The present invention pertains to processes for pulping cellulosic materials, e.g., wood, bagasse and straw pulping.
In the manufacture of pulp from cellulosic materials for making paper, cardboard and related products the cellulosic fibers must be liberated from the cellulosic materials using liquid chemicals. The suspended solids of cellulosic fibers subsequently must be liberated and collected from the liquors.
The most common pulping processes employ cooking or digesting a cellulosic material, e.g. wood chips, to separate the cellulosic fibers from lignin and other materials in the wood chips. Side reactions of the pulping process produce high molecular weight organic by-products which include compounds of lignin, tar, pitch, saponified fatty acids and resins and other chemicals released from the wood chips.
During digesting processes, which can utilize a material, such as sulfate, caustic, sulfite, or alcohols, which is introduced into the digester along with the source of cellulosic fiber, with the digester raised to an elevated temperature and under pressure, the cellulosic fibers are released from the host material. Along with the fibers the high molecular weight organic by-products are released and become soluble in the liquid or pulping liquor. The high molecular weight organic by-products become dissolved or colloidal solids.
At the present time two commercial chemical processes are used to produce the cellulosic fiber material, i.e., Kraft or Sulfate Cooking and Acid or Sulfite Cooking. Another process that is the subject of promising laboratory work is Alcohol based Cooking (ASAM).
During and after the fiber producing material is cooked or digested and the fibers are released, the fibers are separated from the rest of the material and some or all of the spent cooking liquor can be used for further cooking of cellulosic material through circulating and recirculating the liquor. Dissolved solids in the spent liquor interfere in the initial cooking step or subsequent cooking steps. After the cooking process, the fiber is washed to remove residual cooking liquor and side reaction compounds. Further delignification can be obtained using oxygen and caustic which is commercially referred to as oxygen delignification within the washing sequence.
During the cleaning or washing processes during the manufacture of unbleached or bleached fibers, spent filtrate containing high molecular weight organic by-products can interfere with the physical and chemical processes needed to efficiently clean the fibers for the paper product. For example, a typical process of washing the fibers uses a cascading arrangement for the washing filtrate. Relatively clean water is introduced at the final washing stage and is cascaded back through several washing devices downstream to the first washing device. The washing equipment extracts the high molecular weight molecules which are carried on the fibers. The contaminated pulp, after washing yields a dirty filtrate which is sent to a preceding step in the washing process. Eventually, the high weight molecular organic by-products in the dirty filtrate interferes with efficient washing of the pulp. Also, residual high molecular weight material not removed from the fiber material interferes with a subsequent bleaching process.
Thus removal of the high weight molecular organic by-products will increase the efficiency of the cooking, washing, and bleaching processes involved in the production of pulp.
The present invention is a method for improving the overall process efficiency of a sulfite, Kraft or alcohol pulping process by removing dissolved high molecular weight organic by-products from any liquor or filtrate stream withdrawn from any process step by passing the liquor or filtrate stream through a filtration media that will trap the high molecular weight organic by-products and, returning the liquor or filtrate to any suitable point in the cooking, washing or bleaching process.
The liquor or filtrate freed of all or a portion of high molecular weight organic by-products will reduce the chemical or physical interference in a suitable process step that normally utilize the spent liquor or filtrate and thus increase the overall efficiency of the pulping process.
Thus in one aspect, the present invention is a method for improving the efficiency of the batch digesting step of a wood fiber pulping process comprising steps of; separating at least a portion of the liquor from wood pulp during or after the digesting step and passing the liquor through a filtration media to remove dissolved high molecular weight organic by-products from the liquor, and returning the liquor after removal of the high molecular weight organic by-products to any digester.
In another aspect, the present invention is a method for improving the overall efficiency of the batch digesting step in a Kraft pulping process comprising the steps of taking black liquor separated from wood pulp during or after the digesting step and passing the black liquor through a filtration media to remove dissolved high molecular weight organic by-products from the liquor, and returning the black liquor after removal of the high molecular weight organic by-products to a digester.
In still another aspect, the present invention is a method for improving the overall efficiency of the batch digesting steps of a sulfite pulping process comprising the steps of taking liquor separated from wood pulp during or after the digesting step and passing the liquor through a filtration media to remove dissolved high molecular weight organic by-products from the liquor, and returning the liquor after removal of the high molecular weight organic by-products to a digester.
In a further aspect, the present invention is a method for improving the efficiency of a wood pulping process using a continuous digester comprising a step of incorporating into a liquor recirculating or circulating system associated with the continuous digester a filtration media to remove high molecular weight organic by-products from the recirculating or circulating liquor.
A still further aspect the present invention is a method for improving the efficiency of a wood pulping process incorporating storage of spent liquor comprising the step of passing the liquor entering the storage facility to a filtration step to remove dissolved high molecular weight organic by-products from the liquor.
In still another aspect, the present invention is a method for improving the efficiency of a wood pulping process incorporating storage of one of spent liquor or filtrate, comprising the step of either prior to or upon withdrawing the liquor or filtrate from the storage facility passing the liquor or filtrate through a filtration media to remove dissolved high molecular weight organic by-products from the liquor or filtrate.
In yet a further aspect, the present invention is a method for improving the efficiency of a wood pulping process incorporating accumulation of hot liquor in pressurized vessels comprising the step of either prior to or upon withdrawing the liquor from the accumulation facility passing the liquor through a filtration media to remove dissolved high molecular weight organic by-products from the liquor.
Another aspect of the present invention is a method for improving the efficiency of a wood pulping process incorporating recycle of one of liquor or filtrate in the wood pulping process, comprising the step of passing liquor or filtrate from any process step through a filtration media to remove colloidal or dissolved high molecular weight organic by-products from the liquor or filtrate and recycling the liquor or filtrate to any appropriate step in the wood pulping process.
A further aspect of the present invention is a method for improving the efficiency of a wood pulping process including fiber washing comprising the steps of; passing collected washing liquid through a filtration media to remove colloidal and/or dissolved high molecular weight organic by-products from the washing liquid to produce a cleaned washing liquid, and using the cleaned washing liquid as a washing liquid or for pulp dilution.
A still further aspect of the present invention is a method for improving the efficiency of a wood pulping process that includes oxygen as a delignification step preceded by and followed by washing of pulp, comprising the steps of; separating washing fluid from the pulp after one of any washing step preceding or any washing step following the oxygen delignification step, passing the separated washing fluid from the pulp through a filtration media to remove colloidal and/or dissolved high molecular weight organic by-products from the washing fluid, to produce a cleaned washing fluid and using the cleaned washing fluid in any washing operation or to dilute the pulp prior to, after or during oxygen delignification.
The entire disclosure of U.S. patent application Ser. No. 09/917,337 filed is expressly incorporated by reference herein.
In describing the present invention it should be noted that at the present time there are two commercially practiced chemical cooking (digesting) processes to which the invention is particularly applicable. These are the Kraft pulping process where sulfate cooking or digesting is used and the acid process wherein sulfite cooking or digesting is used. Another process that is not commercial at this time but which has shown promising results in the laboratory involves pulping using an alcohol cooking step.
For the existing processes there are two types of reactors currently in use. There are batch reactors and continuous reactors. The batch reactor employs two different cooking methods, conventional batch and displacement batch.
In pulping processes there are two types of storage devices that are used to store liquor or filtrate during the processing of the pulp. These are atmospheric tanks and pressurized accumulators.
In the Kraft or sulfate cooking process the liquor withdrawn from the digester is referred to as “black liquor” while the liquor withdrawn from the acid (sulfite) cooking step is referred to as hydrolysate. Therefore, in describing and claiming the present invention the term liquor is used to encompass both sulfate cooking and sulfite cooking. This would also cover alcohol cooking since the alcohol cooking step results in a liquor from which the fibers are separated.
Referring to
Referring to
In pulping process 130 clean water, represented by box 154, is added to the end most washer 152 in the series of pulp washers associated with the washing and oxygen delignification sections of the plant. The filtrate from tank 172 can be recycled to washer 150 in the series as shown by line 192. As shown in
It is within the scope of the present invention to take the streams in various conduits and subject them to a filtration media to remove colloidal or dissolved high molecular weight organic by-products from the stream. For example, referring to
Referring to
Dilution according to the present invention is effected by taking a process filtrate from any area of the pulping process train via line 206 and passing the filtrate through a filter media filtration step 208 to remove, or lower the concentration of, high molecular weight organic by-products in the filtrate. Filtrate leaving the filtration step 208 is conducted via line or conduit 210 and branch conduits 212, 214 and 216 to one of, or all of, the pulp in conduit 202, pulp in the reactor 200 or pulp in conduit 204 to effect dilution in accord with the requirements of the overall process.
Cleaning and screening can take place anywhere in the pulping process where logic, good science or good engineering would dictate.
The foregoing figures and related description are merely illustrative of the present invention. In its broadest terms the use of a separation step to remove dissolved or colloidal or dissolved high molecular weight organic by-products can be applied anywhere in the pulp manufacturing plant (including washing and bleaching of the pulp) to improve overall physical or chemical process efficiency.
For example in the digesting area of a pulp mill, removal of the dissolved high molecular weight organic by-products produced from the cooking reactions will allow for less interference and higher concentration gradients in subsequent cooking reactions needed to produce or liberate fibers from the cellulosic material. Additionally, the cooking chemicals will not be depleted by unwanted reactions that occur between high molecular weight organic solids when the liquor has been treated according to the present invention. Thus, the concentration of cooking chemicals can be reduced for the same amount of cellulosic material produced because side reactions with high molecular weight organic materials do not occur. Lastly, a decrease in the concentration of cooking chemicals required to produce the pulp will also reduce damaging reactions to the cellulosic materials that occur with higher concentrations of cooking chemicals.
In the washing operations dissolved high molecular weight organic by-products in the counter current shower flow can be reduced which increases the concentration gradients for mass transfer and therefore increases the washing efficiency. An increase in washing efficiency would decrease the demand for fresh or clean water in a given plant, which is also referred to as a decrease in dilution factor. The dilution factor is the excess water that must be evaporated. This would decrease the energy requirements of the evaporation plant because less liquid would be evaporated.
Extended delignification of cellulosic material after the cooking plant can be obtained with the use of oxygen. The demand for oxygen and other chemicals required for oxygen delignification would decrease, because, the unwanted reactions with the high molecular weight organic by-products would be decreased. A lower concentration of oxygen and other chemicals would decrease the destructive effects on the cellulosic material.
The benefits of the present invention would be immediate upon removal of a minimum of 10% by weight (based on inlet flow) of the dissolved or colloidal high molecular weight organic by-products from any stream being treated according to the invention.
Furthermore, removal of high molecular weight organic by-products would benefit in the physical activities that are required to occur in cooking processes. For example, better diffusion of the cooking chemicals into the wood would ultimately result in a lower concentration of active chemical required, which would decrease destructive side reactions to the fiber itself. This in turn would produce a higher yield of the desired product and lower operating costs due to lower concentration of the active chemical applied to the wood. Lastly, better diffusion would decrease the amount of uncooked or partially cooked wood, i.e., waste.
Removal of large agglomerated colloidal molecules, such a pitch, would decrease the re-deposition of the colloidal molecules on the pulp, thereby increasing the cleaning efficiency of the washing or extraction device. This would decrease the demand for bleaching chemicals in subsequent bleaching steps. Also, the amount of clean water necessary for the washing plant may be decreased, if the possibility of re-deposition is decreased.
It is believed that immediate monetary benefit to the pulp producer would come from filtering the filtrate used in the washing area of the pulping process. Specifically, the filtrate used for dilution and washing surrounding an oxygen delignification reactor which is in the Brown Stock washing area (after cooking, but before bleaching) would be a prime target for the process of the present invention. Using the process of the present invention in the cooking area of a pulp mill would be effected after application to the washing area of the plant.
As used in the foregoing specification and the appended claims the term dissolved high molecular weight organic by-products is taken to mean any and all of dissolved organic solids, colloidal or dissolved organic solids and colloidal or dissolved high molecular weight organic by-products.
It would be readily apparent to those skilled in the art that the present invention would find application in any cellulosic pulping mill or process. The order and number of unit operation for one pulp mill may be different then those for another mill. Therefore the description of the present invention includes application to all pulp mills regardless of equipment layout or operating process.
Research into pulping processes is an on going effort. Newer chemical pulping processes have been developed and are being demonstrated in the laboratory, e.g. using potassium hydroxide (KOH) and nitrogen compounds such as ammonia. These newer process will also benefit from the methods of the present invention
Having thus described my invention what is desired to be secured by Letter Patent of the United States is set forth in the appended claims which should be read without limitation.
This application is a divisional of U.S. application Ser. No. 09/917,337 filed Jul. 27, 2001, now U.S. Pat. No. 6,752,903.
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Number | Date | Country | |
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20040099386 A1 | May 2004 | US |
Number | Date | Country | |
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Parent | 09917337 | Jul 2001 | US |
Child | 10718395 | US |