PROCESS FOR PRODUCTION OF MICRO FIBRILLATED CELLULOSE
A method for producing micro fibrillated cellulosic material from pulp in which a pulp feed material is pre-treated by passing through a high consistency refiner a single time, followed by dilution and multiple passes through low consistency refiners.
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This application is a divisional application claiming the benefits of U.S. Non-Provisional patent application Ser. No. 14/050,799 filed Oct. 10, 2013, the entirety of which is incorporated herein by reference, the application in turn claims priority to and incorporates by reference provisional application 61/796,101, filed Nov. 2, 2012.
BACKGROUNDEmbodiments of the invention relate to methods to produce micro fibrillated cellulosic material from pulp material.
Cellulose is an organic compound that makes up the structural component of the cell wall in plants and many forms of algae. It is also the most common organic compound on Earth, as well as Earth's most plentiful renewable resource. Micro fibrillated cellulose (“MFC”) comprises a series of micro fibrils that have been separated from their original cellulose fiber. MFC fibers are extremely fine, usually comprising of numerous cellulose chains. MFC typically has a width ranging from 5-20 nanometers and a length ranging from tens of nanometers up to several microns. MFC can be produced from any cellulose source; however, wood pulp is the most commonly used feed material in MFC production.
The increased surface area of MFC allows it to have a much higher number of hydrogen bonds binding the fibrils together, and because of this, MFC has uniquely high strength properties. Additionally, because of an increased ability to use abundant and renewable feed material to produce MFC, MFC has gained attention as a feedstock for material with multiple uses including packaging and composite reinforcement, and has shown potential to replace petroleum-derived polymers.
Many processes have been identified for producing MFC. These processes include cryocrushing, homogenization, microfluidization, and micro-grinding. In cryocrushing, the feed material is frozen using liquid nitrogen prior to high impact forces being applied to separate the fibrils from the cell wall.
In the homogenization process, the feed material undergoes rapid pressure decreases; typically the pressure drop is around 8,000 psi. Homogenization can be scaled for larger production and can be run continuously. Homogenization is a commonly used process for MFC production and one of the easier processes to scale up to larger production. This process can be very energy intensive, commonly requiring greater than 30 MWh/ton. In order to reduce the energy requirements for the homogenization process to produce MFC, carboxymethylation, TEMPO-mediation oxidation and many other chemical pre-treatment steps have been used, but these pre-treatment steps can be very expensive.
Microfluidizers compress the feed material and operate at a constant shear. Microfluidizers can be manufactured with differing geometries in order to produce materials with varying size.
Micro-grinding is similar to disc refining. During this process, feed material is pushed through a gap between a rotating and a stationary disc. These discs have grooves that contact and separate the fibers. The equipment used for the micro-grinding process may have rotor and stator disc surfaces coated with silicon carbide to assist in grinding.
A micro-grinding process to produce MFC has been discussed in EP 1538257 (“EP '257”) to Japan Absorbent Technology Institute. EP '257 presents a method to produce micro fibrillated cellulose using a disc refiner in recirculation beginning with pulp produced from cellulosic material. This patent describes a process for obtaining MFC produced from pulp derived from cellulosic material by mechanically refining the pulp with a disc refiner. The MFC produced from the mechanical refining of the pulp described in EP '257 have fibers with a length of less than 0.2 mm and a water retention value of 10 mL/g or greater. In this process, prior to the mechanical refining of the pulp feedstock treatment, pulp must be diluted to a consistency of 1% to 6%. A mixture of water and ethanol may be used in the described process to reduce viscosity and improve the transferability of the pulp. Using the process of EP '257, MFC is said to be produced after at least ten passes, also known as circulations, through the mechanical refiner, although more passes through the refiner are suggested, resulting in high overall energy consumption.
Conventional methods resisted using medium and high consistency refiners due to the concerns of product quality, such as size and breakage versus desired product properties. Additionally, conventional processes require high energy consumption for refining processes to achieve the desired product, developing a lower energy consumption process is desirable.
Additional information for MFC production is disclosed in the following articles: “Enzymatic hydrolysis combined with mechanical shearing and high-pressure homogenization for nanoscale cellulose fibrils and strong gels” by Pääkkö, M., M. Ankerfors, H. Kosonen, A. Nykänen, S. Ahola, M. Österberg, J. Ruokolainen, J. Laine, P. T. Larsson, O. Ikkala, and T. Lindstrom (2007) published in the Biomacromolecules 8 (6): 1934-1941; Siró, István, and David Plackett. “Micro fibrillated cellulose and new nanocomposite materials: a review.” Springer Science+Business Media B.V. Cellulose (2010) 17: 459-494. Web. 4 Sep. 2012; “Processing and Properties of Micro fibrillated Cellulose”, by Spence, Kelley Lynn; Diss. North Carolina State University, 2011. Web; “The build-up of polyelectrolyte multilayers of microfibrillated cellulose and cationic polyelectrolytes”, by Wågberg, Lars; Gero Decher, Magnus Norgren, Tom Lindström, Mikael Ankerfors, and Karl Axnäs (2008), Langmuir 24 (3): 784-795.
BRIEF SUMMARYA process for producing MFC material having an average fiber length of 0.2 mm or less, with 20 ml/g or more water retention, while reducing the specific energy consumption (“SEC”) for the overall process, has been developed using mechanical refining equipment. The mechanical refiners used in this process can be a single disc refiner, a double disc refiner, a conical refiner, a rotating cylinder refiner, or other types of refiners used to mechanically grind or process cellulosic or lignocellulosic material (referred to herein collectively as “cellulosic material”) to produce individual fibers and smaller fibrillar elements. The feed material for this process may be previously treated cellulosic material (such as wood chips, annual plants, etc.) formed into pulp. The previous treatment of the cellulosic material to produce pulp used as the feed material for MFC can be a result of chemical digestion, such as Kraft cooking, sulfite cooking, soda cooking, biological, enzymatic treatment, etc., mechanical refining, a combination of chemical digestion and refining, or other known processes. An optional pre-treatment step is to introduce enzymes (for example cellulase enzymes) to the pulp after dilution or with the dilution liquid to dilution to either a medium consistency or low consistency prior to the medium or low consistency refining step. These enzymes may be introduced either while agitating the pulp or while not agitating the pulp. This enzyme pre-treatment step should be conducted at a temperature favorable to the enzyme activity and for a time, such as one hour, sufficient for the enzymes to perform the desired effect on the pulp.
The feed pulp material from cellulosic material may be diluted to a solids consistency of 6% to 15% and is frequently referred to as medium consistency pulp. This medium consistency pulp may be fed into a refiner capable of handling medium consistency pulp slurry. This refiner can be a medium consistency refiner, such as a single disc refiner or a double disc refiner with opposing discs, where at least one disc is movable relative to the other disc, or a conical refiner or a rotating cylinder refiner or other suitable refiner. The feed pulp material fed into the refiner may be pushed through a gap between the discs or opening in the conical or other suitable refiner where the pulp material may be subjected to a grinding action to reduce the fiber length, fibrillate, and separate the fibers into individual strands and fibrillar elements than in the feed pulp material. A number of passes through the refiner, desirably more than five passes, may be required to obtain the desired MFC product. In accordance with the present disclosure, the MFC fiber properties may have an average fiber length of 0.2 mm or less and 20 ml/g or higher water retention.
In another embodiment of the new process, feed pulp material generated from cellulosic material to produce a desirable feed pulp material, may be diluted to a solids consistency of 6% to 15% (frequently referred to as medium consistency pulp) and may be fed to a first refiner, such as a refiner capable of handling a medium consistency pulp slurry, typically either a single disc or double disc refiner with opposing discs (or conical refiner or rotating cylindrical refiner or other suitable refiner), with at least one disc being movable relative to the other disc, or a first conical refiner or rotating cylindrical refiner or other suitable refiner. The pulp material fed to the first medium consistency refiner may be pushed through a gap between the discs or opening in the conical refiner where the pulp material can be submitted to a grinding action to reduce the fiber length, fibrillate, and separate the fibers into individual strands and fibrillar elements than in the feed pulp material. The pulp material may make a number of passes through the first medium consistency refiner, possibly more than five passes through the first medium consistency refiner. Given the wide range of fineness of MFC product ranges, the number of passes can be quite substantial, and in some cases greater than fifty, depending on the final average length and other characteristics for the MFC. After passing through the first medium consistency refiner, the pulp material may be diluted to a solids consistency of less than 6% and fed to a second refiner which may be a low consistency refiner, capable of handling pulp material at a consistency of less than 6%. This second refiner may be a single disc refiner, a double disc refiner, a conical refiner, rotating cylindrical refiner, or other suitable refiner). The pulp material undergoes refining in the second refiner, which may be a low consistency refiner, for a number of passes, possibly fewer than ten passes through the second refiner, which may be a low consistency refiner, to obtain the desired MFC product. The resultant MFC product has an average fiber length of 0.2 mm or less and 20 ml/g or more water retention.
The process for producing the MFC material comprises the following steps: a) using feed pulp material produced from cellulosic material; b) diluting the feed pulp material to form medium consistency pulp; c) feeding the medium consistency pulp into a medium consistency refiner; d) using the medium consistency refiner to reduce the fiber length, fibrillate, and separate the fibers into strands and fibrillar elements; e) removing the medium consistency pulp from the refiner; and f) repeating steps c) through e) at least four times to produce MFC material wherein each succession of steps c) through e) uses the removed medium consistency pulp from the prior succession of steps c) through e).
In another embodiment, the process for producing MFC may further comprise: g) diluting the feed pulp material into low consistency pulp, h) feeding the low consistency pulp into a low consistency refiner, i) using the low consistency refiner to reduce the fiber length and fibrillate, and separate the fibers into strands and fibrillar elements, j) removing the low consistency pulp from the refiner, and k) repeating steps h) through j) less than ten times to produce MFC material wherein each succession of steps h) through j) uses the removed low consistency pulp from the prior succession of steps h) through j).
In another embodiment, a single refiner may be used for both the medium and low consistency refining passes. This may be accomplished by diluting while in recirculation mode, i.e., starting at medium consistency in recirculation for at least five passes (pulp material having 6% to 15% consistency), then recirculating at less than 6% consistency for fewer than ten passes.
In yet another embodiment, the process for producing MFC material comprises the steps of: a) using feed pulp material from cellulosic material processed to a high consistency feed pulp; b) pre-treating the high consistency feed pulp in high consistency refiner for a single pass through the high consistency refiner; c) removing the high consistency feed pulp from the high consistency refiner; d) diluting the high consistency feed pulp to form medium consistency pulp; e) feeding the medium consistency pulp into a medium consistency refiner; f) using the medium consistency refiner to reduce the fiber length, fibrillate, and separate the fibers into strands and fibrillar elements; g) removing the medium consistency pulp from the refiner; and h) repeating steps e) through g) at least four times to produce the MFC material, wherein each succession of steps e) through g) uses the removed medium consistency pulp produced by the prior succession of steps e) through g).
In another embodiment, the process for producing MFC material may further comprise: i) diluting the feed pulp material to a low consistency pulp, j) feeding the low consistency pulp into a low consistency refiner, k) using the low consistency refiner to reduce the fiber length, fibrillate, and separate the fibers into strands and fibrillar elements, l) removing the low consistency pulp from the refiner, and m) repeating steps j) through l) less than ten times to produce the MFC material, wherein each succession of steps j) through l) uses the removed low consistency pulp produced by the prior succession of steps j) through l).
High consistency feed pulp material may be feed pulp material with a solids consistency of greater than 15%. In some exemplary embodiments, the feed pulp material may have a solids consistency of greater than 20%. In other exemplary embodiments, the feed pulp material may have a solids consistency of greater than 35%. The feed pulp material may be fed to a pre-treatment refiner, which is also known as a pre-treatment high consistency refiner. This pre-treatment high consistency refiner may be a single disc refiner, a double disc refiner, a conical refiner, a rotating cylindrical refiner, or other suitable refiner. The feed pulp may be fed into the high consistency refiner for a single pass. The specific energy consumption of this pre-treatment high consistency refining step may be 600 KWh/ton or less. Once through the pre-treatment high consistency refiner, the pulp material may be diluted to a solids consistency of 6% to 15% and may be fed to a medium consistency refiner. The pulp material fed to the medium consistency refiner may be pushed through a gap between the discs or opening in the conical refiner where the pulp material can be submitted to a grinding action to reduce the fiber length, fibrillate, and separate the fibers into individual strands and fibrillar elements than in the feed pulp material. A number of passes through the medium consistency refiner may be made, and in some embodiments more than five passes may be made through the medium consistency refiner. The degree of fineness, in this case defined by the average fiber length, should be fine enough such that the final MFC product properties can be achieved with less than ten passes of subsequent low consistency refining. After passing through the medium consistency refiner for five or more passes, the pulp material may be diluted to a solids consistency of less than 6% and fed to a low consistency refiner. The pulp material may undergo refining in the low consistency refiner for a number of passes. Fewer than ten passes may be made through the low consistency refiner, in order to obtain the desired MFC product. The final MFC product resulting from the disclosed process may have less than 0.2 mm average fiber length and greater than 20 ml/g water retention. As indicated earlier, a single refiner can also be used for both the medium and low consistency refining passes using on-line dilution while in recirculation mode. In this example embodiment, the pump through refiner is usually configured to operate on both medium and low consistency fiber suspensions.
In another embodiment of the process, a feed pulp material with a solids consistency of greater than 15% may be used. In some exemplary embodiments, the feed pulp material may have a solids consistency of greater than 20%. In other exemplary embodiments, the feed pulp material may have a solids consistency of greater than 35%. The feed pulp material may be fed into a pre-treatment high consistency refiner for a single pass. The specific energy consumption of this pre-treatment high consistency refining step may be 600 KWh/ton or less. When through the pre-treatment high consistency refiner, the pulp material may be diluted to a solids consistency of 6% to 15% and may be fed into a medium consistency refiner. The pulp material fed into the medium consistency refiner may be pushed through a gap between the discs or opening in the conical refiner where the pulp material may be submitted to a grinding action to reduce the fiber length, fibrillate, and separate the fibers into individual strands and fibrillar elements than in the feed pulp material. A number of passes through the medium consistency refiner may be made, specifically more than five passes, to obtain the desired MFC product. The final MFC product may have an average fiber length of 0.2 mm or less with 20 ml/g or more water retention.
In still another embodiment, a process for producing MFC material comprises the steps of: a) using a feed pulp material from cellulosic material processed to a high consistency feed pulp; b) pre-treating the high consistency feed pulp in a high consistency refiner for a single pass through the high consistency refiner; c) removing the high consistency feed pulp from the high consistency refiner; d) diluting the high consistency feed pulp to form a low consistency pulp; e) feeding the low consistency pulp into a low consistency refiner; f) using the low consistency refiner to reduce the fiber length, fibrillate, and separate the fibers into strands and fibrillar elements; g) removing the low consistency pulp from the refiner; and h) repeating steps e) through g) less than ten times to produce the MFC material, wherein each succession of steps e) through g) uses the removed low consistency pulp produced by the prior succession of steps e) through g).
In still another embodiment, the feed pulp material may have a solids consistency of greater than 15%. In some exemplary embodiments, the feed pulp material may have a solids consistency of greater than 20%. In other exemplary embodiments, the feed pulp material may have a solids consistency of greater than 35%. The feed pulp material may be fed to a high consistency pre-treatment refiner for a single pass. The specific energy consumption of this pre-treatment high consistency refining step may be 600 KWh/ton or less. Once through the pre-treatment high consistency refiner, the pulp material may be diluted to a solids consistency of less than 6% and fed to a second refiner, which may be a low consistency refiner, capable of handling pulp material at a consistency of less than 6%. The pulp material may undergo refining in the low consistency refiner for a number of passes, possibly fewer than ten passes, to obtain the desired MFC product. The final refined product may have an average fiber length of 0.2 mm or less with 20 ml/g or more water retention. In some instances, the MFC specification may call for refining to less than an average fiber length of 50 microns. For all embodiments the MFC product produced during the refining steps may undergo subsequent process treatments as deemed desirable for a given end-product application.
In another example embodiment, a method to produce micro fibrillated cellulose (MFC) material has been conceived comprising: diluting a pulped cellulosic material to form a medium consistency pulp; feeding the medium consistency pulp into a medium consistency refiner; refining the medium consistency pulp in a medium consistency refiner to produce refined medium consistency pulp; removing the refined medium consistency pulp from the refiner; and repeating at least four times the feeding, the refining and the removing steps to produce MFC material, wherein in each repetition the feeding of the medium consistency pulp is performed with the refined medium consistency pulp from the prior repetition.
An additional option consistent with the disclosed process is to add enzymes. Cellulase enzymes may be desirable, but other acceptable enzymes could be used. Enzymes may be added to the pulp typically before dilution, but could be added after dilution, or even with the dilution liquid. These enzymes may be added to either a medium consistency slurry of pulp having a solids consistency of between 6% to 15% or to a low consistency slurry of pulp having a solids consistency of less than 6% but prior to the subsequent refining step. The pre-treatment with enzymes generally comprises adding the enzymes to the pulp slurry at a temperature of between about 30° C. and about 60° C. for a duration of between about 5 minutes to about 100 minutes, or about 30 minutes to about 90 minutes, or about 45 minutes to about 60 minutes. The contact of enzymes and pulp slurry may be in a tank, such as the tank where dilution of the pulp slurry occurs, but is not limited to a tank. The enzymes may be added with or without agitation of the pulp slurry. Suitable equipment generally permits for contacting the enzymes with the pulp slurry and sufficient retention time to allow for the desired reaction between the enzymes and the pulp slurry to occur.
When the enzymes are used to weaken or break the bonds in the cellulose chain of the pulp, less energy is required to accomplish the desired refining, thus reducing the operating costs of the process. With enzymes of the cellulase family, about 30% to about 60% less energy is consumed when the pre-treatment with enzymes before at least one of medium consistency refining or low consistency refining. In these tests, the control, represented by line 600, had no enzyme pre-treatment and used fine bar type refiner plates. Lines 610 and 620 reflect the tests conducted with an enzyme from the cellulase family using fine bar type refiner plates. The weight percentage varied of enzyme was varied in these two tests. From these tests it is clear the savings in cumulative SEC to obtain a given average fiber length is between about 40% to about 60%, a significant savings in energy. Comparing the test information represented by line 630 to that of the control, line 600, similar energy savings were obtained. The savings in operating costs is significant, even taking into account the additional costs for the enzyme as energy cost savings exceed the cost of the enzymes.
As a result of the tests where an additional pre-treatment step with enzyme prior to low consistency refining, it has been found the additional benefit of the MFC produced having improved transparency properties of a film compared to MFC produced without the enzyme pre-treatment, thereby increasing the value of the MFC produced. The improved film transparency is a result of increased development and separation of the cellulose micro-fibrils into a more uniform product.
While the invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not to be limited to the disclosed embodiment, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.
Claims
1. A process for producing micro fibrillated cellulose (MFC) material comprising:
- a) using a feed pulp material from cellulosic material processed to a high consistency feed pulp having a solids consistency of greater than 15 percent;
- b) pre-treating the high consistency feed pulp in a high consistency refiner for a single pass through the high consistency refiner;
- c) removing the high consistency feed pulp from the high consistency refiner;
- d) diluting the high consistency feed pulp to form a low consistency pulp having a solids consistency of less than 6 percent;
- e) feeding the low consistency pulp into a low consistency refiner;
- f) using the low consistency refiner to reduce the fiber length, fibrillate, and separate the fibers into strands and fibrillar elements;
- g) removing the low consistency pulp from the refiner; and
- h) repeating steps e) through g) less than ten times to produce the MFC material, wherein each succession of steps e) through g) uses the removed low consistency pulp produced by the prior succession of steps e) through g).
2. The process of claim 1, wherein the feed pulp material is wood pulp.
3. The process of claim 1, wherein the produced MFC material has an average fiber length of 0.2 mm or less and 20 mg/l or higher water retention.
4. The process of claim 1, wherein the pre-treating the high consistency feed pulp in a high consistency refiner step has a specific energy consumption of 600 KWh/ton or less.
5. The process of claim 1, wherein the produced MFC material has an average fiber length of the MFC of 50 microns.
6. The process of claim 1, wherein the produced MFC material is sent to a collection reservoir.
7. The process of claim 1 further comprising adding enzymes to the feed pulp material prior to step e) to form a pulp slurry, wherein the feed pulp material is agitated once the enzymes have been added.
8. The process of claim 7, wherein the pulp slurry has a temperature of between about 30° C. and about 60° C.
9. The process of claim 7, wherein the process has a duration between about 5 minutes to about 100 minutes.
10. The process of claim 7, wherein contact of enzymes and pulp slurry is in a tank.
11. The process of claim 10, wherein the tank is where dilution of the pulp slurry occurs.
12. The process of claim 1 further comprising adding enzymes to the feed pulp material prior to step e) to form a pulp slurry, wherein the feed pulp material is not agitated once the enzymes have been added.
13. The process of claim 12, wherein the pulp slurry has a temperature of between about 30° C. and about 60° C.
14. The process of claim 12, wherein the process has a duration between about 5 minutes to about 100 minutes.
15. The process of claim 12, wherein contact of enzymes and pulp slurry is in a tank.
16. The process of claim 15, wherein the tank is where dilution of the pulp slurry occurs.
Type: Application
Filed: Oct 10, 2014
Publication Date: Apr 2, 2015
Applicant: ANDRITZ INC. (Glens Falls, NY)
Inventors: Marc SABOURIN (Beavercreek, OH), Antti Luukkonen (Wien)
Application Number: 14/511,541
International Classification: D21H 17/00 (20060101); D21H 11/18 (20060101);