JP6378502B2 - Method for recovering valuable materials from lithium ion secondary batteries - Google Patents

Description

The present invention relates to a method for recovering valuable materials from a lithium ion secondary battery, and more particularly to a method for easily and efficiently recovering valuable materials such as aluminum and copper from a lithium ion secondary battery.
In this specification and claims, a lithium ion secondary battery refers to a defective product generated in the manufacturing process of a lithium ion secondary battery or a small lithium for a mobile phone, a PC, or a home appliance that is used and discarded. It is a concept including an ion secondary battery, a large-sized lithium ion secondary battery for in-vehicle use or industrial use, and a battery containing other lithium as a constituent element.

  A lithium ion secondary battery includes a positive electrode material in which lithium, cobalt, nickel, or the like is applied to an aluminum foil, a negative electrode material in which graphite or the like is applied to a copper foil, an electrolyte, a separator, or the like. As described above, since lithium ion secondary batteries contain valuable materials such as lithium, cobalt, nickel, aluminum, and copper, these useful substances must be recovered from discarded lithium ion secondary batteries. Is very important for our poor country.

With regard to a method for recovering valuable materials from lithium ion secondary batteries, Patent Document 1 discloses a method in which used lithium secondary batteries are roasted and then crushed, and then crushed materials are sieved to collect the sieving. In addition, a recovery method for recovering cobalt has been proposed.
However, this proposed technique cannot efficiently recover other valuable materials such as aluminum and copper.

Patent Document 2 discloses that a used lithium battery built in an aluminum case is roasted together with the aluminum case, and the obtained roasted material is crushed and magnetically separated to be separated into a magnetic material and a non-magnetic material. Further, by applying a magnetic field from a magnet to a non-magnetic material that has generated eddy current and repelling the non-magnetic material from the magnet, the non-magnetic material is separated into crushed powder mainly composed of aluminum and crushed powder composed mainly of copper. A collection method has been proposed.
However, in this proposed technology, aluminum as a positive electrode current collector in the form of foil and copper as a negative electrode current collector exhibit complicated movement due to the influence of air when separated due to its shape. It was difficult to control the physical behavior of the object, and it was not always possible to easily separate valuable materials.

Furthermore, in Patent Document 3, a lithium ion secondary battery having a positive electrode having aluminum as a positive electrode current collector and a negative electrode having copper as a negative electrode current collector is heated by heating at a temperature of 250 ° C. to 550 ° C. A heating step for obtaining a product, a sorting step for sorting the positive electrode and the negative electrode in the heated product, and crushing the positive electrode and the negative electrode sorted by the sorting step, respectively. A crushing step to obtain each, a first sieving step for sieving the crushed positive electrode and collecting the aluminum, and a second sieving step for collecting the copper by sieving the crushed negative electrode and collecting the copper There has been proposed a method for recovering valuable materials from lithium ion secondary batteries.
However, in this proposed technique, when considering the selection process of the positive electrode and the negative electrode, in the heating process that is the previous process, it is desirable to heat in the state of the battery cell that facilitates the selection of the positive electrode and the negative electrode, In the case of a battery module that is an assembly of battery cells, and further, a battery pack that is an assembly of battery modules, it is necessary to heat them after disassembling them. Since it is a manual operation, it has not always been a simple and efficient method for recovering valuable materials.

Japanese Patent Laid-Open No. 06-346160 Japanese Patent Laid-Open No. 11-242967 JP 2013-80595 A

  The present invention has been made in view of the problems of the background art described above, and its purpose is to easily and efficiently recover valuable materials such as aluminum and copper from a lithium ion secondary battery. The object is to propose a method for recovering valuable materials from lithium ion secondary batteries.

In order to solve the above-described problems, the present invention is a method for recovering valuable materials from lithium ion secondary batteries described in [1] to [ 5 ] below.
[1] After heating the lithium ion secondary battery at a temperature of 600 to 1050 ° C. and then crushing, the obtained crushed material is sieved , and air current is applied to the crushed material of 1.0 to 10.0 mm. A method for recovering a valuable material from a lithium ion secondary battery, comprising performing shape selection and recovering aluminum as a heavy product and copper as a light product.
[ 2 ] The lithium ion secondary battery according to [ 1 ], wherein the heavy product obtained by the shape selection is further subjected to magnetic selection to separate iron-based metal from the heavy product. Valuable resources recovery method.
[ 3 ] The lithium as described in [ 1 ] above, wherein the iron-based metal is separated by magnetic separation for the crushed material exceeding 10.0 mm by the sieving, and then copper is recovered by color separation. A method for recovering valuable materials from ion secondary batteries.
[ 4 ] The method for recovering a valuable material from a lithium ion secondary battery according to any one of [1] to [ 3 ], wherein the shape selection is a combination of airflow and vibration.
[ 5 ] The method for recovering a valuable material from a lithium ion secondary battery according to the above [ 4 ], wherein the shape selection is performed using an air table.

  According to the valuable material recovery method from the lithium ion secondary battery according to the present invention described above, it is possible to process the lithium ion secondary battery without distinguishing the form of the battery, that is, the battery cell, the battery module, and the battery pack. Become. Further, valuable materials, particularly aluminum and copper, can be easily and efficiently recovered from the lithium ion secondary battery.

The structure image figure of an air table is shown.

  Hereinafter, an embodiment of a method for recovering a valuable material from a lithium ion secondary battery according to the present invention will be described in detail.

  A lithium ion secondary battery includes a positive electrode material in which lithium, cobalt, nickel, or the like is applied to an aluminum foil, a negative electrode material in which graphite or the like is applied to a copper foil, an electrolyte, a separator, or the like. Then, lithium ions move between the positive electrode material and the negative electrode material in the electrolytic solution, thereby serving as a battery.

  As described above, the lithium ion secondary battery is composed of a positive electrode material, a negative electrode material, an electrolyte solution, a separator, and the like, but the shape varies depending on the intended use. In particular, lithium ion secondary batteries used in vehicles such as electric vehicles (EV) and plug-in hybrid vehicles (PHV) have several types of battery cells such as laminate type, cylindrical type, and square type. The shape and size of battery modules that are aggregates and battery packs that are aggregates of battery modules vary greatly depending on the battery manufacturer and automobile manufacturer. Therefore, when recovering valuable materials from a lithium ion secondary battery, it is necessary to establish a method capable of processing these battery cells, battery modules, and battery packs without distinction.

The valuable material recovery method from the lithium ion secondary battery according to the present invention is not limited to the small lithium ion secondary battery used for PCs, mobile phones, etc., but is also used for large vehicles used for in-vehicle use such as EVs and PHVs. For lithium ion secondary batteries, each battery pack or battery module is first heated at a temperature of 600 ° C. or higher, then crushed, and then the obtained crushed material is subjected to shape selection using at least an air current, and aluminum is obtained. Is recovered as a heavy product and copper as a light product. That is, it includes at least a heating process, a crushing process, and a sorting process, and further includes other processes as necessary.
Hereinafter, each process described above will be described in detail.

-Heating process-
As a heating process, if the lithium ion secondary battery can be heated at a temperature of 600 ° C. or more without distinguishing battery cells, battery modules, and battery packs, there are no particular restrictions on the heating means, heating atmosphere, and the like. And can be appropriately selected according to the purpose.
By heating the lithium ion secondary battery at a temperature of 600 ° C. or higher, harmful substances such as an electrolyte contained in the battery are removed and detoxified. At the same time, the purpose is to remove the combustible material such as the separator and to melt the aluminum foil in the lithium ion secondary battery in order to increase the sorting efficiency in the later sorting process. For the purpose of melting the aluminum foil, the heating atmosphere is not limited. However, if heating is performed in an oxidizing atmosphere, heating is performed at a temperature of 600 ° C. or higher in a reducing atmosphere in order to prevent rapid combustion by combustible materials. If it is, it is desirable to process at the temperature of 663 degreeC or more which is melting | fusing point of aluminum. The molten aluminum foil can be effectively separated by heating under this temperature condition and crushing the subsequent process. From this viewpoint and economical viewpoint, the heating temperature is preferably 600 to 1050 ° C., which is not lower than the temperature at which the aluminum foil can be melted and is not higher than the melting point of copper, and more preferably 650 to 900. More preferably, the temperature is set to ° C.

  Here, the heating temperature refers to the temperature of the gas around the lithium ion secondary battery during heating, for example, the temperature of the gas in the vicinity where the lithium ion secondary battery is placed in the heating furnace during heating. . The heating time is not particularly limited, but is appropriately selected according to the shape and size of the lithium ion secondary battery, preferably 0.5 hours to 6 hours, and more preferably 1 hour to 4 hours.

  The lithium ion secondary battery can be heated using a furnace, and the furnace is not particularly limited. However, a rotary kiln furnace, a fluidized bed furnace, a tunnel furnace, a muffled batch furnace, a cupola furnace, a stalker, etc. A furnace or the like can be used.

-Shredding process-
In order to efficiently recover valuable materials such as aluminum and copper from a lithium ion secondary battery, it is necessary to separate constituent components and elements alone. The heated lithium ion secondary battery is crushed for the purpose of promoting the separation of the single element.
The crushing method in this crushing process is not limited, but in order to efficiently peel off the polar material components such as cobalt and nickel applied to the aluminum foil and the copper foil, that is, to separate the simple substance, the effect that the raw material is stirred and rubbed is effective. For example, a shearing crushing method having a stirring effect is preferable. As a crushing apparatus equipped with such an effective crushing technique, for example, a shearing crusher that performs crushing processing while recirculating crushing raw materials until it passes through a replaceable screen directly below the crushing blade. Can be mentioned.

  The crushing particle size in this crushing step is determined as appropriate in consideration of the ease of the separation of valuable substances such as aluminum and copper in the subsequent sorting step and the purpose of the simple substance separation described above. For example, when crushing is performed using the above-described shearing crusher, the opening diameter of the screen is set to about 40 mm, and the heated lithium ion secondary battery is crushed to a particle size that passes through the opening of the screen, that is, 40 mm or less. By doing this, it has been found that it is possible to sort valuable materials such as aluminum and copper in a subsequent sorting step.

  The crushing after heating in the present invention does not crush the lithium ion secondary battery as it is, but crushes the lithium ion secondary battery that becomes brittle and decreases in weight by heating at 600 ° C. or higher, so that the crushing burden is reduced. It has been reduced. Most of the heated products are metal, carbon and organic materials that are difficult to crush are almost gone, and the parts are physically peeled and decomposed by thermal expansion. Is done.

-Sieving process-
In the present invention, if necessary, sieving is performed after crushing. This sieving step is carried out in order to make the lithium ion secondary battery, which has been separated by heating and crushing steps, into a particle size band suitable for sorting each valuable material. In verification by the present inventors, a sieve based on the JIS Z 8801 standard was used, and a crushed material exceeding 10.0 mm, a crushed material of 1.0 to 10.0 mm, and a crushed material less than 1.0 mm. It has been found that sieving is suitable for sorting valuable materials, particularly for sorting aluminum, copper and cobalt. This is because the crushed material exceeding 10 mm has a tendency to concentrate copper which is difficult to be crushed. For intermediates of 1.0 to 10.0 mm, the shape of aluminum and copper is selected. This is because aluminum and copper can be efficiently recovered, and cobalt is concentrated in a crushed material less than 1.0 mm.
In the above crushing step, when most of the crushed material is a crushed material of 1.0 to 10.0 mm, the crushed material less than 1.0 mm in which cobalt is concentrated, aluminum and copper are concentrated. For the purpose of separating the crushed material, only a 1.0 mm sieving step may be performed. Further, depending on the sorting method in the later sorting process and the sorting apparatus to be used, this sieving process may be unnecessary.

-Sorting process-
The lithium ion secondary battery that has undergone the heating process and the crushing process is subjected to shape selection using an air stream, and aluminum is recovered as a heavy product and copper as a light product.
In this specification and claims, shape selection using airflow refers to air resistance (drag) received in airflow based on a difference in “shape” of the object, which is applied to an object for selecting airflow at least. This means that the object is selected using the difference. According to the shape selection using this airflow, the lithium ion secondary battery is processed under the heating and crushing conditions described above, so that the copper remains in a foil shape and the aluminum is adjusted to a molten mass. By changing this shape, it is possible to concentrate and separate the copper foil as a light product and the molten aluminum mass as a heavy product, unlike ordinary specific gravity sorting. Incidentally, the specific gravity of aluminum is 2.7 g / cm ^3, Tsukamatsuomo of copper is 8.94 g / cm ^3. This is a result of performing separation using the “shape” element largely by using the air flow among the “specific gravity”, “particle size” and “shape” which are the elements of selection.

Examples of the apparatus for performing shape selection using the airflow according to the present invention include a wind power sorter and an air table.
Wind sorters include blow-up type, suction type, and sealed type, but in any case, an air flow is formed in the main body of the sorter, and a processed material is introduced into the air flow, and a foil-like air resistance. A thing with a large (drag) is scattered with an air current and collected as a light product, and the granular material has gravity against the drag and falls and is collected as a heavy product. As a result, the foil-like copper is concentrated on the light product side, and the aluminum that has been melted and formed into a lump is concentrated on the heavy product side and recovered.

The air table uses both airflow and vibration, and selects an object based on the resistance to the airflow and the ease of rolling due to vibration, that is, the frictional force on the table surface.
FIG. 1 is a structural image diagram of an air table.
The object (Feed) is supplied from the feeder, and is subjected to a separation operation by vibration motion of the table surface (left and right direction in FIG. 1) and air flow (vertical direction from bottom to top in FIG. 1). In general, a heavy object is not easily affected by an air flow, is transported by a vibration motion, and falls to the left side (Heavy) in FIG. On the other hand, the lightweight object is strongly influenced by the air flow and floats to be in a state where there is little friction with the table surface, and the table tilts down and falls to the right side (Light) in FIG.
When an air table that has such a shape difference is supplied to an air table that performs such a separation operation, a thick or nearly spherical object is not significantly affected by the air flow. Similar behavior. In addition, thin foil-like objects are strongly affected by air flow, so even those having a large specific gravity behave in the same manner as lightweight objects. Therefore, the foil-like copper is concentrated on the light product side, and the aluminum that has been melted and formed into a lump is concentrated on the heavy product side and collected.

Other than the above wind sorter and air table, the target is sorted by using the difference in the air resistance (drag) received in the air flow based on the difference in the “shape” of the target object at least for the target to be sorted. Any device capable of performing the above can be used in the present invention. However, when sorting is performed with an air table, not only airflow but also vibration, and also the tilt angle of the table are parameters that affect sorting. By setting these to optimum values, higher accuracy can be achieved. Aluminum can be recovered as a heavy product and copper as a light product.
In the verification by the present inventors, it has been found that relatively high quality copper having a copper quality of 80 wt% or more can be recovered on the light product side by sorting using an air table. In addition to the molten aluminum lump and some copper foil, crushed iron scraps exist on the heavy product side. These can be separated from copper and aluminum by re-selecting the shape after removing iron scraps by magnetic separation, for example, but considering the quality of copper and aluminum and the selection cost, it is also possible to sell it as mixed metal It is done.

  When the above-described sieving is performed on the lithium ion secondary battery that has undergone the heating and crushing process, the shape selection using the airflow described above is performed on 1.0 to 10.0 mm sieving intermediate. Perform shape selection using airflow. This is because the crushed material in such a particle size range contains a large amount of foil-like copper and aluminum that has melted and formed into a lump shape, and copper and aluminum are efficiently separated by shape selection using an air flow. This is because it can be separated and recovered.

For crushed material exceeding 10.0 mm obtained by sieving, after separating the iron-based metal by magnetic sorting, copper is recovered by color sorting.
In this particle size band, in addition to stainless steel and iron-based components used in battery cells and battery modules of lithium ion secondary batteries, copper foil that is hard to be crushed is concentrated, and a small amount of aluminum foil and its molten mass exist. Stainless steel and iron parts can be easily removed by magnetic sorting. Moreover, since aluminum and copper exist as coarse grains exceeding 10.0 mm, separation becomes easy.
After separating the iron-based metal that is a magnetic deposit by the magnetic separation equipment, the copper and the non-magnetized aluminum and copper are selectively sorted by a known sorting equipment that combines a metal detector and a color sorting technique. By this screening, copper can obtain high-grade copper having a quality of 95 wt% or more.

  Cobalt is concentrated in the crushed material less than 1.0 mm obtained by sieving, so that cobalt can be efficiently recovered by a known refining process.

  EXAMPLES Next, although an Example is given and this invention is demonstrated further more concretely, this invention is not limited to this Example at all.

  Copper and aluminum were separated from an in-vehicle battery module made of an assembly of laminated battery cells, which are lithium ion secondary batteries, according to the valuable material recovery method according to the present invention.

  First, the in-vehicle battery module was subjected to heat treatment for 3 hours using a hot air type heating furnace capable of generating hot air of 600 ° C. to 700 ° C. The battery module subjected to this heat treatment was crushed to 40 mm or less using a shearing crusher having a stirring effect. The obtained crushed material was sieved into a crushed material having a mesh size of less than 1.0 mm, 1.0 to 10.00 mm, and more than 10.0 mm using a sieve having an opening of 1.0 mm and 10.0 mm based on the JIS Z 8801 standard. Divided.

  For crushed material exceeding 10.0 mm, the magnetic deposit was separated using a magnetic separator, and then the copper was separated using a color sorter.

  For the sieve intermediate of 1.0 to 10.0 mm, it was separated into light products and heavy products using an air table. Moreover, about the heavy product, the magnetic deposit was isolate | separated using the magnetic separator.

Table 1 shows the analytical values of copper, aluminum, and cobalt of the separated product, and Table 2 shows the respective material balances.

From Table 1 and Table 2, copper is separated and recovered from the crushed material exceeding 10.0 mm obtained by sieving, and a light product is obtained by shape selection using an air flow from 1.0 to 10.0 mm sieving intermediate. Thus, it can be seen that about 70% of the copper contained in the battery module can be recovered with high quality.
In addition, aluminum tends to be concentrated on the heavy product side due to sorting residue of crushed material exceeding 10.0 mm and shape sorting using airflow performed on crushed material of 1.0 to 10.0 mm, Thereby, it turns out that about 90% of the aluminum contained in the battery module can be recovered. However, since there is a concern that the quality of these materials is low, it is possible to improve the quality by sorting and re-sorting the shape again. Can also be sold.
As for cobalt, 60 to 70% of the battery module can be recovered as a crushed material of less than 1.0 mm. At the same time, since they contain a large amount of lithium, they can be reused as, for example, a cement raw material.

  The technology according to the present invention can be implemented without distinguishing the form of a lithium ion secondary battery, that is, a battery cell, a battery module, and a battery pack, and is also valuable from lithium ion secondary batteries, particularly aluminum, Because it is a method that can easily and efficiently recover copper, it should be used suitably as a valuable material recovery method from large-sized lithium ion secondary batteries for automotive and industrial use, where the market is expected to expand in the future. Can do.

Claims (5)

A lithium ion secondary battery is heated at a temperature of 600 to 1050 ° C. and then crushed, and then the obtained crushed material is sieved, and a shape using an air flow is applied to a crushed material of 1.0 to 10.0 mm. A method for recovering valuable materials from a lithium ion secondary battery, wherein sorting is performed to recover aluminum as a heavy product and copper as a light product. The valuable product recovery from the lithium ion secondary battery according to claim 1, wherein the heavy product obtained by the shape selection is further subjected to magnetic selection to separate iron-based metal from the heavy product. Method. 2. The lithium ion secondary battery according to claim 1 , wherein for the crushed material exceeding 10.0 mm by sieving, after separating the iron-based metal by magnetic separation, copper is recovered by color selection. 3. Valuables recovery method from The method for recovering a valuable material from a lithium ion secondary battery according to any one of claims 1 to 3, wherein the shape selection is a combination of airflow and vibration . The method for recovering a valuable material from a lithium ion secondary battery according to claim 4 , wherein the shape selection is performed using an air table .

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