DE102011075831A1 - Creating work-up process useful for working up starting material comprising water and lipophilic substance, comprises providing model of successively executable work-up steps, and providing work-up step to create work-up process - Google Patents

Abstract

Creating work-up process (400) for working up a starting material comprising water and a lipophilic substance (105), comprises: providing a model of optionally and successively executable work-up steps for successively working up the starting material in a specific order; and providing at least one work-up step to create the work-up process, where the provision is based on a prediction of a content of a component in the material, which is fed to the work-up steps, and based on a content (207) of the component in a desired output material of the workup process. Independent claims are also included for: (1) processing water and the lipophilic substance containing starting material, comprising creating the work-up process for processing the starting material, and carrying out the work-up procedure according to the created workup process; and (2) a device, which is formed to carry out the above method.

Description

The present invention is directed to a method for preparing a work-up process for working up a raw material, to a method for working up the starting material, as well as to an apparatus which is adapted to carry out the methods.

More particularly, the present invention relates to a process for preparing a work-up process and a work-up process which is suitable for working up water, in particular water, which is contaminated with organic and inorganic contaminants in dissolved or undissolved form, which occurs in an oil well is used.

In oil exploration, particularly so-called secondary oil production, water is injected or pumped into a wellbore, in particular using a pump, to thereby obtain higher production rates at other wells. In particular, when pumping the water into a borehole, a pressure in a reservoir of an oil reservoir increases, whereupon oil at an increased flow rate exits one or more other boreholes so as to be more easily conveyed. However, from the other wells no pure oil exits the reservoir of the oil deposit, but in particular a mixture of oil, gas, water and impurities, such as solid particles. The mixture can be worked up in a gas oil separation plant (GOSP), in particular partially separated into its components. The water thus obtained can be used for further injection or pumping into a well of the oil deposit (Water Reinjection).

Before pumping or injecting the recovered water into a borehole, the water, in particular the water already recovered from a borehole, must fulfill certain compositional requirements. In particular, undissolved, finely dispersed solids, solutes, and unseparated oil or fat, in coarse, medium, or fine distribution, interfere with re-pumping through a wellbore into a reservoir of oil well.

In particular, the solids must be removed as much as possible so as not to damage process equipment, such as an injection pump, and not to clog the permeability and / or porosity of the formation or reservoir of the oil deposit (filter cake).

Furthermore, oil in the water recovered from the borehole may settle in reinjection tubes and thus reduce "wells" performance. Furthermore, oil contained in the recovered water may also stick to the formation. Thus, a reduction of the oil content or concentration in the recovered water is required before the thus treated or reclaimed water can be reused for injection into a wellbore.

The composition of the recovered water and the requirements for the recovered water may vary from oil reservoir to oil reservoir and / or application dependent. Therefore, it may be necessary to customize the process steps individually to properly work up the recovered water. Furthermore, it may be necessary to add the reclaimed, recovered water with make-up water, or add additional water to the reclaimed recovered water, in particular to achieve a required total amount of water to perform the reinjection process can. The make-up water (also called make-up water) can be, for example, seawater, groundwater and / or surface water.

While basic process steps for working up water, particularly containing oil, grease and / or solids, are generally known, there may be a need to provide a work-up process which includes a feedstock containing water, oil, grease and / or solids. be cleaned up or worked up so that an output material meets predetermined conditions, in particular, observes or falls below predetermined concentrations of certain components.

There may be a need for a method for preparing a work-up process for working up a starting material, which contains in particular water and a lipophilic substance, which creates a work-up process, in particular without having to perform experiments or measurements, to given requirements of a starting material and / or an output material is adjusted. Further, there may be a need to create a work-up process that allows work-up of a feedstock in an economically attractive manner. Further, there may be a need for a work-up procedure to work up, especially to clean, a starting material containing water and a lipophilic substance, such that a starting material for a given starting material does not exceed predetermined concentrations of certain constituents.

The need can be met by the subject matters of the independent claims, wherein dependent claims specify example embodiments.

According to one embodiment of the present invention, there is provided a method of preparing a work-up process for work-up (in particular, cleaning, in particular, separation and / or filtering of undesired substances or constituents) of water (especially sea water, fresh water, groundwater or surface water) and a lipophilic (ie Substance having in particular aliphatic hydrocarbon chains, such as oil, fat, lipids or the like) substance containing starting material (a material to be supplied to the work-up process, in particular a liquid-solid mixture) is provided. In this case, the method comprises providing (in particular setting up, configuring, computationally determining, specifying) a modeling (in particular a physical modeling or mathematical modeling of a behavior of processing steps, in particular cleaning steps or separation steps or filter steps) of optionally (ie optionally switchable or switchable) one behind the other (or sequentially to be performed) in a specific order (in particular in a fixed order, which was determined on the basis of heuristic rules, theoretical considerations or calculation models) executable processing steps (wherein each processing step in particular using an associated processing machine or a refurbishment module or a reprocessing wherein each work-up step is a basic work-up process or a separation process or a filter method for separating unwanted constituents may have) for successive workup of the starting material. Furthermore, the method comprises providing (in particular selecting or activating within the workup process) at least one workup step (or several workup steps or all workup steps) of the workup steps (wherein a fixed number of workup steps may be predetermined, in particular the workup steps using different technologies for processing the starting material, in particular comprising centrifugation method, flotation method, filtering method, etc.) for execution (so that at least one work-up step determines the work-up process) to prepare the work-up process, wherein the provision (of the at least one Work-up step) on a prediction (in particular a computational prediction or a computed prediction) of a content (or concentration or relative amount) of a component s (or multiple constituents) in material to be fed to the work-up step, and a content (or concentration or proportion) of the constituent (or constituents) in a desired output material (which is the material ultimately output from the work-up process is) based on the refurbishment process. In particular, the ingredient may be a component, an element, a type of component or the like which should not be above a certain concentration or content in the dispensing material, i. in particular is at least partially removed from the starting material. In particular, the ingredient may be as a chemical element or a chemical class of elements or as a physical element or by a physical property such as size, hardness, physicochemical property, such as solubility in various solvents, hydrophilicity, lipophilicity or be characterized.

The work-up steps that can be carried out in the specific sequence can form a flowchart that corresponds to a chain of the work-up steps, wherein depending on the properties of the starting material and depending on the properties of the desired output material, only a subset of work-up steps can actually be used to modulate the work-up.

The specific order of the successive processing steps can be derived from heuristic rules. One rule may be to remove first of all dispersed solids (especially in order of decreasing size) so that the downstream cleaning equipment (especially work-up steps) will not be compromised in their refurbishment functionality or cleaning functionality. The dispersed solids may include, for example, salts, minerals, such as sand, which have an average size of between 100 nm to 10 mm. Another heuristic rule may be to provide a chain of work-up steps between which optionally a pump, a buffer tank and / or a mixer may be arranged.

Another heuristic rule may indicate that make-up water or make-up water is added or admixed only after the last work-up step, in particular to allow lower volume flows in previous work-up steps, which may allow a simplified work-up also because of higher concentration of impurities.

Another heuristic rule may indicate for different classes of impurities (for example, dispersed solids, oil or dissolved substances), which are categorized for example by "coarse", "medium" and "fine" (in particular with regard to their size and / or their weight and / or with regard to their concentration), to provide various work-up steps. If several workup steps or purification steps for a class of contaminants are needed to achieve the target output material requirements, the work-up steps may be successively applied in that order. Depending on the desired quality or the desired properties of the output material and the starting material, the necessary work-up steps can be extended.

If a favorable arrangement is found, further dimensioning and cost calculations can be carried out automatically. However, these two steps can also be carried out simultaneously in order to find the most favorable overall solution which meets all the requirements regarding the content of one or more constituents in the output material.

While modeling the various workup steps, it may be desirable to add certain chemicals, for example for corrosion protection, or to provide a pump just prior to reinjection.

The modeling can be done on an electronic computer (computer or server) running a computer program.

According to one embodiment of the invention, the method of preparing a refurbishment process further comprises specifying a respective refining effect for each of the refurbishment steps (wherein, for example, a change in concentration of the ingredient may be specified as it passes through the refurbishment step, for example by an indication of a reduction of the ingredient, for example an absolute indication or a relative indication), wherein the prediction (in particular the computed prediction) of the content (or concentration) of the constituent (or constituents) in the material to be supplied to the work-up step is based on the respective work-up effect (s). the respective work-up effects) of those work-up steps which are provided for execution in the order prior to the execution of the work-up step (to which the material is to be supplied).

In particular, for a component under consideration, a work-up effect can be specified for each work-up step which is provided within the work-up process, whereby it is possible to computationally determine a concentration or a content of the component after passing through each individual work-up step. Thus, a prediction of the content of the constituent is facilitated so as to omit (in particular not provide), in particular, unnecessary processing steps if, for example, the content of the constituent is already below a content of the constituent in the desired output material. Thus, a refurbishment process, which is based on the prepared refurbishment process, can be shortened and simplified.

According to one embodiment of the present invention, the work-up effect is determined by specifying a content of the constituent (or constituents) at an input port (where material to be processed, in particular, is to be introduced) and at an output port (where, in particular, the material reclaimed by the work-up modulus) of a work-up module ( a modeled device or apparatus) modeling the work-up step.

In this case, the work-up module can only mathematically model a physically existing work-up device or a work-up apparatus. The physically present refurbishment apparatus may have an input port that represents an actual embodiment of the input port and may further include an output port that is modeled as the output port of the refurbishment module. The content of the constituent may, for example, be given as the concentration in the units of parts per million (ppm) or mass per unit volume or percentage by weight. Specifying a work-up effect or specifying the content of the component at an input port and at an output port may further include specifying a pressure, a flow rate and / or a temperature. Thus, a work-up effect can be specified more precisely, which increases an accuracy of creating the work-up process.

According to one embodiment of the present invention, if the predicted content (or concentration) of the component (which is reduced by employing the at least one work-up step) in the material to be supplied to the work-up step is greater than the at least one work-up step as the content of the ingredient in the desired output material. If the content of the component in the material to be supplied to the work-up step is smaller than the content of the component in the desired output material, the work-up step in question may be omitted, that is, not intended (or not selected). As a result, the refurbishment process can be simplified and shortened.

According to an embodiment of the present invention, the intended work-up step outputs material, wherein the content of the ingredient in the dispensed material is smaller than the content (or concentration) of the ingredient in the feed material. The envisaged work-up step thus reduces the content (or concentration) of the ingredient in the material dispensed by the intended work-up step as compared to the content of the ingredient in the material provided to the intended work-up step. Thus, a reduction of undesirable components in the output material can be achieved.

According to an embodiment of the present invention, the method for preparing a work-up process further comprises specifying a content of the component in the starting material, wherein the content or concentration of the component may be given in, for example, parts per million (ppm). Specifying the content of the ingredient in the feedstock allows for successively calculating the content of the ingredient in successively going through the intended work-up steps. Thus, the content of the ingredient may be determined after passing through first work-up steps to decide whether to run through a work-up step located after the first work-up steps or possibly omit this subsequent work-up step so as to proceed to the next work-up step and decide whether this next processing step is required or not. This may be the case if this closest work-up step is suitable for reducing a constituent in its content, which content is still above a content of a desired output material.

According to an embodiment of the present invention, the method of preparing a refurbishment process further comprises predicting a composition (specifically, a specification of concentrations of multiple constituents) of the successively reclaimed starting material after each of the scheduled refining steps. For example, the composition may include an indication of a content of oil or fat, and / or an indication of a content of solids (in particular, specified sizes or diameters, respectively). In particular, the composition of the output material can be calculated on the basis of a known composition of the starting material and the workup effects or separation effects of the intended workup steps in order to be able to more accurately state a total workup effect of the workup process.

According to one embodiment of the present invention, the starting material (which is to be supplied to the work-up process) contains the lipophilic substance, in particular oil and / or fat, in a concentration range of between 0% by weight and 5% by weight, in particular between greater than 0% by weight. and 2% by weight. In this case, the lipophilic substance may be present in droplet form of a size between 100 nm and 5 mm. The oil may in particular be an oil obtained from an oil deposit, in particular crude oil. Thus, the method can be used in particular for working up, or cleaning of a fluid, which is obtained in oil production and what should be reused in particular for a secondary oil production.

According to one embodiment of the present invention, the starting material further contains solid particles (in particular pebbles, sand or quartz) in a concentration range between 0% by weight and 5% by weight, in particular between greater than 0% by weight and 2% by weight. In this case, the solid particles in particular have a mean size between 100 nm and 10 mm, in particular between 500 nm and 2 mm, more particularly between 1 .mu.m and 100 .mu.m. Thus, the method is particularly suitable for the treatment or purification of a fluid which is obtained in the crude oil production and typically contains solid particles.

The work-up steps can each be designed specifically for working up or purifying a fluid of oil or of solid particles.

According to one embodiment of the present invention, the work-up steps are, in particular in the specific order, a use of a solid-liquid-cyclone, a corrugated-plate-separator, a hydrocyclone for the separation of two liquid phases (liquid phase). liquid-cyclone), a flotation unit (flotation), a filter unit, in particular with walnut shell filter media (walnut shell filter), in particular in the preceding order, modeled, wherein executed by the apparatuses processing steps are successively modeled successively modeled.

In a physical actual work-up process, a solids separation hydrocyclone, a plate separator, a hydrocyclone for separating two liquid phases, a flotation unit, a filter unit (especially walnut shell filter) may be cascaded in this order and optionally selectable. This can be ensured that initially solids are removed, first coarse solids, then medium-sized solids can be removed or as "coarse" designated oil components, which oil components of medium size and finally oil components of finer size can be reduced. This can be used to create an effective refurbishment process.

In accordance with one embodiment of the present invention, the preparation of the refurbishment process further includes modeling a use of a pump and / or a tank and / or a mixer within the refurbishment process.

For example, a pump may be necessary to achieve a required pressure or to achieve a required flow rate during the work-up process. A tank can be used as a cache. A mixer can be used in particular for admixing make-up water to the processed starting material. This makes the refurbishment process more flexible.

According to an embodiment of the present invention, the preparation of the work-up process further comprises modeling an addition of make-up water, in particular seawater, surface water or groundwater, in particular to a material issued by the last intended work-up step. Thus, the work-up process can be made even more flexible, in particular to provide larger amounts of material (volume increase) for reinjecting into a wellbore.

According to one embodiment of the present invention, the work-up process is modeled as stationary, in particular at a constant flow rate (for example described by a volume per unit of time flowing through the work-up process) and / or constant pressure of the feedstock and / or discharged output material. By a stationary modeling of the work-up process or by an actual stationary operation of the work-up process by means of a physically existing apparatus, the work-up process can be carried out without intermediate storage of intermediate products, which simplifies the work-up process.

In accordance with one embodiment of the present invention, at least one operating parameter (or a larger number of operating parameters) of at least one of the scheduled work-up steps is adjusted to match a composition of the material dispensed by the work-up process with the desired output material.

The operating parameter may also be adjusted to improve economics of the refurbishment process. Furthermore, it can be ensured that the material output by the work-up process at least largely coincides with the requirements imposed on the desired output material.

According to an embodiment of the present invention, there is provided a process for working up a raw material containing water and a lipophilic substance, the process comprising establishing a work-up process for work-up of the starting material according to any one of the preceding embodiments of the present invention, and (actual physical) performing a work-up process according to the prepared refurbishment process.

Herein, performing the work-up procedure may include providing various work-up apparatuses configured to physically perform the work-up operations, i. actually perform material separation steps. Performing the work-up procedure may also include sequencing the intended work-up equipment so as to set up the work-up steps that are intended to be performed in sequence in the particular order. By previously creating the refurbishment process, unnecessary refurbishment equipment can be avoided, thus reducing the cost of the physically-done refurbishment process and speeding / simplifying it.

According to an embodiment of the present invention, the work-up method actually performed physically further comprises measuring a content of the component (or plural components) after performing the work-up step (or after performing a plurality of work-up steps which are provided); Comparing the measured content with the predicted content of that component (which is determined by arithmetically determining the content after passing through the modeled work-up step); and changing the method (and / or the modeling) based on a result of the comparing.

For example, if the content of the ingredient after performing one of the intended work-up steps (ie, the measured content of the ingredient) is greater than the predicted content of the ingredient, one or more further work-up steps may be included in the order prior to the work-up step concerned, which is also a reduction the content of the ingredient concerned. Alternatively, one or more operating parameters of one or more designated work-up steps may be changed to alter the content of the ingredient to better match the content of the ingredient in the desired output material.

According to one embodiment, an apparatus is provided, which is designed to carry out an embodiment of a method for creating a refurbishment process or an embodiment of a refurbishment process. The apparatus may include a processor, a memory for storing program code, an input unit, and an output unit. Further, the apparatus may comprise refurbishment apparatuses configured to physically perform the refurbishment steps.

According to one embodiment, there is provided a method of preparing a work-up process for working up a source material containing water and a lipophilic substance, the method comprising: specifying a content of at least one constituent in the feedstock; Specifying a content of the ingredient in a desired output material; Specifying a plurality of separation modules by a respective indication of a release effect on the component; Modeling the refurbishment process by a plurality of modeled separation methods sequentially applicable according to a flow chart, the plurality of separation processes of the plurality of separation modules by respectively predicting a content of the component at an output port of the separation module based on the content of the constituent material at an input port the separation module and on the separation effect of the separation module are modeled on the component; wherein at least one separation method of a separation module in the flowchart is optionally applicable in response to a condition to thereby prepare the work-up process, the condition depending on a predicted content of the component at the input port of the separation module and the content of the component in the desired output material.

It should be noted that embodiments of the invention have been described with reference to different subject matters. In particular, some embodiments of the invention are described with apparatus claims and other embodiments of the invention with method claims. However, it will be readily apparent to those skilled in the art upon reading this application that, unless explicitly stated otherwise, in addition to a combination of features belonging to a type of subject matter, any combination of features that may result in different types of features is also possible Subject matters belong.

Further advantages and features of the present invention will become apparent from the following description of exemplary embodiments. The individual figures of the drawing of this application are merely to be regarded as schematic and not necessarily to scale. Embodiments of the present invention will now be described with reference to the accompanying drawings. The invention is not limited to the described or illustrated embodiments.

1 schematically illustrates a flowchart for establishing a refurbishment method according to an embodiment of the present invention;

2 schematically shows an input mask for specifying starting material, make-up water and output material according to an embodiment of the present invention;

3 exemplifies an input mask for specifying a work-up effect of a work-up step according to an embodiment of the present invention; and

4 schematically shows a refurbishment process, which has been created according to an embodiment of the present invention.

1 schematically shows a flowchart 100 of processing steps arranged one behind the other, which are used to create a refurbishment process (see 4 ) is used according to an embodiment of the present invention. The flowchart shows a first process step 101 which models, like a source material 105 from a gas oil separation plant (GOSP) 103 is issued. The starting material 105 is done by means of a modeled mixer 107 a chemical substance from a container 109 added, for example, to reduce corrosion of components of a physically present work-up module. The starting material mixed with the chemical substance 111 gets into a tank 113 filled from where it by means of a pump 115 is made available to the subsequent processing steps.

That from the pump 115 leaking material 117 is specified by an indication of a content of oil and fat and an indication of a content of suspended particles, as in 2 in table 200 is illustrated. The material 105 has in this example 1000 ppm oil and fat 204 on and 500 ppm of suspended particles 205 , That in the starting material 105 respectively. 117 ( 1 ) contained fat or oil 204 and the solid particles 205 can still be specified in terms of their size (in the example of 2 not specified).

In the decision block 119 in 1 First it checks if the solids 205 in the material 117 have a concentration which is not greater than a content of an output material 121 (see table 201 in 2 "Target Specifications") in the issue process 123 of the schedule 100 lies. If this is not the case, then it will be in the branch 125 branches, which determines that the material 117 a refurbishment step 127 which is a hydrocyclone for solids separation 126 is, if hydrocyclone for solids separation is preferred. This hydrocyclone 127 separates solid particles 205 from the material 117 and gives out processed material.

On the other hand, if the solids 205 in the material 117 a given specification of the output material (see 2 table 201 ), the decision element branches 119 in the branch 131 , In particular, the work-up step reduces 127 (SL-C, "Solid-Liquid Cyclone", ie hydrocyclone for solids separation) the content of coarse solids in the material from the material stream 117 ,

In a subsequent decision element 133 is tested for medium-sized solid particles 205 also after application of a hydrocyclone for solids separation of the feed material below a content of the medium-sized solid particles which is specified by the desired output material, such as in the table 201 of the 2 is specified.

In particular, table specifies 201 in 2 the concentration of oil and fat, as well as the concentration of suspended solids in a desired output material. In particular, it is specified that the desired output material has a concentration of oil and fat 204 for example, at most 5 ppm and a concentration of suspended solids 205 of not more than 10 ppm, for example. Furthermore, the specification of the desired output material may include a specification of concentrations of oil and fat or suspended solids for various size classes such as "coarse", "medium", and "small" (in 2 not specified).

If in the decision element 133 in 1 It is determined that the requirements for a concentration of medium-sized solids 205 at this point are not met, will be in the branch 135 branches, which the material present there the work-up step 136 . 137 feeds, which a plate separator 138 modeled. There is an addition 134 a chemical substance according to the step 136 upstream, if it is foreseeable that a plate separator alone is not sufficient to achieve the required solids content in the starting material. On the other hand, if the requirements for a concentration of medium-sized solids 205 at the decision element 133 are already met, are the work-up steps 136 . 137 not done.

The material after that 139 becomes of another decision element 141 then examined if a content of oil 204 in coarse form a content of crude oil in the desired output material (specified in Table 201 in 2 ) exceeds or not. If the concentration of oil in coarse form is still above the desired concentration of coarse oil in the desired output material, so will the branch 143 Branches, which the material present there model a refurbishment step 145 supplying, which a work-up by means of a hydrocyclone for the separation of a liquid phase (LL-C, "Liquid Liquid Cyclone") 144 modeled, if previously no plate separator was used. The work-up step 145 is particularly suitable oil 204 in coarse form. Next is the work-up step 145 only modeled, if not the step before 137 (CPS, "Corrugated Plate Separator", ie plate separator) has been performed.

In another decision element 147 it is checked whether the material present there 146 has a concentration of oil of average shape or size less than the desired concentration of medium-sized oil in the desired output material (see Table 201 in 2 ). If the content of medium-sized oil is above the content of medium-sized oil in the desired output material, it becomes one branch 149 Branches, which model the material there present a work-up step 151 which performs an execution of a flotation process 150 modeled. When the content of medium-sized or medium-sized oil in the decision element 147 already meets the targets, becomes the refurbishment step 151 not done.

The then modeled material 153 becomes another decision element 155 which checks whether or not a concentration or a content of fine-sized oil satisfies the target with respect to the concentration of fine-form oil in the desired output material or not. If this is not the case, then it will be in a branch 157 branches, which model the existing material a refurbishment process 159 feeds which one pump 161 and a filter 163 modeled. In the decision element, the goal is a concentration of oil and fat of a fine size or fine shape 155 achieved, then the work-up step 159 not modeled.

The material thus available 162 is an output step 123 supplied, which is an admixing of additional water 164 by means of a mixer 165 includes, as well as a filling of a tank 167 , a pump by means of a pump 169 and an injecting 171 the final output material 170 in a borehole.

In particular, in the decision elements 119 . 133 . 141 . 147 and 155 checks whether the calculated concentrations of solids at the respective time 205 or oil and fat 204 in the different size steps the targets ( 2 table 201 ) of the desired output material or not. It also takes into account whether or to what extent, as specified 208 in 2 , in the output step 123 additional water 164 is added to the output material or not.

table 203 in 2 further illustrates a specification of make-up water 164 , here called make-up water, in terms of a concentration of oil and fat 204 and a concentration of suspended solids 205 , In particular, the concentration of oil and fat of make-up water, which is used as make-up water 164 in the output step 123 at 10 ppm and the concentration of suspended solids is 10 ppm.

3 illustrates a specification of a work-up effect of the work-up step 145 (LL-C) according to an embodiment of the present invention. table 301 in 3 (illustrated as "input") specifies a concentration of oil and fat 204 or of suspended solids 205 a material, which according to the branch 143 the LL-C is supplied. In particular, the concentration of oil and fat in the feed material is 1000 ppm. table 303 in 3 specifies a concentration of oil and fat or suspended solids in a material resulting from the work-up step 145 is issued. In particular, a concentration of oil and fat is that of the work-up step 145 delivered material 100 ppm, thus bringing the concentration of oil and fat by a factor of 10 by performing the work-up step 145 has been reduced.

Further, a flow rate (total flow), a pressure and a temperature are specified, which respectively are the operating parameters of the work-up step 145 specify at which the work-up effect or separation effect is achieved. A specification of the work-up effect may include multiple input and output concentrations or a separation factor (reduction factor) or a mathematical relationship.

4 schematically illustrates a refurbishment process 400 , which has been created according to an embodiment of the present invention. The refurbishment process 400 comprises a selection of processing steps or process steps, which are described in the flowchart 100 of the 1 the selection being based on a specification of the starting material, make-up water and output material, such as by tables 200 . 203 and 201 in 2 is illustrated.

First, the process steps or processing steps are as in box 101 of the 1 Illustrated, go through what a material 117 output. The material 117 is then through the work-up step 127 guided, then through the work-up step 145 , then through the work-up step 151 and then the refurbishment step 159 to be supplied, which by a pump 161 and a filter 163 is performed. Then a final work-up, as in box 123 of the 1 illustrated, executed.

This in the injection step 171 spent or pumped into the well reclaimed starting material 105 (ie the final output material 170 ) meets the requirements of the desired output material according to the table 201 of the 2 (target specifications) especially with regard to a concentration of oil and fat 204 (not above 5 ppm) and for a concentration of suspended solids 205 (not over 10 ppm). The thus worked-up starting material can be advantageously reused for a secondary oil production.

Claims (17)

Method for creating a refurbishment process ( 400 ) for working up a starting material, the water and a lipophilic substance ( 105 ), the method comprising: providing modeling optionally consecutively in a particular order executable processing steps ( 127 . 136 . 137 . 145 . 151 . 159 ) for successive work-up of the starting material ( 105 ); Providing at least one work-up step ( 127 . 136 . 137 . 145 . 151 . 159 ) of the refurbishment steps for execution to create the refurbishment process, the providing based on a prediction of a content of an ingredient ( 204 . 205 ) in material to be supplied to the work-up step and on a content ( 207 ) of the component in a desired output material of the refurbishment process. The method of claim 1, further comprising: specifying a respective work-up effect ( 301 . 303 ) for each of the work-up steps, wherein the prediction of the content of the constituent in the material to be fed to the work-up step is based on the respective work-up effect of those work-up steps intended to be performed in the order prior to the work-up step. The method of claim 2, wherein the work-up action comprises, by specifying a content of the ingredient at an input port ( 304 ) and at an output port ( 306 ) of a refurbishment module ( 144 ), which completes the work-up step ( 145 ), is described. Method according to one of the preceding claims, wherein the at least one work-up step is provided for execution if the predicted content of the constituent in the material to be fed to the work-up step is greater than the content of the constituent in the desired output material. A method according to any one of the preceding claims, wherein the intended work-up step outputs material, wherein the content of the ingredient in the dispensed material is less than the content of the ingredient in the feed material. The method of any one of the preceding claims, further comprising: specifying a content ( 206 ) of the component ( 204 . 205 ) in the starting material ( 105 ). The method of any one of the preceding claims, further comprising: Predicting a composition of the successively reclaimed starting material after each of the scheduled work-up steps. Method according to one of the preceding claims, wherein the starting material, the lipophilic substance, in particular oil and / or fat, in a concentration range of between 0 wt.% And 5 wt.%, In particular between greater than 0 wt.% And 2 wt.%, contains. Process according to any of the preceding claims, wherein the starting material further comprises solid particles ( 205 ) in a concentration range between 0 wt.% And 5 wt.%, In particular between greater than 0 wt.% And 2 wt.%, Contains, wherein the solid particles in particular a mean size between 100 nm and 10 mm, in particular between 500 nm and 2 mm, more particularly between 1 .mu.m and 100 .mu.m. Process according to one of the preceding claims, wherein the work-up steps, in particular in the particular order, are carried out using a hydrocyclone for solids separation ( 126 ), a disk separator ( 134 ), a hydrocyclone for separating a liquid phase ( 144 ), a flotation unit ( 150 ), a filter unit ( 163 ), in particular walnut shell filters, in particular in the preceding sequence, as are successively modeled successively modeled. The method of claim 1, wherein the preparing the refurbishment process further comprises modeling a use of a pump. 161 ) and / or a tank or several tanks ( 113 . 167 ) and / or a mixer ( 107 . 165 ) within the refurbishment process ( 400 ) having. The method of any one of the preceding claims, wherein the preparing the refurbishment process further comprises modeling an addition of make-up water ( 164 ), in particular to a material output by the last intended processing step, wherein the addition of make-up water is taken into account in a decision as to whether a work-up step is provided or not. Method according to one of the preceding claims, wherein the work-up process as stationary, in particular at a constant flow rate ( 208 ) and / or constant pressure ( 210 ) of the supplied starting material ( 105 ) and / or the discharged output material ( 170 ), is modeled. Method according to one of the preceding claims, wherein at least one operating parameter ( 208 . 210 . 212 ) at least one of the scheduled work-up steps is adjusted to match a composition of the material output from the work-up process with the desired output material. A method for recovering a source material containing water and a lipophilic substance, the method comprising: creating a work-up process ( 400 ) for working up the starting material ( 105 ) according to one of the preceding claims; and performing a refurbishment process in accordance with the refurbishment process created. The method of claim 15, further comprising: Measuring a content of the component after carrying out the work-up step; Comparing the measured content with the predicted content; Change the method based on a result of the comparison. Device which is designed to carry out a method according to one of the preceding claims.

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