Patent Application
20250214844
The present invention relates to a method for obtaining graphite, and, where applicable, valuable metals, which are preferably selected from at least one of the metals of the first and/or the third main group and/or at least one of the metals of the 7th to 11th secondary group, from lithium-ion batteries, as well as a plant for obtaining graphite, and, where applicable, valuable materials from lithium-ion batteries, which is preferably designed to carry out the method according to the invention.
Due to the increasing use in electrically powered motor vehicles as an energy source, lithium-ion batteries will accumulate in large quantities in the near future during production and, at the end of their service life, they will accumulate as waste. These batteries are made of various valuable materials that are available as a composite. Essentially, these are:
Plastics, ferrous metals, copper, aluminium, graphite as anode material, metal oxides as cathode material, lithium, cobalt, nickel, manganese and other rare valuable materials as well as electrolyte.
About 50% of the battery modules consist of the so-called “black mass”, in which the particularly valuable raw materials are bound, and which consists mainly of fine graphite and lithium metal oxides in a size in the range of 0.5 to 10 μm. In addition, nickel, manganese, copper and cobalt are also to be regarded as particularly valuable components.
The battery blocks are connected in such a way that controlled disassembly, for example by loosening a screw connection, is practically impossible. In addition, very different formats are commercially available. Therefore, the manufacturer's instructions must always be observed before and during the unloading and separation process. Depending on the type of battery, it can even be necessary to activate special devices within the battery to activate the battery connections in order to be able to carry out the discharge. After opening the battery and discharging, the components must be separated. The metals and plastics of the housing can be sorted separately and supplied into a recycling management, wherein suitable recycling methods are already being used here.
The remaining battery blocks consist of individual battery cells and/or modules. Depending on the design of the battery, it is possible to simply separate the cells, but there are also batteries in which the separation of the battery blocks is very complex so that, in prior art, there is no satisfactory method for recycling the blocks or also the cells. The unpleasant characteristic of these batteries is that a complete discharge is very time-consuming, and the batteries exhibit voltage, i.e., a state of charge, after a short time following a discharge cycle. A battery that is not completely discharged usually suffers a short circuit when opened, which can ignite the electrolyte due to the effect of heat. The results in unforeseeable deflagrations leading all the way up to fires.
In some of the solutions known from prior art, attempts are made to thermally recycle the batteries by recovering the metals, wherein, however, the plastics, electrolyte and lithium are completely or extensively lost. In some methods, the battery cells are comminuted and transferred directly into the wet-chemical process. The battery cells are insufficiently separated before the subsequent wet-chemical precipitation method. This doubles the amount to be processed in the wet-chemical process. Such a wet-chemical method is described, for example, in EP 3 670 686 A1.
In addition, valuable raw materials in the black mass such as lithium, graphite, nickel, cobalt and other metals, for example, are lost during thermal recycling. This results in a high load on the precipitation chemistry or the wet-chemical method due to metallic and other residual materials of the battery shells and conductors.
From DE 10 2011 082 187 A1, a method for the comminution of batteries containing LiPF6 is known, in which the battery is subjected to a comminution process, which is carried out by means of at least one tool acting mechanically on the battery, wherein the comminution process takes place in an ambient fluid surrounding the battery, which comprises at least one alkaline earth metal. The ambient fluid is an aqueous solution containing calcium or magnesium, which are present as basic hydroxides Ca(OH)2 or Mg(OH)2 and react in aqueous solution with the hydrogen fluoride (HF for short) produced during the decomposition of LiPF6 to form poorly soluble CaF2 or MgF2 and are bonded in this way.
Based on the above-mentioned problems of the methods known from prior art, the task of the present invention is to provide an effective method in which valuable raw materials for a recycling management can be obtained from batteries that either come from the production scrap or have reached the end of their service life, in particular, graphite as well as valuable metals.
According to the invention, the task is solved by means of a method with the features of Patent claim 1.
The method according to the invention for obtaining graphite, and, where applicable, valuable metals, which are preferably selected from at least one of the metals of the first and/or the third main group and/or at least one of the metals of the 7th to 11th secondary group, from lithium-ion batteries, comprises at least one step in which the batteries with a residual charge of no more than 30% are comminuted with the addition of water in a comminuting device so that a mixture of comminuted batteries and water is obtained, wherein the mixture comprising the comminuted batteries and the water is separated by means of two separate process steps in such a way that the mixture is initially separated into a first aqueous graphite-enriched fraction in a first process step comprising particulate components with a size of >5000 μm, preferably with a size of >4000 μm, more preferably with a size of >3000 μm, even more preferably with a size of >2000 μm, and a second non-aqueous graphite-depleted fraction comprising particulate components with a size of <5000 μm, preferably with a size of <4000 μm, more preferably with a size of <3000 μm, even more preferably with a size of <2000 μm, the first aqueous graphite-enriched fraction comprising particulate components with a size of <5000 μm, preferably with a size of 4000 μm, even more preferably with a size of <3000 μm, even more preferred with a size of <2000 μm and then, in a second process step, into a first aqueous graphite-enriched freed fraction from the particulate components and a non-aqueous graphite-depleted fraction loaded with the particulate components, and wherein the first aqueous graphite-enriched fraction freed from the particulate components and the non-aqueous graphite-depleted fraction loaded with the particulate components are then freed from water.
The proposed method is characterized by a high level of effectiveness, which makes it possible to return more than about 95% of the valuable raw materials to the circular industry (recycling) in a very energy-efficient way. Surprisingly, in this way it has been shown that the complete discharge of the batteries is not necessary for the subsequent separation process, which can significantly reduce the effort involved in the preliminary process of the method. The energy gained during the partial discharge can also be favourably reused.
By comminution the batteries wet, the risk of deflagrations or even fires is reduced to a minimum. The water immediately reduces the temperature, preventing a chemical chain reaction. To this extent, the addition of a sufficient amount of water during the comminution of the batteries not only prevents greater heating, but it was also surprising to find that the harmful hydrogen fluoride is not released, or at least not in a measurable concentration. Currently, it is assumed that the reaction of hydrolysis of LiPF6 in pure water is very slow, as opposed to hydrolysis in contaminated electrolyte water, as shown in the following:
LiPF6→LiF+PF5
Only in the subsequent reaction,
PF5+H2O→POF3+2 HF,
would hydrogen fluoride be produced. In contrast to prior art, the method according to the invention thereby preferably does not use binding agents for binding the LiPF6, as described for example in DE 10 2011 082 187 A1.
A further advantage of the method according to the invention is also that the mechanical/fluid separation of the valuable raw materials (also referred to as “black mass”) from the metals and plastics loads the subsequent process steps with significantly less material, whereby a corresponding system can thus be operated more effectively and cost-effectively.
Further favourable embodiments according to the invention are specified in the dependently formulated claims. The features listed individually in the dependently formulated claims can be combined with each other in a technologically meaningful manner and can define further embodiments according to the invention. In addition, the features specified in the claims are further specified and explained in the description, wherein further preferred embodiments according to the invention are presented.
The first aqueous graphite-enriched fraction freed from the particulate components can preferably be made via a filter press. In the method according to the invention, this fraction contains a large part of the valuable black mass, which can be pressed through a filter by applying pressure and thus extensively freed from water. The pre-dried black mass can then be temporarily stored in a container.
The non-aqueous graphite-depleted fraction loaded with the particulate components is dried via a drying device, in particular by a vacuum dryer, in accordance with an favourable further embodiment of the method.
The vaporous condensate water produced during the drying process of the non-aqueous graphite-depleted fraction loaded with the particulate components can preferably first be condensed into hot water and, where applicable, then cooled down via a heat exchanger. The water thus obtained may be returned to the comminuting device and/or to the mixture comprising the comminuted batteries and the water.
In accordance with a favourable further embodiment of the present invention, the then dried non-aqueous graphite-depleted fraction loaded with the particulate components, which can comprise a graphite-containing secondary fraction, can first be comminuted and then separated into pure fractions. For this purpose, preferably, another comminuting device, in particular, an impact mill, is used.
Separation into the pure fractions can preferably be carried out by means of a sieve cascade which is designed to divide the comminuted heavy fraction into a first intermediate fraction with metal-containing particles in the range of about 250 μm to about 100 μm, a coarser fraction with plastic-containing particles in the order of more than 250 μm, and a third finer fraction with graphite-containing particles in the order of less than 100 μm. The middle fraction is then preferably separated into pure metallic fractions, where applicable, by means of an air separation table and/or a magnetic separator, in order to purely obtain the metals copper, aluminium, iron and/or manganese, for example, by type. The third finer fraction, which may still contain water, is preferably dried by sieving and pressing so that a dried graphite-containing secondary fraction is obtained.
A preferred further embodiment of the method provides that the aerosol produced during the comminution process and containing part of the graphite-containing secondary fraction is aspirated, wherein the part of the graphite-containing secondary fraction contained therein is separated, in particular, it is filtered, and, where applicable, combined with the remaining dried graphite-containing secondary fraction.
In summary, the preferred further separation process described above can be described as follows. The metals and plastics with adhering black mass are first separated in a separation method. Another comminuting device, in particular, an impact mill, knocks off the black mass on the metals. An aspiration system collects the dust, which essentially consists of black mass. A sieve cascade preferably separates the components sorted according to their size. Magnetic separators can be used, for example, to separate the ferromagnetic components. The other metals can be separated from each other, for example, by exploiting the density differences with an air separation table or the like. The metals are preferably collected separately and can be supplied into a recycling management. The lighter plastics are also preferably collected and can be supplied into a recycling management. The black mass is also preferably collected in order to be supplied into a further processing.
In another preferred further embodiment of the method, the water obtained during the drying process can be collected, then cooled by a heat exchanger and then returned to the comminuting device and/or the mixture comprising the batteries comminuted and water. The water can have particulate components with a size of up to 500 μm, for example. Alternatively, and/or additionally, the water can also be added to the process via a friction washer located downstream from the comminuting device.
In accordance with a preferred further embodiment of the present invention, the water is preferably supplied in relation to a quantity of 1000 kg of batteries per hour in a quantity of 20 to 200 m3/h. Due to the large and continuous volumetric flow, the heat generated during the mechanical comminution of the batteries and in the hydrolysis method is immediately dissipated. In accordance with the present invention, the comminution is therefore preferably not carried out in a standing water reservoir, but water is constantly supplied and discharged from the comminuting device in which the comminution takes place so that the heat generated in the process is also permanently dissipated.
According to the invention, for example, ordinary tap water at a temperature below room temperature can be supplied during comminution of the batteries. However, it is preferable that the water is supplied at a temperature within the range of 5° C. to 20° C.
The water management, for example, can be designed as a circulation system. For example, the water can be supplied into the comminution and/or separation process from a storage container and collected again downstream, for example, where separated particles are dried, for example, in a sieve press, and then returned to the comminution and/or separation process. In particular, filter systems can also be used to process the circulating water so that the exhaust air from a vacuum pump used in the system, for example, condenses and the condensate can be supplied back into the storage container. If further water is needed, it can be supplied from the line network (so-called make-up water). The circulating water can be monitored with regard to various parameters, such as pH value, conductivity, biocity, colour or the like for example. Where applicable, partial quantities of the circulating water can be exchanged in each case. The amount of circulating water required for the separation process according to the invention is approximately 20 to 200 m3/h/t batteries. In the case of two-step comminution, the use of at least 20 m3/h/t is recommended, preferably at least 50 m3/h/t. In the case of three-step comminution, it is preferred to use at least 50 m3/h/t of circulating water, being particularly preferred, about 100 m3/h per tonne of batteries
Preferably, the comminution of the batteries, particularly the battery cells and/or battery modules, is carried out in at least two steps in such a way that they are initially coarsely pre-comminuted in a first step before they are comminuted more finely in a subsequent second step. The selection of the number of comminution steps, for example two, three or more such steps, depends on the size of the material introduced. For complete battery modules with a size of more than 0.5 m, for example, a three-step comminution system is favourable. For individual battery cells or smaller units with a size of less than, for example, 0.5 m, a two-step system is usually sufficient.
The clear blade width in the comminuting device used in the last comminution step is preferably less than about 12 mm, preferably less than about 9 mm. The clear blade width in the penultimate step can then be less than 25 mm, preferably about 19 mm, for example. For example, with more than two comminution steps, the clear blade width of the third-to-last step is less than about 60 mm, preferably less than about 45 mm. The specific drive power, i.e., the drive power per throughput capacity in kg/h of battery cells and/or modules for the blade shafts, is about 50 W/kg battery cells and/or modules per hour, preferably about 80 to 120 W/kg/h.
In accordance with another preferred further embodiment of the method according to the invention, for the further processing of those fractions containing the main part of the black mass, the dried graphite-containing fraction and/or the graphite-containing secondary fraction are preferably mixed with concentrated sulphuric acid so that a graphite-containing pulp is obtained, wherein the obtained graphite-containing pulp is then filtered, for example, directly, so that graphite and a sulphuric acid solution are obtained.
The filtered graphite can then preferably be cleaned, in particular, be flushed with water. Furthermore, in this preferred variant of the method according to the invention, the sulphuric acid solution, which comprises at least one metal of the first and/or the third main group and/or at least one metal of the 7th to 11th secondary group, can then be wet chemically separated and/or wet chemically extracted.
According to the invention, the black mass obtained in the various separation processes described above is then preferably further processed in a wet-chemical process, in particular, dissolved by sulphuric acid, until the metals have dissolved in the acid. For example, the graphite can be separated, collected and recycled via a sieve press.
The individual metals, particularly selected from the series comprising lithium, aluminium, manganese, iron, cobalt, nickel, copper, can be precipitated, collected and supplied into a recycling management by specifically adjusting the acid concentration and/or temperature from the acid solution for example.
Acids or special intermediate products of particular interest to the basic industry can also be extracted directly from the method.
The acid is preferably circulated within a circulation system.
In summary, some preferred measures are listed below that serve the wet-chemical processing of the black mass previously obtained by the separation processes:
When complete car batteries, which are usually designed as relatively large components, are delivered, the design and electrical connections are fundamentally different, as each car manufacturer has its own specific structure. In these cases, additional measures or modifications to the processing method can be useful. For example, the car batteries can be detected according to the manufacturer and discharged and disassembled until the individual battery cells and/or modules are separated. For this purpose, it is advisable to consult the manufacturer's documentation and, where applicable, to deactivate auxiliary devices, such as safety devices within the battery for example, for the purpose of discharging. Depending on the materials used, the battery housing is also disassembled and supplied into the recycling industry by type, as are existing conductors, insulators and other components.
For example, the discharge can take place either on the complete car battery or on the individual battery cells and/or modules after assembly. The discharge energy of the batteries is preferably recycled, for example through direct grid feed-in, buffer storage or the like for example.
In particular, the mixer shaft of the separator or shredder used in the first separation process can be operated at a speed of at least 500 rpm, preferably more than 1000 rpm, preferably with more than 1500 rpm, in order to achieve effective flow conditions and movements of the particles in the comminuting device.
For example, the vacuum dryer can be operated at a pressure of less than 900 mbar. The temperature inside the dryer should preferably be more than 100° C.
It is favourable to use a control system with process monitoring that is suitable for recording and/or monitoring the water inlet and/or the quantity of batteries, particularly the battery cells and/or battery modules, and/or the concentration of the black mass.
The connected aspiration systems preferably used in the method according to the invention can collect the dust and guide it via a filter system, comprising, for example, a wet scrubber and/or ultra-fine filter with activated carbon and/or cyclone separator, in order to reduce the burden on the environment to a minimum.
The method according to the invention can be carried out either continuously or discontinuously, whereas the methods previously known from prior art are always only batch processes. The comminuting device according to the invention preferably operates continuously.
Important acids for the raw materials industry can be discharged from the wet-chemical method in accordance with a preferred further embodiment of the method. In the wet-chemical part of the method, sulphuric acid and/or ammonia are used, in particular, for the dissolving process. The setting of the temperature and the acid concentration preferably follows the precipitation rules for the respective metals one after the other in a cascade, wherein separate containers can be used depending on the setting.
All media used can be circulated so that the use of resources is reduced to a minimum. The energy consumption is significantly lower than with thermal separation methods due to the use of purely mechanical/fluid engineering methods.
In addition to the method described above, the object of the present invention is furthermore a plant for obtaining graphite, and possibly valuable metals, which are preferably selected from at least one of the metals of the first and/or the third main group and/or at least one of the metals of the 7th to 11th secondary group, from lithium-ion batteries, comprising at least one comminuting device which comprises a comminuting unit that can be flushed with an aqueous medium, at least one separation device downstream from the comminuting device in the transport route, which preferably comprises at least one sieve, suitable for separating material obtained in the comminuting device into at least two fractions with different particle sizes, at least one further separation device downstream from the separation device in the transport route, which preferably comprises a sieve, suitable for separating at least one fraction previously separated in the first separation device into at least two further fractions with different particle sizes, and at least two separate drying devices downstream from the separation device in the transport route for the drying of at least two fractions.
In accordance with a preferred further embodiment according to the invention, the comminuting unit comprises at least two comminution steps arranged one below the other according to gravity.
In accordance with a preferred further embodiment according to the invention, the plant comprises at least one comminuting device, preferably designed as an impact mill, wherein this is downstream from at least one other separation device in the transport route and serves to further reduce the particles of a previously separated fraction.
In accordance with a preferred further embodiment according to the invention, the plant comprises at least one plant area in the transport route downstream from at least one comminuting device and/or downstream from at least one separation device, in which area the particles of at least one previously separated fraction are dissolved in a liquid medium and then subjected to a further separation process, wherein this plant area comprises, in particular, a device for sieving and/or pressing and/or adjusting the pH value and/or extracting and/or crystallizing.
The invention and the technical environment are explained in more detail below using the figures. It should be pointed out that the invention is not intended to be limited by the exemplary embodiments shown. In particular, unless explicitly stated otherwise, it is also possible to extract partial aspects of the facts explained in the figures and combine them with other components and insights from the present description and/or figures. In particular, it should be pointed out that the figures and in particular the proportions depicted are only schematic. The same reference numbers designate the same items so that explanations from other figures can be used as a supplement. The figures show:
In the following, the sequence of an embodiment variant of the method according to the invention as well as the structure of an embodiment variant of the plant according to the invention for processing batteries for the purpose of recycling materials contained therein are explained in more detail.
The actual method for comminution the batteries and separating the components is first preceded by a preliminary process 1, which is described in the schematic diagram in accordance with
The isolated batteries, battery cells and/or battery modules, which are hereinafter understood under the general term “isolated batteries 10”, are first mixed with water 12 and preferably comminuted in a multi-step comminution process 13, for example, by means of a shredder. The water 12 is constantly supplied and serves, among other things, to dissipate the heat generated in the process so that hydrogen fluoride (HF for short) is not released. After the comminution process or step 13, the mixture comprising the comminuted batteries and the water can be separated into a first aqueous graphite-enriched fraction 15 and a second non-aqueous graphite-depleted fraction 16 (separation step 14), for example by centrifuging the mixture.
The first aqueous graphite-enriched fraction 15 obtained in accordance with the separation step 14, which contains the predominant fraction of the black mass, preferably comprises particulate components with a size of <3 mm, whereas the second non-aqueous graphite-depleted fraction 16 preferably comprises particulate components with a size of >3 mm. The first aqueous graphite-enriched fraction 15 can be directly freed from the water in accordance with a drying step 17 so that a dried graphite-containing fraction 18, which contains the predominant part of the black mass, is obtained.
In the sense of the present invention, “black mass” is understood to mean the mostly valuable raw materials which can subsequently be separated in a wet-chemical method, as shown in accordance with
However, the first aqueous graphite-enriched fraction 15 can also be separated into a first aqueous graphite-enriched fraction 19, which is freed from the particulate components, and a non-aqueous graphite-depleted fraction 20, which is loaded with the particulate components. For example, this can be sieved in a plurality of steps, first coarsely (step 21) and then finely (step 22) in order to obtain the non-aqueous graphite-depleted fraction 20 loaded with the particulate components. The first aqueous graphite-enriched fraction 19, which has been freed from the particulate components, can then be freed from the water, for example, via pressing (step 23). The contaminated water 24 can, after it has been purified and processed, where applicable, by suitable measures (step 25), returned to the water cycle and reused in the process.
The second non-aqueous graphite-depleted fraction 16, which may contain, for example, still moist small particles with a particle size within the range of about 3 mm to about 10 mm as well as foils and metals, is supplied into a second sub-process 26 for processing, which is shown in
In accordance with
The heavier metallic particles (heavy fraction 29), which contain the main part of the first graphite-containing secondary fraction 33, can be supplied into a comminuting device, in particular, an impact mill 34, the after separation described above in accordance with separation step 27, in which further comminution takes place. The different fractions obtained in this way can then b separated from each other by a sieving process 35, namely into a first intermediate fraction with particles within the range of about 250 μm to about 100 μm, a coarser fraction with particles in the magnitude of more than 250 μm and a third finer fraction with particles in the magnitude of less than 100 μm. The third, finer fraction then comprises the main part of the first graphite-containing secondary fraction 33, which is combined with the black mass fraction produced after passing through the separation step or filter system 32 and can also be supplied into the wet-chemical process (see
The coarser fraction shown in
This fraction 20 can first be dried in a drying device, in particular in a vacuum dryer 43, wherein the condensate water 44 produced in this method can be supplied into the water circuit 25. After the drying device 43, the material can be supplied into a comminuting device, in particular an impact mill 45, in which further comminution takes place. The comminution step is then followed by a sieving process 46 for the separation of the fractions obtained in this method. The plurality of fractions (for example, three) can be of the same order of magnitude as in the sieving process 35 described earlier in
The coarser fraction (>250 μm) usually contains mainly plastics 50. This can be collected by type (step 51) and also supplied into a recycling management 39. The middle fraction, on the other hand, can be further separated by means of an air separation table and/or a magnetic separator 52, for example, in order to collect the metals copper, aluminium and iron by type and also feed them into a recycling management 39.
The aerosol 55 produced during comminution step 45 that contains part of the second graphite-containing secondary fraction 49 can be aspirated from it via an aspiration step 53 and filtered via a separation step 56 so that the part of the second graphite-containing secondary fraction 49 contained therein is separated, in particular, it is filtered. The black mass fraction 54 produced after passing through the separation step or filter system 56 can also be combined directly or, where applicable, with the other fractions 18, 33, 49 and then supplied into the wet-chemical processing (see
In the following, the method of wet-chemical processing (fourth sub-process 57) of the various black-mass-containing fractions 18, 33, 49, 54 is explained in more detail on the basis of
The individual or possibly combined fractions containing black mass 18, 33, 49, 54 can be brought into solution by means of aqueous sulphuric acid, ammonia, hydrogen peroxide and/or organic solvents 58 (step 59) for example and then subjected to a sieving and/or filtering process 60. Graphite 61 can be separated, collected 62 and returned to the circular economy 39. The metals 63 obtained after this separation are in a solution, the pH value of which can be adjusted accordingly depending on the metal (step 64) where applicable. Extraction 65 can then be carried out, in which the metals can be extracted and crystallized or re-extracted, for example, as metal sulphates. Adjusting the pH value (step 64) depending on the metal and extracting can be done in a plurality of steps. Afterwards, the metal sulphates 66 of the individual metals of each step can be separated and collected by type (step 67) and thus obtained as raw materials 68 for basic industry. Superfluous ammonium sulphate 69 can be discharged and recycled 70 as shown in
In the following, an exemplary structure of a plant 71 for the separation process described above is described in detail on the basis of a plurality of schematic flow diagrams, initially with reference to
Below the lower end of the comminuting device 73 is the input end 75 of a friction washer 76, which includes a screw conveyor equipped with paddles. The friction washer 76 comprises a sieve located below the inclined screw conveyor. When the comminuted material, in particular the mixture comprising the comminuted batteries and the water, is conveyed by means of the screw conveyor from the input end 75 to the axially opposite output end 77 of the screw conveyor (from left to right in the drawing), then the finer material with a particle size of less than 1 to less than 3 mm, for example, (e.g., the first aqueous graphite-enriched fraction 15) falls through the sieve and passes through a line 78 below the input end 75 into a buffer tank 79. The coarser material with a particle size of more than 1 to more than 3 mm, for example (e.g., the second non-aqueous graphite-depleted fraction 16), on the other hand, is transported via the screw conveyor arranged in the friction washer 76 to its output end 77, falls down via the opening there and first reaches a silo 81 via line 80, from which it is supplied to the second sub-process 26. This will be explained in more detail later with reference to
The fraction of the finer particles, for example from less than 1 to less than 3 mm, is conveyed by means of a pump 82 to a sieve 83, by means of which a further separation is made into the two fractions 19, 20, namely a fraction 19 with a particle size of less than, for example, 500 μm, which contains the largest part, for example, containing about 95% of the black mass and about 5% metals and a fraction 20 with a particle size of more than, for example, 500 μm, which contains metals such as copper and aluminium as well as plastics with adhering black mass. This fraction 20 is supplied via line 84 and screw conveyor 85 to the third sub-process 42, which will be explained in more detail later with reference to
The separation process 11 shown as an example in the plant 71 can therefore be summarized as follows. The shredder 73, to which water 12 and individual batteries, battery cells and/or modules 10 are supplied, also serves as a separator in which the materials are first separated. Water is supplied to the shredder 73 in order to essentially remove the black mass from the other components of the individual batteries 10 and then transport them away. The shredder 73 is a extensively closed container, which is combined with the housing of the friction washer 76, which is located under the container and in which the screw conveyor is located. The combined device has two offset outlets. The first outlet, which is located in the entrance area 75 of the friction washer 76, is connected to line 78. The second outlet, which is located in the output region 77 of the friction washer 76, is connected to line 80. The mesh size of the sieve of the friction washer 76, which is located around the screw conveyor, can be used to determine the size of the smaller particles that allow the sieve to pass to the first outlet.
In the shredder 73, the small parts are swirled in the water so that the black mass is flushed off. Due to the collision of the small parts with the housing of the shredder 73 and the flow guides during the transport of the particles in the device, the black mass is additionally removed from the battery parts. The screw conveyor in the friction washer 76 below the shredder 73 comprises at least one mixer shaft with radially arranged levers, which, due to their shape, force a direction of movement from the input end 75 to the output end 77 with the second outlet in addition to the turbulence. Due to the separation process in the shredder/separator 73, the metal and plastic parts leave the device via the second outlet in the output region 77 of the screw conveyor, while the black mass falls through the sieve with the water and leaves the device via the first outlet in the input area 75 of the screw conveyor. The further separation of this material is then carried out via the further sieve 83, through which larger particles, particularly plastic particles with a size of more than 500 μm, for example, are separated from the black mass transported in the water. The mesh size of the additional sieve 83 can vary so that, for example, smaller particles within the range of about 100 μm to about 1 mm, preferably within the range of about 100 μm to about 500 μm, are separated.
The finer fraction of particles with a size of less than 500 μm enters the tank 86 and is then supplied by means of another pump 87 via line 88 to a further separation process of the first sub-process 11, which is explained in more detail below with reference to
In accordance with the flow diagram of
In the following, the further separation process 26 concerning the fraction of the coarse material 16 resulting from the first shredder process in accordance with
The medium-coarse fraction 20 separated in the separation process in accordance with
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2022 203 084.2 | Mar 2022 | DE | national |
| 10 2023 200 645.6 | Jan 2023 | DE | national |
| 10 2023 201 763.6 | Feb 2023 | DE | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2023/057996 | 3/28/2023 | WO |
