JP6088267B2 - NMP purification system - Google Patents

Description

  The present invention relates to an NMP purification system for purifying an NMP aqueous solution containing NMP (N-methyl-2-pyrrolidone).

  The main constituent materials of the positive electrode and the negative electrode in the lithium ion battery are an active material, a current collector, and a binder. The binder is generally obtained by dissolving polyvinylidene fluoride (PVDF) in N-methyl-2-pyrrolidone (NMP) as a dispersion medium. And an electrode is manufactured by apply | coating an active material and a binder mixed slurry to a collector. Here, NMP is gasified in the drying process after slurry application, but most of it is recovered due to environmental impact and cost issues. Recently, there are an increasing number of cases where the recovered NMP is reused in the manufacturing process.

The outline of the NMP recovery and reuse process is as follows.
(1) NMP in exhaust gas is recovered by an adsorbent or a water scrubber. By this step, NMP is concentrated to a state of about 70 to 90% of NMP and about 30 to 30% of water.
(2) The NMP / water mixture is purified by distillation. In this step, NMP is purified to 99% and moisture to 1% or less. Various impurities other than moisture are required to be removed at the same time.

  NMP purified in these steps is reused in the manufacturing process again. Further, distillation purification is performed both off-site and on-site.

  Thus, NMP recovery usually includes a distillation purification step. This distillation purification requires a lot of energy and has drawbacks such as an increase in the size of the apparatus.

  On the other hand, as a water separation technique, a technique utilizing pervaporation separation instead of distillation purification has been proposed. As the pervaporation membrane, a NaA-type zeolite membrane (inorganic porous support-zeolite membrane) or the like is used. Patent Document 1 discloses that an anhydrous alcohol is produced by using an osmotic vapor separation step. Patent Document 2 describes the purification of NMP by pervaporation separation (PV) method using a special framework type zeolite membrane that is not NaA type. A-type zeolite membranes such as NaA-type are widely used mainly in bioethanol production processes, but have the disadvantage of being vulnerable to acids.

  Patent Document 3 discloses that the sodium concentration in alcohol is measured by electrical conductivity.

JP 2004-51617 A JP 2012-67090 A Japanese Patent Laid-Open No. 11-64262

  Here, an NMP purification system using a pervaporation / separation (PV) method is required to be as efficient as possible and to have no problem with its quality upon reuse. In particular, elution of metals such as Na and Al from a separation membrane used for pervaporation separation (PV) becomes a problem.

  The object of the present invention is to suppress the decrease in purity of NMP due to metal ions such as Na and Al eluted from the pervaporation / separation (PV) means in the NMP purification system provided with the pervaporation / separation (PV) means and the ion exchange means. It is another object of the present invention to provide an NMP purification system that can purify NMP.

  The present invention relates to an NMP purification system for purifying an NMP aqueous solution containing NMP (N-methyl-2-pyrrolidone), wherein the NMP aqueous solution selectively permeates and vaporizes water through a separation membrane to obtain dehydrated NMP. Vapor separation means, ion exchange means for removing metal ions contained in the dehydrated NMP using an ion exchange resin to obtain purified NMP, and conductivity measuring means for measuring the conductivity of the purified NMP It is characterized by that.

  In one embodiment, the separation membrane is a NaA type zeolite membrane.

  In one embodiment, the metal ion concentration in the purified NMP is estimated from the conductivity measured by the conductivity measuring means, and the ion exchange resin in the ion exchange means is replaced when the metal ion concentration is a predetermined value or more. To do.

  Furthermore, in one form, it further has a preconductivity measuring means for measuring the conductivity of the dehydrated NMP supplied to the ion exchange means, and the measurement results of both the conductivity measuring means and the preconductivity measuring means. From this, the metal ion concentration is estimated.

  According to the present invention, dehydrated NMP is obtained by using pervaporation separation means, and this is ion exchanged by ion exchange means to remove impurities such as metals such as Na and Al and amines. The removal of metals such as Na and Al in the means can be performed reliably.

It is a block diagram which shows the whole structure of a system. It is a block diagram which shows the structure of an NMP refinement | purification system. It is a figure which shows the relationship between the metal ion concentration in refined NMP, and electrical conductivity. It is a figure which shows the relationship between the formic acid concentration contained in NMP, and electrical conductivity. It is a figure which shows the relationship between the formic acid concentration contained in NMP aqueous solution, and electrical conductivity.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a block diagram illustrating a configuration of an NMP purification system according to an embodiment.

  In the electrode manufacturing facility 10, an electrode manufacturing process of a lithium ion battery is performed using NMP. At the time of this electrode manufacture, an electrode is manufactured by apply | coating an active material and a binder mixed slurry to a collector. Here, a binder in which PVDF is dissolved in NMP is used as the binder, and NMP is gasified and exhausted in a drying step after slurry application.

  Exhaust gas from the electrode manufacturing facility 10 is introduced into a recovery device 12, where NMP is recovered. The recovery device 12 recovers NMP in the exhaust, and various methods can be used.

  For example, there is a method using a scrubber that sprays water, contacts with exhaust, and dissolves and recovers NMP in water. With this method, an aqueous solution of NMP having a relatively high water content can be obtained. On the other hand, the equipment itself is relatively simple, can be operated easily, can be processed at a low temperature, and can suppress the deterioration of NMP.

  In addition, there is an adsorption method in which NMP is adsorbed on an adsorbent such as activated carbon or zeolite, and then desorbed to separate and concentrate NMP. In this method, the NMP aqueous solution obtained by desorption from the adsorbent has relatively little water. However, since the temperature is relatively high at the time of desorption, there is a problem that NMP tends to deteriorate.

  Here, it is known that the NMP aqueous solution recovered from the lithium ion battery manufacturing process in this way contains a small amount of formic acid.

  If NMP contains 15% or more of moisture, the flash point disappears and it is treated as a non-hazardous material. Therefore, when NMP is purified off-site, it is common to keep the NMP concentration of the recovered aqueous solution at 85% or less (water content 15% or more) even if an adsorption method is used. For this reason, it is also preferable that the water content of the NMP aqueous solution recovered by the recovery device 12 is 15% or more. It is also suitable to replenish water if necessary.

  The NMP aqueous solution (recovered liquid) recovered in the recovery device 12 is supplied to the filtration device 14 to remove impurities. The filtration device 14 is a membrane filtration device using a UF (ultrafiltration) membrane or an MF (microfiltration) membrane, and removes solid matter contained in the recovered liquid.

  The filtrate obtained by the filtration device 14 is supplied to the ion exchange resin column 16 where excess ions are removed. In particular, acids such as nitric acid produced from amines and amines and the formic acid described above are removed.

  The treatment liquid (NMP aqueous solution) that has been desalted by the ion exchange resin column 16 is supplied to the NMP dehydration purification unit 30 including the pervaporation / separation (PV) device 18 and the ion exchange resin column 20, where water is removed. The recovered NMP is obtained.

  The water content of the recovered NMP dehydrated and concentrated in the NMP dehydration purification unit 30 is 1% or less. Then, the recovered NMP is once again removed from the ion exchange resin column 20 by removing ions such as amines, and then the suspended solids are removed by the filtration device 22 to be recovered and used in the electrode manufacturing facility 10.

  FIG. 2 shows the configurations of the ion exchange resin column 16, the pervaporation / separation (PV) apparatus 18, and the ion exchange resin column 20 that constitute the NMP purification system. As described above, the NMP aqueous solution with a water content of about 30% to 5% recovered by the recovery device 12 is supplied to the ion exchange resin column 16 where the ions are removed. The conductivity of the supply liquid is measured by the conductivity meter 34a, and the conductivity of the effluent from the ion exchange resin column 16 is measured by the conductivity meter 34b. A valve 32 for stopping the operation of the ion exchange resin column 16 is provided on the downstream side of the ion exchange resin column 16. The valve 32 may be provided on the upstream side of the ion exchange resin column 16.

  The NMP aqueous solution from the ion exchange resin column 16 is supplied to the heat exchanger 36 by a pump or the like, and is heated by passing through the heat exchanger 36. The NMP aqueous solution is supplied to the pervaporation / separation (PV) apparatus 18 which is a permeation vapor separation means. The Here, another heat exchanger is provided in the effluent piping of the ion exchange resin column 16, and the dehydrated NMP obtained by the pervaporation / separation (PV) apparatus 18 is supplied thereto, whereby the ion exchange resin column 16 The heat of dehydrated NMP may be transferred to the effluent. As a result, the effluent from the ion exchange resin column 16 can be heated and the dehydrated NMP can be cooled. Further, heating steam is supplied to the heat exchanger 36, and the heat of the heating steam raises the temperature of the NMP aqueous solution to an appropriate temperature, for example, 120 ° C., for supplying to the pervaporation separation (PV) apparatus 18.

  The pervaporation / separation (PV) apparatus 18 uses a separation membrane (permeation vaporization membrane) having an affinity for the component to be treated, and flows the mixture on the membrane supply side, and the reduced pressure or inert gas flows on the permeation side. Separated by the difference in permeation speed of each component.

  In the case of this embodiment, a zeolite membrane is used, and water is separated and concentrated on the permeate side and NMP on the supply side due to the hydrophilicity of the zeolite. At that time, the permeate water changes from a liquid to a gas (water vapor).

  Thus, the NMP aqueous solution is heated to about 120 ° C. by heat exchange by the heat exchanger 36 and supplied to the pervaporation / separation (PV) apparatus 18. The separation membrane of the pervaporation / separation (PV) apparatus 18 is, for example, a cylindrical membrane module that uses a NaA-type zeolite membrane. The NMP aqueous solution is supplied to the stock solution chamber (supply solution side) of the pervaporation / separation (PV) apparatus 18, while the permeation chamber (permeation side) is vacuum-exchanged via the heat exchanger 40 and the gas-liquid separator 42. A pump 44 is connected and the inside is depressurized. Therefore, water in the NMP aqueous solution is vaporized while penetrating the separation membrane, and is obtained as water vapor in the permeation chamber (permeation side). The water vapor obtained in the permeation chamber is cooled in the heat exchanger 40 to which cold water is supplied, and then introduced into the gas-liquid separator 42, where condensed water stays downward. The vacuum pump 44 is connected to the space above the gas-liquid separator 42, and the air from which moisture has been removed is exhausted by the vacuum pump 44. In addition, since NMP is contained in the air discharged | emitted from this vacuum pump 44, it is good to carry out this etc. by a detoxification apparatus. The abatement apparatus may perform, for example, a combustion process. Condensed water collected in the gas-liquid separator 42 is appropriately drained, but since the inside is in a reduced pressure state, the permeation chamber of the vacuum pump 44 and the pervaporation / separation (PV) device 18 is a valve or the like. After separation, drain it.

  Here, a NaA type zeolite membrane is adopted as the separation membrane of the pervaporation / separation (PV) apparatus 18. Since this separation membrane (A type zeolite membrane such as NaA type) is weak against acids such as formic acid, it is important to sufficiently remove the acid in the ion exchange resin column 16.

  In this embodiment, the conductivity of the NMP aqueous solution before and after the ion exchange resin column 16 is measured using the conductivity meters 34a and 34b, and the residual acid is detected. When the remaining acid is detected, the valve 32 is closed to stop the supply of the remaining NMP aqueous solution to the pervaporation / separation (PV) apparatus 18. Then, the ion exchange resin in the ion exchange resin column 16 is replaced. Of course, a plurality of new ion exchange resin columns 16 may be provided, and when the acid concentration of the effluent of the ion exchange resin column 16 in use increases, the ion exchange resin column 16 may be switched to another ion exchange resin column 16.

  Here, in the present embodiment, the acid concentration such as formic acid is detected by the conductivity meters 34a and 34b. This is because the conductivity of the NMP aqueous solution is relatively low and varies depending on the acid concentration. That is, the water content of the NMP aqueous solution that is the supply liquid of the ion exchange resin column 16 is about 30% to 5% of water, and if no acid is mixed, the conductivity is 0.05 μS / cm or less. On the other hand, when formic acid is mixed in at about 1 ppm, the conductivity rises to about 1.6 μS / cm. Further, if the water content is about 20%, the electrical conductivity is 1.3 μS / cm at a formic acid concentration of 0.5 ppm, and the electrical conductivity is 3 μS / cm at a formic acid concentration of 8 ppm. , Conductivity increases. That is, the formic acid concentration can be measured by conductivity.

  In the present embodiment, two conductivity meters 34 a and 34 b are provided, and the conductivity of the NMP aqueous solution before and after the treatment of the ion exchange resin column 16 is measured. Therefore, the change in conductivity before and after the treatment of the ion exchange resin column 16 can be constantly monitored. Accordingly, it is possible to grasp the removal rate of the formic acid and the like, the accumulated removal amount, etc., to know the more appropriate state of the ion exchange resin column 16, and formic acid and the like to flow into the pervaporation separation (PV) apparatus 18. Can be reliably prevented.

  Moreover, PVDF mainly used as a binder is known to cause a defluorination reaction by coexisting with a basic substance. Since the viscosity of the binder solution that has undergone the defluorination reaction changes before the reaction, it causes a failure in the slurry application process. For this reason, it is preferable to remove basic substances, particularly amines, from NMP.

  The ion exchange resin column 20 is filled with a mixed bed ion exchange resin, and removes metals such as Na and Al and amines in the liquid. Then, purified NMP from which metals such as Na and Al and amines are removed is obtained at the outlet of the ion exchange resin column 20.

  In this embodiment, two conductivity meters 38 a and 38 b are provided, and the conductivity of purified NMP before and after the treatment of the ion exchange resin column 20 is measured. Therefore, the change in conductivity before and after the treatment of the ion exchange resin column 20 can be constantly monitored. Therefore, the ion removal rate, integrated removal amount, etc. in the ion exchange resin column 20 can be grasped, and the appropriate state of the ion exchange resin column 2 can be known.

  In the pervaporation / separation (PV) apparatus 18, as described above, A-type zeolite is used as the separation membrane. When A-type zeolite is used for the separation membrane, there is a concern that its constituent components, Na and Al, may leak to the subsequent stage. If metal ions such as Na and Al are contained in the purified NMP after dehydration, there will be an adverse effect in the electrode manufacturing process of the lithium ion battery.

  Therefore, it is necessary to ensure that metal ions such as Na and Al are several tens of ppb or less in purified NMP to be reused.

  In this embodiment, an ion exchange resin column 20 is provided. Here, metal ions are removed, and conductivity meters 38a and 38b for measuring the conductivity of purified NMP before and after the ion exchange resin column 20 are provided. Provided. That is, the metal ions contained in the purified NMP are detected by measuring the conductivity of the purified NMP using the conductivity meters 38a and 38b.

  Here, commercially available NMP contains several hundred ppm of γ-butyrolactone, which is highly likely to be contained in purified NMP. Therefore, even if γ-butyrolactone is contained in several hundred ppm by experiment, there is no significant influence on the conductivity. On the other hand, if metal ions such as Na are several tens of ppb, the conductivity changes according to the metal ion concentration. It was confirmed. That is, NMP containing 300 ppm of γ-butyrolactone was made to contain Na ions in an amount of 0 to 100 ppb, the conductivity was measured, and it was confirmed that a significant change in conductivity could be detected even at 10 ppb.

  Then, the exchange time of the ion exchange resin in the ion exchange resin column 20 is determined from the detection results of the conductivity meters 38a and 38b, the valve 48 is closed, and the ion exchange resin is exchanged. Although the operation of the ion exchange resin column 20 may be stopped and the ion exchange resin may be replaced, it is preferable to prepare another column and switch the path.

  In this way, according to the present embodiment, it is possible to detect several tens of ppb levels for metals such as Na. Therefore, the level of the metal ions can be managed according to the detection results of the conductivity meters 38a and 38b, and in particular, monitoring can be performed online.

  In particular, in the present embodiment, conductivity meters 38a and 38b for measuring the conductivity of purified NMP before and after the ion exchange resin column 20 are provided. Therefore, the removal amount of metal ions in the ion exchange resin column 20 can be grasped. For this reason, the situation of the more suitable ion exchange resin column 20 can be known, and it can prevent reliably that a metal ion mixes with refinement | purification NMP.

"Experimental example"
Hereinafter, experimental examples will be described.

<Reference Example 1>
NMP having a purity of 99.5% or more was purchased, and γ-butyrolactone was added to this NMP to prepare NMP having various γ-butyrolactone concentrations.

Then, the NMP of the prepared various γ- butyrolactone concentration, while preventing absorption of moisture for the sealed container was filled with dry N ₂ in the headspace, is supplied to the conductivity meter, a conductivity was measured.

γ-butyrolactone concentration: 0 to 300 ppm
Conductivity meter: Foxboro 875CR (trade name: 875CR type conductivity / specific resistance measuring instrument manufactured by FOXBORO)
The results are shown in Table 1.

  Thus, it was found that the conductivity was constant regardless of the concentration of γ-butyrolactone (GBL).

<Specific example 1>
A predetermined concentration of NaClO ₄ was dissolved in NMP containing 300 ppm of γ-butyrolactone (GBL), and the relationship between the concentration and the conductivity was confirmed.

For the conductivity meter, Foxboro 875CR was used. The results are shown in Table 2. In the table, it is expressed as NaClO ₄ and the concentration as Na is described.

  Thus, it can be seen that the conductivity changes in accordance with the Na concentration at an Na concentration of 0 to 100 ppb, and the Na concentration of several ppb can also be detected by the conductivity. 3A and 3B show graphs corresponding to Table 2. FIG. FIG. 3A is a logarithmic scale for the vertical and horizontal axes.

<Reference Example 2>
NMP with a purity of 99.5% was purchased. Pure water was added to this NMP to prepare NMP aqueous solutions having various moisture concentrations.

Then, the various NMP solution prepared, for a sealed container, is filled with dry N ₂ in the headspace and maintained the water content. And it supplied to the conductivity meter from the sealed container, measured the conductivity, and confirmed the relationship between moisture and conductivity.

Moisture concentration: 1% to 30%
Conductivity meter: Foxboro 875CR (trade name: 875CR type conductivity / specific resistance measuring instrument manufactured by FOXBORO)
The results are shown in Table 3.

  Thus, the electrical conductivity was less than 0.05 μS / cm at a moisture content of 1-30%.

<Specific example 2>
A predetermined concentration (1 ppm) of formic acid was dissolved in each NMP aqueous solution having a moisture content of 1%, 10%, 20%, and 30%, and the relationship between moisture and conductivity was confirmed. That is, the NMP aqueous solution was filled in the sealed container, and the upper space was filled with dry N ₂ to maintain the moisture content. And the NMP aqueous solution in this sealed container was distribute | circulated to the conductivity meter, and the conductivity was measured. The conductivity meter used was Foxboro 875CR as described above. The results are shown in Table 4.

  Thus, if the formic acid content is 1 ppm, the conductivity of the NMP aqueous solution having a water content of 1% to 30% does not change much. Therefore, it was found that the formic acid concentration in the NMP aqueous solution can be sufficiently quantified. In particular, compared with the case of 0 ppm formic acid, there was a marked difference and it was sufficiently detectable.

<Specific example 3>
Formic acid was dissolved in an NMP aqueous solution having a water content of 15% and anhydrous NMP, and the conductivity was measured. The conditions are the same as in specific example 1.

Table 5 shows the relationship of conductivity to formic acid concentration in anhydrous NMP.

  Thus, the conductivity increases as the formic acid concentration in anhydrous NMP increases. Here, FIGS. 4A and 4B show graphs corresponding to Table 3. FIG. FIG. 4A is a logarithmic scale for the vertical and horizontal axes.

Table 4 shows the relationship between the formic acid concentration and the conductivity with respect to an NMP aqueous solution having a water content of 20%.

  Thus, the conductivity increases as the formic acid concentration in the NMP aqueous solution increases. 5A and 5B show graphs corresponding to Table 4. FIG. FIG. 5A is a logarithmic scale for the vertical axis and the horizontal axis (conductivity).

[Effect of this embodiment]
According to this embodiment, NMP can be purified while monitoring impurities (metal ions) contained in purified NMP obtained by treating dehydrated NMP from the pervaporation / separation (PV) apparatus 18 with the ion exchange resin column 20. it can.

  DESCRIPTION OF SYMBOLS 10 Electrode manufacturing equipment, 12 Collection | recovery apparatus, 14,22 Filtration apparatus, 16,20 Ion exchange resin column, 18 Permeation vapor separation (PV) apparatus, 30 NMP dehydration purification part, 32 Valve, 34a, 34b, 38a, 38b Electrical conductivity Total, 36,40 Heat exchanger, 42 Gas-liquid separator, 44 Vacuum pump.

Claims (5)

An NMP purification system for purifying an NMP aqueous solution containing NMP (N-methyl-2-pyrrolidone),
A pervaporation separation means for selectively dehydrating NMP aqueous solution through a separation membrane to obtain dehydrated NMP;
Ion exchange means for removing the metal ions contained in the dehydrated NMP using an ion exchange resin to obtain purified NMP;
Conductivity measuring means for measuring the conductivity of the purified NMP;
An NMP purification system. The NMP purification system according to claim 1,
An NMP purification system, wherein the separation membrane is a NaA-type zeolite membrane. The NMP purification system according to claim 1 or 2,
An NMP purification system that estimates the metal ion concentration in purified NMP from the conductivity measured by the conductivity measuring means, and replaces the ion exchange resin in the ion exchange means when the metal ion concentration is a predetermined value or more. The NMP purification system according to claim 3,
further,
A preconductivity measuring means for measuring the conductivity of dehydrated NMP before being supplied to the ion exchange means;
An NMP purification system for estimating a metal ion concentration from the measurement results of both the previous conductivity measuring means and the conductivity measuring means. The NMP purification system according to any one of claims 1 to 4,
An NMP purification system further comprising an ion exchange means for removing impurities contained in the NMP aqueous solution using an ion exchange resin in a stage preceding the pervaporation separation means.