The invention relates to refining of lignocellulosic fibrous material and particularly to thermomechanical pulping (TMP) and other mechanical refining processes.
TMP processes have conventionally refined fibrous material at high consistencies, typically having consistencies of 20 percent (20%) or more fiber by weight of the pulp suspension passing through the refiner. At high consistency levels, the pulp suspension is a fibrous mass and is transported by a pressurized blowline or screw conveyor which can handle such masses. In contrast, pulp suspensions at lower consistency levels flow as a liquid slurry that can be moved by pumps.
Mechanically refining pulp at a high consistency requires a large amount of energy that is expended primarily in frictional heat losses associated with viscoelastic deformations of the pulp in the refining zone. These frictional heat losses result in a large amount of energy that is not applied directly to refining pulp. Refining pulp is the separation (defibrate) and development (fibrillate) of the wood fibers. Typically less than 10% to 15% of the electric energy applied in a high consistency TMP refiner is directly applied to refining the pulp. There is a long felt need to increase the energy efficiency of a TMP refiner.
To address the need for lower electric energy consumption, TMP mills are searching for ways of displacing energy-intensive high consistency refining (HCR) with less energy intensive refining processes. Over the last ten to fifteen years many TMP mills have installed a single low consistency refining (LCR) stage directly following a mainline high consistency refining (HCR) stage. In most of these mill applications, the low consistency refiner (LCR) applies a specific energy less than 150 kWh/ODMT (kilowatt hours per oven dried metric ton) and displaces less than 100 ml (milliliters) of freeness.
Because low consistency refiners apply energy to a fluid pulp slurry, they tend to operate at significantly higher refining intensities than do high consistency refiners. However, the high refining intensities and fluid medium limits the total energy that can be applied in the refining zone of a LCR. Further, low consistency refining tends to produce pulp having limited freeness reduction. The limited displacement of freeness arises from excessive shearing of fibers and loss in pulp strength due to a narrow plate gap and a high energy load in a single stage of low consistency refining. Multiple stages of low consistency refining have been proposed. However, there is a practical limit to the number of LCR stages due to the inherent shearing of less developed (high freeness) mechanical pulp fibers in low consistency refiners.
Entailing fiber pretreatments to increase fiber flexibility and resistance to shearing resulted in a displacement of approximately 400 mL of high consistency refining with multiple stages of low consistency refining and energy savings of more than 30% as compared to conventionally produced thermomechanical (TMP) pulps. These entailing pretreatment methods included partial wood fiber defibration in a pressurized chip press (such as described in U.S. Pat. No. 6,899,791) followed by gentle fiber separation in a high consistency refiner (such as described in U.S. Pat. No. 7,300,541), chemical treatment, and high-pressure/high-intensity primary refining (such as described in U.S. Pat. No. 5,776,305, and U.S. Pat. No. 6,165,317). These pretreatments help improve fiber development and minimize fiber damage when low consistency refining across such a large span of freeness.
Despite continued advances in thermomechanical pulping there remain several long felt needs including: i) improving pulp quality development; ii) developing less-energy intensive pump-through refiners, and iii) reducing the complexity and cost of mechanical equipment in TMP systems.
A novel TMP process has been developed having an initial HCR stage and at least one subsequent medium consistency refining (MCR) stage. The MCR stage(s) processes a thick stock pulp slurry of wood chips, pre-conditioned cellulosic fibers, or other comminuted cellulosic material, having a pulp consistency in a range of 5% to 14% consistency. In contrast, LCR stages conventionally process a liquid pulp slurry having a consistency of typically below 5%. The use of a MCR stage(s) increases the pulping capacity of the refining process and reduces the number of refiners, as compared to a similar conventional TMP process with LCR stages. For example, a medium consistency (MC) refiner processing pulp having a consistency of 8% may replace two equally sized low consistency (LC) refiners processing pulp having a consistency of 4%.
The novel TMP process with a MCR stage(s) reduces energy consumption by limiting high consistency refining (HCR), preferably to a single HCR stage, and shifting a large portion of the refining activity from the HCR stage to the medium consistency refining stage(s). In so doing, both the number of high consistency refiners and pump-through refiners are preferably reduced, as compared to conventional TMP processes having HCR and several LCR stages. Further, a MCR stage(s) provides enhanced pulp quality development as compared to conventional TMP processes having HCR and LCR stages. The combined HCR and MCR stages produce pulp having high quality, such as pulp having high tensile strength, especially at low freeness levels.
The novel TMP process disclosed here includes a first HCR step, preferably with preconditioning treatments to enhance fiber development prior to medium consistency refining, and at least one subsequent MCR stage. An MC pump-through refiner may be configured to process twice the amount of pulp processed by a same sized conventional LC refiner. MC refiners may be used to reduce the total number of refining stages in a mill operation. The preconditioning step should improve the MC refining response at higher freeness levels, and increase displacement of energy-intensive HCR. The TMP pretreatments may include partial defibration in a pressurized chip press, gentle fiber separation in a fiberizer refiner, chemical treatments (before, during, or after the HC refining stage), high-intensity or high-pressure HC refining, and a combination of these processes.
A thermomechanical pulping method has been developed including: refining pulp with a high consistency refining stage, and a medium consistency refining (MCR) stage or multiple MCR stages processing the refined pulp discharge from the high consistency refining stage. The high consistency refining stage may include refining the pulp, such as wood chips, pre-conditioned wood fiber and comminuted cellulosic material, with a pressurized high consistency refiner. The method may further include diluting the refined pulp discharged by the high consistency refining stage in a standpipe and fluidizing the pulp in the standpipe. The medium consistency refining stage may include a mechanical disc refiner having plate segments with an open inlet.
A thermomechanical pulping method has been developed comprising: refining wood chips, pre-conditioned wood fibers or other comminuted cellulosic materials in a high consistency pulp suspension using a high consistency refining (HCR) stage, wherein the pulp suspension has a pulp consistency of at least twenty percent (20%) by weight of the suspension; diluting the suspension of refined pulp discharged from the HCR stage to a medium consistency having a pulp consistency in a range of 5% to 14% consistency by weight, and refining the refined pulp in the medium consistency suspension formed in the dilution step using a medium consistency refining (MCR) stage.
A thermomechanical pulping system has been developed comprising: a high consistency refining stage having an inlet receiving wood chips, pre-conditioned chips or fibrous material, or other comminuted cellulosic material, a refining zone, and an outlet discharging refined high consistency pulp; a pulp dilution stage have a first inlet to receive the refined high consistency pulp and a second inlet to receive a liquor, a chamber to dilute the refined high consistency pulp with the liquor to form medium consistency pulp, and an outlet discharging the medium consistency pulp, and a medium consistency refining stage having an inlet receiving the medium consistency pulp from the outlet of the pulp dilution stage, wherein the medium consistency refining stage includes a refining zone to refine the medium consistency pulp and an outlet for the refined medium consistency pulp.
The partially refined pulp discharged from the primary refiner 12 flows to a standpipe 16. The partially refined pulp has a high consistency, such as greater than 20%. The high consistency pulp is either blown or conveyed, e.g., by a blowpipe or screw conveyor 17, to the standpipe 16 and diluted by the addition of liquor from a liquor source 18 of white water or other suitable liquor. The slurry in the standpipe is diluted to a medium consistency of 5% to 14%, preferably 5% to 12%, and most preferably 6% to 10%.
The standpipe 16 fluidizes the medium consistency pulp discharged from the standpipe. Fluidization ensures that the pulp and liquid are well mixed at the discharge 14 of the standpipe. Without suitable fluidization, the pulp may separate from the liquor in the standpipe, and settle at the bottom and sides of the standpipe.
The pulp in the bottom of the standpipe may be fluidized with a conditioner 20, such as a rotating vertical screw, positioned at the bottom of the standpipe and turned by a motor 22. The conditioner 20 avoids excessive compaction of the fibrous pulp material in the bottom of the standpipe. The pressure of the pulp suspension in the standpipe creates a pressure head on the medium consistency pulp being discharged 14 from the standpipe.
A vacuum pump 21 degasses the pulp suspension in the standpipe, such that air 30 is removed from the pulp suspension through the inside of the conditioner 20 which is in contact with the pulp. Air removal promotes operation of the MC pump 24 in a stable condition at the desired pulp throughput. Air 30 may be removed from the pulp at other locations in the path 26 of the pulp suspension prior to the inlet to a medium consistency (MC) pump 24.
The medium consistency (MC) pump 24 may be a centrifugal pump having a sturdy shaft and multiple vane impeller. The MC pump 24 moves the medium consistency pulp from the stand pipe 16 to the medium consistency refiner 28. MC pumps are conventional, and tend to have a much heavier duty construction than do centrifugal-type pumps used for low consistency suspensions. MC pumps requires a larger motor, than the motors required to pump LC pulp suspension, due to the thick pulp suspension flowing from the standpipe.
The medium consistency, degassed pulp is pumped to the inlet of the MC refiner 28. An adjustable valve 27 regulates the rate of pulp suspension flowing through conduit 26 to the medium consistency (MC) refiner 28. The MC refiner 28 includes opposing discs defining between them a refining gap. The refiner may have a single rotating disc with a single refining zone or two or more rotating discs with multiple refining zones. The refined pulp discharged from the MC refiner 28 may flow to additional MC refiners, to a storage tank or to further conventional pulp processes 32, such as screening, cleaning or bleaching.
The MC refining 40 produced a steady increase in tensile index (pulp bonding strength) whereas the tensile index of the low consistency refiner series 44 dropped off dramatically when refined below a freeness of 40 mL. These results suggest that after several passes of refining at low consistency the pulp suspension is too fine to maintain a stable plate gap, resulting in excessive fiber cutting and loss in pulp strength. The medium consistency process 40 attained a comparable tensile index to the pulp produced by the high consistency process at lower freeness levels. These results demonstrated that medium consistency refining in a pump-through refiner can achieve bonding strength levels similar to that of more energy-intensive high consistency refined (HCR) pulps.
Both the MC refining 58 and LC refining 60 produced a steady increase in tensile index. The MCR process 58 attained a higher tensile index across all levels of freeness as compared to the LCR process 60. These results suggest that medium consistency refining better develops the chemically treated hardwood fibers. It is postulated that the higher mass of fibers between the plates during MC refining results in more fiber to fiber development whereas LC refining has relatively more shearing actions.
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.
This application claims the benefit of U.S. Provisional Patent Application 61/035,853, filed Mar. 12, 2008, the entirety of which is incorporated by reference.
Number | Date | Country | |
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61035853 | Mar 2008 | US |