 29, wherein the asphaltene particles within a classifying zone (83, 117) of the container (15, 97) are separated according to their particle size.