The present invention relates to digestion of wood chips in a digester employing alkaline liquor for the production of paper pulp.
In the papermaking industry, wood logs are converted into chips, which are subsequently treated in a digester system to separate the cellulose fibers and to remove desired amounts of lignin, etc., which binds the fibers together in the natural state of wood, for the production of paper pulp.
Digestion of wood chips employing an alkaline liquor is a common practice in the industry. In this process, commonly wood chips and an alkaline digesting liquor, sometimes premixed, are introduced to a top inlet zone of a continuous digestion vessel (a digester). In the digestion process, the chips and liquor move generally, but not always, together downward through the digester, the digestion reaching generally optimal completion when the mass reaches the bottom portion of the digester. A typical digester is divided into various zones such as the inlet zone, an upper digestion zone within which, among other things, the chip/liquor mass is heated toward a full cook temperature, a full cook zone within which the mass is subjected to a full cook temperature for a selected period of time, an extraction zone within which digestion spent liquor (black liquor at this point) is withdrawn from the digester, a wash zone in which the mass is washed with process liquids to wash the dissolved solids in the black liquor from the mass, and a withdrawal zone in which the mass of (partially) washed pulp is withdrawn from the digester and passed to further treatment apparatus, such as pulp washers.
Scaling occurs on surfaces of the equipment in an alkaline pulping system and results in loss in productivity and higher operating costs. Severe scaling in a continuous digester system often leads to loss of production of up to several days a year for scale removal by acid cleaning or high-pressure hydro blasting. Currently there are no known cost-effective process modifications to prevent scaling from forming, and many mills rely on the use of a class of expensive chemicals, known as “antiscalants” in the art, as pulping additives to suppress scaling. Even with the antiscalants, costly periodic cleaning of heaters or other digester equipment is often required.
Calcium carbonate has been shown to be a key component of scale formed on surfaces of alkaline pulping equipment such as digester cooking heaters and digester screens. In addition, wood generally is the single largest source of calcium present in cooking liquor. The solubility of calcium salts in alkaline pulping liquor has been found first increases and then decreases with increasing cooking temperature and/or cooking time. When the amount of calcium in the cooking liquor exceeds its solubility, calcium precipitates as calcium carbonate and, along with lignin and other deposits, forms scale on the surface of heater, screens and digester shell wall. Thus, under typical alkaline pulping conditions, the amount of dissolved calcium in the cooking liquor increases as cooking proceeds, goes through a maximum near when the maximum cooking temperature is reached, and decreases rapidly afterward as a result of calcium carbonate precipitation onto equipment surfaces (scaling) and surfaces of chips/fibers.
Scaling tendency of calcium in cooking liquor has been shown to decrease dramatically after the liquor has been heated at or near typical full cooking temperatures. This action is, at times, referred to in the art as calcium deactivation by heat treatment, and has been practiced in some digesters. An exemplary application of this calcium deactivation, as described in European Patent Application EP 0313730 A1, comprises of heating cooking liquor high in calcium at or near full cooking temperature, holding it at this temperature in a vessel for a period of time, typically longer than ten minutes, and returning the heat treated liquor, with “deactivated” calcium, to the digester system. Because scale forms on the surfaces of this “sacrificial” vessel, generally at least two vessels are needed in order to maintain continuous operation of calcium deactivation, with at least one vessel being online and one vessel being cleaned of scales. This technology is probably effective, but requires addition capital and operating costs, and therefore is not widely practiced in the industry.
Cleaning accumulated scale from a digester requires taking the digester offline and removal of the scale, commonly by chemical dissolution of the scale and/or pressure cleaning with a liquid. This cleaning consumes several days of downtime of the digester in addition to the labor required to perform the cleaning, both of which are very costly. As a consequence of such cost, cleaning of digesters is commonly conducted no more frequently than annually. The gradual accumulation of scale within the digester over the period of a year results in ever increasing loss of efficiency as more and more scale develops. It is therefore most desirable that a method be provided for reducing or substantially eliminating the accumulation of scale within a digester.
One aspect of the present invention relates to an apparatus for continuous digestion of wood chip comprising an upright generally cylindrical vessel having a top end and a bottom end. The top end of the cylindrical vessel is adapted to receive wood chips mixed with a cooking liquor to be treated therein. A first conduit is integrally attached at a first location positioned between the top and bottom ends of the vessel for selectively extracting a first quantity of cooking liquor from the vessel. The first location is positioned upstream of a second location within the vessel where the cooking liquor being at substantially full cooking temperature. A second conduit is integrally attached at a third location positioned downstream from the first and second locations of the vessel. The second conduit is in fluid communication with a fourth location positioned at, about below or upstream from the first location for selectively extracting a second quantity of cooking liquor from the vessel at the third location and transporting at least a portion of the extracted second quantity of cooking liquor to the fourth location.
Another aspect of this invention relates to an apparatus for continuous digestion of wood chip comprising a vessel having a top end and a bottom end. The top end of the vessel is adapted to receive wood chips to be treated therein. A first conduit is integrally attached at a first location positioned between the top and bottom ends of the digester for selectively extracting a first quantity of cooking liquor from the vessel. The first location is positioned upstream of a second location within the vessel where the cooking liquor being at substantially full cooking temperature. A second conduit is integrally attached at a third location positioned downstream from the first and second locations of the vessel. The second conduit is in fluid communication with a fourth location positioned at, about below or upstream from the first location for selectively extracting a second quantity of cooking liquor from the vessel at the third location and transporting at least a portion of the extracted second quantity of cooking liquor to the fourth location. A third conduit is integrally attached to a fifth location positioned outside of the vessel. The third conduit is in fluid communication with the fourth location positioned at, about below or upstream from the first location for selectively extracting a second quantity of cooking liquor from the vessel.
Yet another embodiment of this invention relates to an apparatus for continuous digestion of wood chip which comprising an upright generally first cylindrical vessel having a top end and a bottom end. The top end of the first cylindrical vessel is adapted to receive wood chips mixed with a cooking liquor to be treated therein. An upright generally second cylindrical vessel is configured to be in fluid communication with the first cylindrical vessel. The second vessel having a top end and a bottom end, the top end of the second cylindrical vessel is adapted to receive the treated wood chips from the first vessel. A first conduit is integrally attached at a first location positioned between the top and bottom ends of the second cylindrical vessel for selectively extracting a first quantity of cooking liquor from the second cylindrical vessel. The first location is positioned upstream of a second location within the second cylindrical vessel where the cooking liquor being at substantially full cooking temperature. A second conduit is integrally attached at a third location positioned downstream from the first and second locations of the second cylindrical vessel. The second conduit is in fluid communication with a fourth location positioned at, about below or upstream from the first location for selectively extracting a second quantity of cooking liquor from the second cylindrical vessel at the third location and transporting at least a portion of the extracted second quantity of cooking liquor to the fourth location.
One or more advantages flow from the present invention. One advantage is reduced calcium carbonate scaling. The apparatus and process modifications disclosed in the present invention can be tailored to a digester system such that net reduction in pulping energy requirement, in the form of medium or high pressure steam consumption, can be realized for more cost savings. Furthermore, when the content of dissolved solids in the process stream(s) added to the early stages of a cook that is lower than in the liquor removed from the cooking system, washing of the cooked chips is generally improved, and a smaller amount of weak black liquid can be used in pulp washing. As a result, a smaller amount of washing liquor used, a higher total solid is sent to evaporators and additional savings are realized from a lower steam demand in the weak black liquor evaporation. In addition, removal of calcium and other non-process elements, as well as certain extractives, from the early stages of a cook has been found to improve pulp brightness and bleachability. Thus the present invention also results in still more savings from a lower pulp bleaching cost as an additional benefit.
With reference to
At the bottom of the vessel, the removed pulp stream is sent to a first pulp washer (not shown) via 24, and the washing filtrate 42 from the first pulp washer is often cooled in cooler 40, “cold blow filtrate” 26 as commonly known in the art, and introduced to the bottom of the digester for cooling and washing the cooked chips above the blow assembly 22. This filtrate is available for recirculation to the vessel, either with or without cooling, and with or without further treatment before or after having been mixed with a stream of white liquor (WL) 44 and/or black liquor extracted from the upper and/or lower extraction locations on the digester, and reintroduced into the vessel, such as at the top end of the vessel. In
With reference to
The depicted digester 50 includes an upright generally cylindrical second vessel having a top end 54 where there is received a supply of wood chips and alkaline cooking liquor 56 and a bottom end 58 which includes a blow assembly 60 by means of which a stream 62 of cooked chips and spent cooking liquor (pulp) is removed from the vessel, such stream being sent to a pulp washer 9 not shown). The washing filtrate from the pulp washer 64, also known as cold blow filtrate in the art, may be cooled and sent to the bottom of the second vessel for cooling and washing the cooked chips above the blow assembly 60. This cold blow filtrate is also available for recirculation to the first vessel 80, either without further treatment or after having been mixed with a stream of white liquor 92 and conveyed into the first vessel. In the depicted embodiment of
The preferred embodiment of the method of the present invention was employed with the digester depicted in
In a further example of the preferred embodiment of the method of the present invention, employing a single vessel digester as depicted in
In a still further example employing the preferred embodiment of the method of the present invention, in a single vessel digester as depicted in
The present method is operable with both hardwood pulp and softwood pulp.
Table I presents typical ranges of calcium concentrations in the cooking liquor in various locations in a digester as shown in
Employing these calcium concentration ranges, one skilled in the art may readily determine the optimal locations at which cooking liquor may be extracted from the digester and where makeup liquor of lesser calcium concentration should be introduced to the digester.
Inasmuch as the dissolved calcium concentration in cooking liquor may vary as a function of the initial carbonate ion concentration, a significant amount of the cooking liquor should be withdrawn around the process point where the dissolved calcium concentration peaks. At what cooking temperature (corresponding to a certain digester location) the dissolved calcium concentration peaks depends on the carbonate concentration in the liquor. The higher the initial carbonate concentration in the liquor, the earlier the dissolved calcium concentration peaks within the digester.
Logistically, the preferred location in the digester for replacing cooking liquor high in dissolved calcium with a liquor low in dissolved calcium is the first set of cooking circulation screens in a single-vessel continuous digester. Similarly the most suitable location to replace the extracted calcium-rich liquor with a liquor low in dissolved calcium is the chip transfer line (bottom circulation as known in the art) leading into the digester (the second vessel in
Alternatively, (1) one may extract a sufficient amount of one of the process streams from a process point in a continuous digester that is located at least several minutes after full cooking temperature is reached, adding this process stream to an early stage of the cook, e.g. the feeding system or the bottom circulation, and extract an optimal amount of cooking liquor downstream of the addition point and upstream of the process point where full cooking temperature is reached Further, same as Item (1) above, except that the temperature of the added process stream may be controlled by use of a heat exchanger, such that a desire pulping temperature profile is maintained.
Still further, same as Item (1) above, except that more than one process stream may be extracted from different process points after full cooking temperature is reached and that the temperature of one or more of the streams may be controlled by the use of one or more heat exchangers.
Another significant benefit, namely an increased maximum sustainable pulp production, is achieved from another preferred embodiment of the present invention. According to this embodiment, the upper extraction flow rate described in Examples I-III above (also depicted in
Other variations in the method of the present invention will be recognized by one skilled in the art and the invention is to be limited only as set forth in the claims appended hereto.
This application is a divisional of application Ser. No. 10/877,529 filed on Jun. 26, 2004.
Number | Date | Country | |
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Parent | 10877529 | Jun 2004 | US |
Child | 11809692 | Jun 2007 | US |