EP0032044A1 - Forming dry laid webs - Google Patents

Forming dry laid webs Download PDF

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Publication number
EP0032044A1
EP0032044A1 EP80304688A EP80304688A EP0032044A1 EP 0032044 A1 EP0032044 A1 EP 0032044A1 EP 80304688 A EP80304688 A EP 80304688A EP 80304688 A EP80304688 A EP 80304688A EP 0032044 A1 EP0032044 A1 EP 0032044A1
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EP
European Patent Office
Prior art keywords
forming
air
fibre
fibres
web
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Granted
Application number
EP80304688A
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German (de)
French (fr)
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EP0032044B1 (en
Inventor
Raymond Chung
James H. Dinius
David W. Appel
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Kimberly Clark Corp
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Kimberly Clark Corp
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Publication of EP0032044A1 publication Critical patent/EP0032044A1/en
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    • DTEXTILES; PAPER
    • D01NATURAL OR MAN-MADE THREADS OR FIBRES; SPINNING
    • D01GPRELIMINARY TREATMENT OF FIBRES, e.g. FOR SPINNING
    • D01G99/00Subject matter not provided for in other groups of this subclass
    • DTEXTILES; PAPER
    • D01NATURAL OR MAN-MADE THREADS OR FIBRES; SPINNING
    • D01GPRELIMINARY TREATMENT OF FIBRES, e.g. FOR SPINNING
    • D01G25/00Lap-forming devices not integral with machines specified above

Definitions

  • the present invention relates to a method and apparatus for forming non-woven fabrics and to the products produced thereby suitable for bath tissue or the like to heavier webs suitable for facial tissues, components for feminine napkins, diaper fillers, toweling, wipes, non-woven fabrics, saturating paper, paper webs, paperboard, et cetera.
  • materials suitable for use as disposable tissue and towel products have been formed on paper-making equipment by water-laying a wood pulp fibrous sheet. Following formation of the sheet, the water is removed either by drying or by a combination of pressing and drying. As water is removed during formation, surface tension forces of very great magnitude develop which press the fibers into contact with one another resulting in overall hydrogen bonding at substantially all fiber intersections; and a thin, essentially planar sheet is formed. It is the hydrogen bonds between fibers which provide sheet strength and, such bonds are produced even in the absence of extensive additional pressing. Due to this overall bonding phenomenon, cellulosic sheets prepared by water-laid methods inherently possess very unfavorable tactile properties (e.g . , harshness, stiffness, low bulk, and poor overall softness) and, additionally, possess poor absorbency characteristics rendering such sheets generally unsuitable for use as sanitary wipes, bath and facial tissues, and toweling.
  • very unfavorable tactile properties e.g . , harshness, stiffness, low bulk, and poor overall softness
  • water-laid sheets are typically creped from the dryer roll with a doctor blade. C reping reforms the flat sheet into a corrugated-like structure thereby increasing its bulk and simultaneously breaking a signif cant portion of the fiber bonds, thus artifically improving the tactile.and absorbency properties of the material.
  • creping raises several problems. Conventional creping is only effective on low basis weight webs (e.g., webs having basis weights less than about 15 lbs./2880 ft. 2 ), and higher basis weight webs, after creping, remain quite stiff and are generally unsatisfacto for uses such as quality facial tissues.
  • Air forming of wood pulp fibrous webs has been carried out for many years; however, the resulting webs have been used for applications where either little strength is required, such as for absorbent products--i.e., pads--or applications where a certain minimum strength is required but the tactile and absorbency properties are unimportant--i.e., various specialty papers
  • a system was proposed employing rotor blades mounted within a cylindrical fiber "disintegrating and dispersing chamber" wherein air-suspended fibers were fed to the chamber and discharged from the chamber through a screen on to a forming wire.
  • a second type of system for forming air-laid webs of dry cellulosic fibers which has found limited commercial use has been developed.
  • this system employs a fiber sifting chamber or head having a planar sifting screen which is mounted over a forming wire. Fibers are fed into the sifting chamber where they are mechanically agitated by means of a plurality of mechanically driven rotors mounted for rotation about vertical axes. Each rotor has an array of symmetrical blades which rotate in close proximity to the surface of the sifting screen.
  • the system generally employs two, three or more side-by-side rotors mounted in suitable forming head.
  • the forming head is to be cleared of agglomerated material, it is necessary to remove 10% or more by weight of the incoming material from the forming head for subsequent reprocessing or for use.in less critical end products.
  • the separating method used entrains a large number of good fibres with the agglomerates leaving the forming head.
  • the severe mechanical action of the hammermills in the secondary processing system damages and shortens such otherwise good fibres, while breaking up the agglomerates.
  • Another inherent shortcoming of these systems is a tendency to form webs having a non-uniform weight profile across their width. This is a condition which is very difficult to overcome. It is especially troublesome when making webs in the towelling and lightweight tissue ranges.
  • air- forming techniques can be advantageously used in high speed production operations to prepare cellulosic sheet material that is sufficiently thin, and yet has adequate strength, together with softness and absorbency, to serve in applications such as bath tissues, facial tissues and light weight toweling.
  • a method of forming an air-laid web of dry fibers in accordance with the present invention comprises a) conveying individual fibers and soft fiber flocs in a high volume air stream through a flow control and screening system wherein provision is made for substantially eliminating cross-flow and eddy current forces so as to maintain cross-directional control of the mass quantum of fibers being conveyed and wherein the fibrous materials are subjected to only minimal mechanical action so as to minimize the formation of undesired pills and nits; b) separating individual fibers and soft fiber flocs from undesired pulp lumps, pills, rice, nits and other undesired aggregated fiber masses with the individualized fibers and soft fiber flocs being permitted to pass through a separator screen into a forming zone while the undesired aggregated fiber masses are withdrawn from the air stream for secondary hammer milling operations and/or scrap or usage in inferior products; and, c) air-laying the dry individual fibers and soft fiber flocs on a relatively moving forming surface in a
  • non dense, rolled up bundle of fibers, often including bonded fibers, having a bulk density greater than .2 grams per cubic centimeter (g./cc.) and which are generally formed by mechanical action during fiber transport or in a rotor chamber where the fibers are commonly, and often intentionally, subjected to mechanical disintegrating action.
  • loc and soft floc are herein used to describe soft, cloud-like accumulations of fibers which behave like individualized fibers in air; i.e., they exhibit relatively high coefficients of drag in air.
  • Basis density is the weight in grams of an uncompressed sample divided by its volume in cubic centimeters.
  • the phrase "2-dimensional" is used to describe a system for forming a web wherein: i) the cross-section of the system and the flows of air and fiber therein are the same at all sections across the width of the system; and ii), where each increment of system width behaves essentially the same as every other increment of.system width; thereby permitting the system to be scaled up or down to produce high quality webs of any suitable and commercially useful widths on a high-speed production basis and wherein a web's cross-directional profile in terms of basis weight can be controlled and, preferably, can be maintained uniform.
  • coefficient of variation is used herein to describe variations in the cross-directional basis weight profile of both the web being formed and the fibrous materials input to the system, and comprises the standard deviation (a) expressed as a percent of the mean.
  • the coefficient of variation should not vary more than 5% and, preferably, should vary less than 3% in the cross-machine direction.
  • the basis weight profile in the cross-machine direction of the web being formed may, for example, be determined by weighing strips of the web which are three inches in width (3" C.D.) by seven inches in length (7" M.D.).
  • rate of fiber delivery is intended to mean the mass quantum or weight rate of feed of fibrous materials delivered to the forming head, and may be expressed, for example, in units of pounds per hour per inch of former width (lbs./hr./in.), pounds per minute per foot of former width (lbs./min./ft.), or in any other suitable units.
  • “Throughput” is intended to describe the-screening rate for fibrous materials discharged from the forming head--i.e., the mass quantum or weight rate of fiber delivery through the former screen per unit area of screen surface--and may be expressed, for examole, in units of pounds per hour per square inch of effective screen surface area (lbs./hr./in. 2 ).
  • FIGURE 1 there has been illustrated an exemplary system for forming an air-laid web 60 of dry fibers, such system here comprising: a fiber metering section, generally indicated at 65; a fiber.transport or educator section, generally indicated at 70; a forming head, generally indicated at 75, where provision is made for controlling air and fiber flow, and where individual fibers are screened from undesirable aggregated fiber masses and, thereafter, are air-laid on a foraminous forming wire 80; a suitable bonding station, generally indicated at 85,.where the web is bonded to provide strength and integrity; a drying station, generally indicated at 87, where the bonded web 60 is dried prior to storage; and, a take-up or .reel-type storage station, generally indicated at 90, where the air-laid web 60 of dry fibers is, after bonding and drying, formed into suitable rolls 95 for storage prior to delivery to some subsequent processsing operation (not show-n) where the web 60 can be formed into specifically desired consumer products.
  • a fiber metering section generally indicated at
  • the forming head 75 includes a separator system, generally indicated at 76, for continuous removal of aggregated fiber masses.
  • a separator system for continuous removal of aggregated fiber masses.
  • Such separated aggregated fiber masses and individualized fibers entrained therewith are preferably removed from the forming area by means of a suitable conduit 77 maintained at a pressure level lower than the pressure within the forming head 75 by means of a suction fan (not shown).
  • the conduit 77 may convey the masses to some other area (not shown) for use in inferior products, for scrap, or, alternatively, the undesirable aggregated fiber masses may be recycled to a hammermill where the masses are subjected to secondary mechanical disintegration prior to reintro--duction into fiber meter-65.
  • the forming head 75 also includes a forming chamber, generally indicated at 79, positioned immediately above the foraminous forming wire 80.
  • a forming chamber generally indicated at 79, positioned immediately above the foraminous forming wire 80.
  • a vacuum box 126 positioned immediately below the forming wire 80 and the web forming section 79 serves to maintain a positive downwardly moving stream of air which assists in collect- i n g the web 60 on the moving wire 80.
  • a second supplementary vacuum box 128 may be provided beneath the forming wire at the point where the web 60 exits from beneath the forming chamber 79, thereby insuring that the web is maintained flat against the forming wire.
  • the web 60 is passed through calendar rolls 129 to lightly compact the web and give it sufficient integrity to permit ease of transportation to conveyor belt 130.
  • a light water spray can be applied from nozzles 131 and 135 in order to counteract static attraction between the web and the wire.
  • An air shower 132 and vacuum box 134 serve to clean loose fibers from the wire 80 and thus prevent fiber build-up.
  • the web 60 may be bonded in any known conventional manner such, merely by way of example, as i ) spraying with adhesives such as latex, ii) overall calendering to make a saturating base paper--i.e., a bulky web with a controlled degree of hydrogen bonding--iii) adhesive print pattern bonding, or other suitable process.
  • adhesives such as latex
  • ii) overall calendering to make a saturating base paper--i.e., a bulky web with a controlled degree of hydrogen bonding--iii) adhesive print pattern bonding, or other suitable process.
  • Such bonding processes do not form part of the present invention and, therefore, are . neither shown nor described in detail herein, but, such processes are well known to those skilled in the art of non-woven fabric manufacture. Bonding of the web as by rolls 136 and 138, and drying at 87, may be necessary prior to forming the roll 95.
  • Multiple forming heads 75 may be provided in series in order to increase overall productivity of the system.
  • FIGURE 2 there has been illustrated a conventional sifting system of the type described in
  • U.S. Pat No. 4,014,635 for forming air-laid webs of dry fibers.
  • a hammermill 141 disintegrates fiber provided through conduit 142, the fiber being thereafter conveyed to distributor 148 for distribution onto moving forming wire 80 through screen 150.
  • a plurality of rotating impellers 151 rotate about vertical axes and "sift" the fiber through screen 150. Material to be recycled is removed through conduit 155a to the hammermill 141.
  • pulp or other fibrous material is subjected to intensive mechanical disintegration in hammermill 141, and the resulting individualized fibers, pills and pulp lumps are then fed into the fiber distributor 148 where they are subjected to severe mechanical agitation by impellers 151.
  • Such mechanical agitation results in stratification of the fibrous materials, with the finer materials said to move downwardly, and the coarser materials rising upwardly where such coarse materials are recycled to hammermill 141 for secondary hammermilling operations.
  • the finer materials include individual fibers, soft fiber flocs and relatively small nits which are mechanically propelled across the surface of and through the perforate bottom wall or screen . 150 by the agitating and sifting action provided by the impellers 151. That material passing through the perforate bottom wall or mesh screen 150 is then deposited on the forming wire 80 by means of gravity and the air stream generated by suction box 126 to form an air-laid web 60' of dry fibers.
  • the foregoing sifting system has proven suitable for forming relatively high basis weight webs--e.g., webs having basis weights on the order of 24 lbs./2880 ft. or greater.
  • extremely high fiber recycle percentages must be maintained when attempting to form webs, particularly when attempting to form relatively light basis weight webs suitable for bath and/or facial tissues.
  • productivity of the fiber distributor is extremely low, and a large percentage of the input fibers are subjected to secondary hammermilling operations which tend to further shorten, curl and otherwise damage the fibers and which require excessive amounts of energy consumption.
  • the rotary sifting action of the impellers 151 tends to roll fibers between the impeller blades and the housing 149 and the screen 150 thus generating a large number of undesired pills which increase the recycle percentage.
  • each distributor lays a very thin layer of fibers on the layer from the preceding distributor.
  • such systems are limited in width and generally have poor cross-directional profiles, poor formation, and low strength due to mechanical damage to the fibers.
  • the flow control and screening arrangement of our apparatus is of the 2-dimensional type employing an elongate rotor housing having a single rotor mounted for rotation about a horizontal axis located above the forming wire 80. Since the process of the present invention is essentially 2-dimensional with no component of flow in the cross-machine direction, it is significantly more manageable and predictable than a sifting type former employing multiple rotors rotating in a horizontal plane about vertical axes, thereby permitting the system to be conveniently and readily scaled up and/or down in-width-to-meet commercial web requirements.
  • feed mat 116 may be formed which meets the preferred conditions of full-width uniformity in terms of the mass quantum of fibers forming the mat and the coefficient of variation of the fibrous materials input to the system.
  • the mat thus formed is then fed into the teeth of lickerin 121 which serves to disaggregate the fibers defining the mat by combing such fibers (along with any pulp lumps, nits and other aggregated fiber masses which are present) out of the mat and feeding such materials directly into a high volume air stream 123.
  • the air-suspended fiber stream is conveyed through a suitable fiber transport duct 170 (FIG. 3) from the full-width eductor 70 to a full-width inlet slot 171 formed in the upper surface of, and extending fully across, a generally cylindrical housing 172 which here defines the 2-dimensional flow control, screening and separating zone 75.
  • a suitable fiber transport duct 170 (FIG. 3) from the full-width eductor 70 to a full-width inlet slot 171 formed in the upper surface of, and extending fully across, a generally cylindrical housing 172 which here defines the 2-dimensional flow control, screening and separating zone 75.
  • the exemplary duct 170 is preferably subdivided into a plurality of side-by-side flow channels separated by partitions 174 extending the full length of the duct.
  • the desired coefficient of variation constraint in the web being formed can be obtained by spacing the partitions 174 apart by approximately four inches so as to form a plurality of adjacent flow channels extending across the full axial length of housing 172. It has also been found that a partitioned duct arrangement of the type shown in FIG. 3 can be advantageously used to accommodate width differences between the feed mat 116 formed in the fiber metering section 65 and the final air-laid web 60 deposited on'the foraminous forming wire 80. For example, excellent results have been obtained when attempting to form a web 60 forty-eight inches in width, utilizing a feed mat 116 only forty inches in width.
  • air-suspended fibrous materials introduced radially into housing 172 through inlet slot 171 are conveyed by co-action of the air stream and the rotor assembly 175 through the housing 172 for controlled and selective discharge either a) through a full-width discharge opening, generally, indicated at 178 in FIG. 3, and into forming zone 79 for ultimate, air-laid deposition on forming wire 80 or, alternatively, b) through a full-width tangential separator slot 179 formed in housing 172 downstream of the discharge opening 178.
  • the separator slot 179 which here forms part of the separation and/or recycle zone 76 (FIGS.
  • 1 and 3 is preferably on the order of from 3/16" to 3/8" in circumferential width when working with wood fibers and, if desired, may be adjustable in any conventional manner (not shown) so as to permit circumferential widening or narrowing of the slot 179 to' optimize separation conditions.
  • screening means 180 To permit controlled, selective discharge of individualized fibers and soft fiber flocs through opening 178 and into forming zone 79, while at the same time precluding discharge of nits and other undesired aggregated fiber masses therethrough, suitable screening means, generally indicated at 180 in FIG. 3, is mounted within discharge opening 178.
  • Such screening means 180 may simply take the form of a conventional woven square-mesh wire screen of the type shown at 180A in FIG. 4 and having openings sized to preclude passage of aggregated fiber masses provided that the screen openings do not exceed 0.1" open space from wire-to-wire in at least one direction and have between 38% and 46% open area.
  • screening means 180 is formed with the same radius of curvature as the semi-cylindrical portion of housing 172 within which discharge opening 178 is formed.
  • rotor assembly 175 comprises a plurality of transversely extending rotor bars 181, each fixedly mounted on the outer periphery of a plurality of closely spaced spiders 182.
  • the bars 181 move through the radially entering stream of air-suspended fibers entering at inlet slot 171.
  • the air and fibers tend to move outwardly towards the wall of housing 172, thus best illustrated at 186 in FIG. 6.
  • Such annular aerated bed 186 of fibrous material is believed to be on the order of one-half inch to one and one-half inches thick (dependent upon actual operating parameters), and is believed to be moving rotationally at about half the speed of the rotor bars 181.
  • the rotor assembly 175 is preferably designed a) to minimize pumping action which tends to reduce the relative speed differential between the rotor bars 181 and the aerated bed 186, thus causing the fibers to move over and beyond the screening means 180, and b) so as to minimize mechanical action between the rotor bars 181 and both the housing 172 and screening means 180, which action tends to disintegrate fibers and aggregated fiber masses carried in the air stream and to general pills.
  • the rotor bars 181 are on the order of 3/4" in radial height by 3/8" in thickness, and are mounted so as to provide a clearance between the outer edges of the bars 181 and the inner wall surface of the housing 172 and screening means 180 of from 0.10 inches to 0.25 inches and, preferably, from 0.18 inches to 0.20 inches. To avoid generation of cross-flow forces, it is important that the rotor bars 181 are contznuous, extend the-full width of the rotor chamber, and are oriented parallel to the axis of the rotor assembly 175.
  • the aerated bed--which contains individualized fibers, soft fiber flocs, nits and other aggregated fiber masses--passes over the screening means 180 some, but not all, of the individualized fibers and soft fiber flocs pass through the screening means into the forming zone 79, while the balance of the individualized fibers and soft fiber flocs, together with nits and other aggregated fiber masses, pass over the screen without exiting from the rotor housing 172.
  • Separation of undesired nits and aggregated fiber masses from individualized fibers and soft fiber flocs is accomplished with a full-width classifying air jet 194, provided upstream of the separator slot 179 and downstream of screening means 180; such air jet being positioned to introduce a full-width air stream generated by any conventional source (not shown) radially into rotor housing 172 just ahead of the separator slot 179.
  • the positive classifying air stream introduced radially into housing 172 through air jet 194 tends to divert individualized fibers and soft fiber flocs within the aerated bed 186 radially inward as a result of the relatively high drag coefficients of such materials and their relatively low bulk density (which is-.generally on the order of less than .2 g./cc.). Since the nits and aggregated fiber masses have a relatively high bulk density in excess of .2 g./cc.
  • the classifying air stream introduced through the full-width air jet 194 does not divert such materials to any significant extent and, therefore, such undesired materials tend to be cetrifuagally expelled through the tangential separator slot 179. It has been found that the introduction of classifying air through the full-width classifying air jev 194 into housing 172 at pressures on the order of from 30" to 100" H20 and at volumes ranging from 1.5 to 2.5 ft.3/min./in. is adequate for deflecting a significant portion of the individualized fibers and soft fiber flocs. The energy level of the classifying air jet is most conveniently controlled by adjusting its pressure.
  • the present invention has thus far been described in connection with the use of a conventional woven square-mesh screen 180A (FIGURE 4) for the screening means 180 shown diagrammatically in FIGURE 3, it is preferred that the screening means 18.0 take the form of a high capacity slotted screen 1808--e.g., of the type shown in FIGURE 5.
  • the screen slots be oriented with their long dimensions parallel to the axis of the rotor assembly.
  • the exemplary system herein described has eight rotor bars 181.
  • the number and/or shape of the rotor bars may be varied, provided that such modifications are consistent with mechanical stability and low rotor "pumping" action. That is, the rotor assembly 175 must be dynamically balanced assembly and, therefore, it must include at least two rotor bars. However, it will be appreciated that it can include fewer or more than the eight bars illustrated in FIGURES 1 and 3--for example. excellent results have been achieved with a 4-bar rotor assembly.
  • n rotor bars where n equals any whole interger greater than "l"--and the shape of the rotor bars are such that pumping action is minimized. Otherwise, the rotor assembly 175 will tend to sweep the aerated fiber bed 186 over and beyond the screening means 180 rather than permitting and, indeed, assisting fiber movement through the screening means.
  • the rotor bars 181 need not be rectangular in cross-section. Rather, they can be circular, vane-shaped, or of virtually any other desired cross-sectional configuration not inconsistent with the objective of minimizing rotor pumping action.
  • the air/fiber stream exiting from housing 172 through screening means 180 does not exit radially but, rather, at an acute .angle or along chordal lines or vectors which, on average, tend to intersect a line tangent to the mid-point of the screening means 180 at an included angle a.
  • the screening means 180 covers an arc of approximately 86° and, where an 8-bar rotor is being operated at a rotor speed on the order of 1400-1450 RPM, it has been found that the angle a is generally on the order of 11°.
  • the forming zone 79 is preferably provided with sidewalls.(a portion of one such sidewall. is shown at.199 in FIGURE 3), a full-width downstream forming wall 200, and a generally parallel full-width upstream forming wall 201, which are respectively connected to rotor housing 172 at the downstream and upstream edges of screening means 180, and which respectively lie in parallel planes which intersect a line tangent to the mid-point of the screening means 180 at included angles on the order of 11°.
  • the upstream end of forming wall 201 is bent as indicated at 201A, 201B so as to form a shaped portion which generally accommodates the air/fiber flow pattern exiting the upstream portion of screening means 180.
  • the walls 199, 200 and 201 serve to enclose the-forming zone 79 and to thereby preclude disruption of the air/fiber stream as a result of mixing between ambient air and the air/fiber stream.
  • the enclosed forming zone 79 is preferably maintained at or near atmospheric pressure so as to prevent inrush and outrush of air and to thereby assist in precluding generation of cross-flow forces within the forming zone.
  • angle a can vary with changes in operating parameters such, for example, as changes in rotor RPM. However, for operation at or near optimum conditions, it is believed that the angle a will generally lie within the range of 5° to 20° and, preferably, will lie within the range of 8° to 15°.
  • the lower edges of forming walls 200, -201 terminate slightly above the surface of foraminous forming wire 80--generally terminating on the order of from one-quarter ; inch to one and one-quarter inches above the wire.
  • the upstream and downstream forming walls lie in planes which intersect the horizontally disposed forming surface 80 at included acute angles ⁇ where ⁇ is on the order of 33°.
  • is on the order of 33°.
  • the angular value of f is not critical and can vary over a wide range dependant only upon the orientation of the forming surface 80 relative to the forming zone 79.
  • the forming zone is preferably dimensioned so that under normal adjustment of variable system operating parameters, the velocity of the fiber/air stream through the forming zone is at least 20 f.p.s. and the fibers are capable of traversing the entire length of the forming zone 79 from screen 180 to forming wire 80 in not more than .1 seconds.
  • the individualized fibers, soft fiber flocs, and any aggregated fiber masses present in the feed mat 116 will be disaggregated and dispersed within the air stream passing through fiber transport duct 170 with essentially the same cross-directional mass quantum relationship as they occupied in feed mat 116.
  • the air/fiber stream enters rotor housing 172 (FIGURE 3) at approximately 65 f.p.s. [Eq. VIII] and at a fiber feed rate of 4.65 lbs./min. [Eq. II].
  • the rotor bars 181 sweep through the aerated bed 186 and across screening means 180, thus causing at least certain of the individualized fibers and soft fiber flocs within the aerated bed 186 to move through the screening means--such air-suspended fibers have a velocity vector normal to the screening means 180 of approximately 18 f.p.s. [Eq. IX] and a composite velocity vector of approximately 82 f.p.s. [Eq. XIV] directed towards screening means 180 at an acute angle--while, at the same time, sweeping nits and aggregated fiber masses over and beyond the screening means 180.
  • a negative suction zone of 1.7" H 2 0 is generated in the wake of each rotor bar 181, as best illustrated at 204 in FIGURE 6.
  • Each such negative suction zone extends the full-width of the rotor housing 172 and is parallel to the axis of the rotor assembly 175.
  • the negative suction generated would be on the order of 3.0" H 2 0.
  • the negative suction generated is sufficient to momentarily overcome the pressure drop of approximately 1.5" H 2 O across the screening means 180 and, as a consequence, normal flow of the air/fiber stream through screening means 180 ceases momentarily in the region of the screen beneath the negative suction zone 204.
  • the full-width negative suction zones 204 are, of course, also sweeping across the screening means 180 at the same velocity as the rotor bars 181--viz., 150 f.p.s.--and, as a consequence, the rapidly moving spaced full-width lifting forces serve twp o,[prtamt functions--viz., the generated lifting forces i) tend to lift individualized fibers and soft fiber flocs off screening means 180 in the wakes of the rotor bars across the full-width of rotor housing 172, thus preventing layering of fibers on the screen which tends to plug the screen openings and thus inhibits free movement of fibers through the screen; and ii), tend to lift nits and other aggregated fiber masses off the screening means 180 so as to facilitate their peripheral movement over and beyond the screening means and towards the full-width separator slot 1979.
  • Such peripheral movement results from the movement of the annular aerated bed 186 and the sweeping action of the rotor bars 181.
  • Those individualized fibers and soft fiber flocs remaining in the aerated bed 186 after transit of separator slot 179 are then returned to the region overlying screening means 180, where they are successively acted upon by the rapid succession of pressure reversal conditions from full-width negative pressure zones 204 alternating with full-width zones of positive pressure drops until all such materials pass through the screening means 180 into forming zone 79.
  • the air/fiber stream exiting from housing 172 decelerates almost immediately to approximately 36 f.p.s. [Eq. XI] within forming zone 79 and moves through the forming zone toward the foraminous forming wire 80 which is here moving at 750 ft./min.
  • the fibers are air-laid or deposited on forming wire 80 at the rate of 4.43 lbs./min. [Eq. I]--i.e., the difference between the rate of fiber supplied [Eq. II] and the 5% of fibrous materials supplied which are separated and removed through separating slot 179--to form web 60.
  • the fibers deposited on the forming wire 80 are held firmly in position thereon as a result of suction box 126 and its associated suction fan and ducting which serve to accommodate and remove the high volume of air supplied.
  • the web 60 deposited on forming wire 80 has more than adequate integrity to permit rapid movement of the forming wire. Indeed, if one desires to further increase productivity, n additional forming heads may be utilized and the speed of foraminous forming wire 80 may be increased by a factor equal to the number of separate forming heads used--e.g., under the assumed operating condition, two heads would permit operation at 1,500 f.p.m.; three heads would permit operation at 2,250 f.p.m.; et cetera.
  • the mass quantum of fibers deposited on the forming wire 80 per unit area of former screen 180 will be on the order of ten times as great as that deposited by conventional prior art sifting heads of the type shown in , FIGURE 2; and, consequently, the forming wire may be operated at speeds considerably in excess of the 1,000 f.p.m. practical limit experienced with such prior art systems. Indeed, with the present invention, forming wire speed is no longer limited by the speed of web formation but, rather, by the speed of such subsequent processing steps as bonding in the web bonding station 85 (FIG. 1).
  • the rotor assembly.175 may be formed with n rotor bars 181 where n equals any whole integer greater than "I".
  • fiber throughput--a limiting constraint when attempting to maximize productivity-- is a function of rotor speed multiplied by the square root of the number of rotor bars employed--i.e., fiber throughput: i (RPM x 4No. of rotor bars 181). This relationship will, of course, vary with the particular screen employed; and, has been graphically illustrated in FIG. 8 wherein fiber throughput in lbs./in./hr.
  • the line 209 represents the Regressor, or "line-of- best-fit", from which functional relationships between throughput and rotor speed can be determined when using a coarse wire screen of the type described above.
  • the line 210 represents the same functional relationships when using a fine wire screen of the type described above.
  • the forming system seems to be less tolerant of mismatches between forming air and rotor speed; and, where such mismatches occur, fibers tend to accumulate on the sidewalls 199 of the forming zone 79. This is readily corrected by reducing rotor speed, normally by less than 10%, while maintaining forming air constant.
  • both nit levels in the air-laid web 60, and fiber throughput in lbs./hr./in. 2 are a function of the percentage of fibrous materials removed from the aerated bed 186 through the full-width separator slot 179 (FIGURE 3).
  • line 211 graphically portrays the decreasing separation/recycle percentages (the abscissa); while, at the same time, increasing separatioh/recycle percentages are accompanied by increased fiber throughput in lbs./hr./in. 2 .
  • Numerical nit levels range from “0” (“excellent”), to “1” ("good”), to “2” (“adequate”), to "3” (“poor”), to "4" through “6” ("inadequate” to “nonacceptable”).
  • Such numerical ratings are subjective ratings based upon visual inspection of the formed web 60 and subjective comparisons of pre-established standards.
  • FIG. 9 also shows that the throughput of the forming system was increased from .62 lbs./hr./in. 2 while at the same time improving web quality from "poor” to "excellent” by increasing the fiber delivered to the system and increasing the percent recycle.
  • a 2-dimensional air-laid web forming system embodying features of the present invention will, when operating at a proper balance of fiber supply, forming air supply, and rotor speed, not only deliver maximum fiber throughput with minimum recycle, but, moreover, will exert a "healing effect" on basis weight non-uniformities entering the forming head 75. That is, the screen 180, when properly loaded with a moving or transient aerated bed 186 of fibers (FIG. 6), acts as a membrane which tends to equalize or even out the passage of fibers through adjacent incremental widths of the screen. Such "healing effect" is only operative over distances of six inches ( 6 ”) or less.
  • the "healing effect” will tend to reduce the coefficient of variation within a forming head 75 supplied with an air/fiber stream delivered through a partitioned duct 170 of the type shown in FIG. 3--viz., the effect of non-uniformities present within each four inch wide segment of the air stream exiting the partitioned duct 170 will tend to be minimized. ! The "healing effect” will not function to even out gross irregularities in fiber basis weight over a wide expanse of former widths.
  • Tables I and II represent the use of ; either a one meter prior art system (Table I) or the 2-dimensional system of the present invention having a semi-cylindrical screen 18" in circumferential length (Table II) to form webs having basis weights of 14 lbs./2880 ft. 2 (bath tissue), 17 lbs./2880 ft. 2 (facial tissue), and 26, 34 and 40 lbs./2880 ft. 2 (toweling).
  • These realistically attainable forming wire speeds may be doubled, tripled, or even further multiplied by using two, three or more forming heads.
  • Such forming wire speeds--viz., speeds ranging from about 228 to about 80 f.p.m.-- are very low for commercial production facilities.
  • a system employing four tandem distributor heads is capable of producing webs ranging from 14 to 40 lbs./2280 ft. 2 at forming wire speeds ranging from about 911 f.p.m. to about 319 f.p.m.--i.e., four times the anticipated average maximum speeds attainable when using only a single forming head 148.
  • Such a system generally requires four hammermills and all of the attendant peripheral fiber conveying and recycling systems, together with their inherent disadvantages in terms of capital investment, space, and energy consumption requirements.
  • tandem distributor heads are capable of forming webs having basis weights ranging from 26 to 40 lbs./2880 ft. 2 suitable for toweling at forming wire speeds respectively ranging from about 981 to about 638 f.p.m. mass quantum of fibers per square inch of former screen as can be delivered by a single prior art fiber distributing head 148.
  • Examples I and II (Table III) include the actual operating parameters utilized for formation of the webs of a prior art apparatus and an apparatus of the present invention, respectively.
  • Example II A further interesting comparative analysis may be made between the present invention of Example II and prior art web forming systems exemplified by Example III of Table III, page 36.
  • Example III Table III
  • both processes produced a facial tissue having approximately the same basis weight.
  • the prior art system required two tandem fiber distributor heads--together with the required peripheral hammermills, fiber conveying systems, and fiber recycling systems; as contrasted with Example II wherein the web was formed in accordance with the invention utilizing only a single forming head 75.
  • fiber throughput in the Example II system embodying the invention was 8.7 times that of the Example III prior art system and, consequently, the speed of forming wire 80 was 500 f.p.m.
  • Example II As compared to only 250 f.p.m. for Example III. While the nit level of the Example III web produced by the prior art system was “1.1" ("good") as compared to "2.7” (between “adequate” and “poor") for the web 60 of Example II, it was necessary to recycle 34% of the fibrous material input to the prior art system as contrasted with only 5.6% in the Example II system. A large portion of the recycled material was comprised of good fibers which, when hammermilled with the aggregated fiber masses, are shortened and damaged. When contrasting the operating parameters used to generate the webs of Example II and any of the other Examples, one dif- ference is worthy of mention at this point--viz., the type of screen employed. In the case of Example II, the single forming head produced significantly higher throughput rates and employed a slotted screen 11x2.5 having 43.6% open screen area; whereas the other Examples employed woven square-mesh screens 10xlO or 12x12.
  • slotted screens produce improved throughput when used with the present invention only when the slots are oriented parallel to the axis of the rotor assembly, such orientation has been found to be not critical when working with prior art forming systems of the type shown in FIGURE 2.
  • data recorded in experiments using a prior art system with a slotted screen has been used to generate the line 219 in FIGURE 10.
  • the present invention permits of greater throughput and, therefore, greater productivity, even when using woven square-mesh screens than do the prior art systems when using slotted screens (Cf., lines 216 and 219 in FIGURE 10).
  • FIGURE 11 there has been illustrated one form of system for feeding a lightly compacted feed mat having a controlled C.D. coefficient of variation directly into a forming head 75 embodying features of the present invention.
  • a feed mat such as that shown at 116 in FIGURE 3 is first conveyed between a pair of full-width compacting rolls 234, 235 which serve to lightly compact the web 116 so as to form a feed mat 236 characterized by its full-width uniformity and having a coefficient of variation of 5% or less.
  • the compacting rolls 234, 235 are hardened steel rolls and are adjusted so as to provide sufficient web compaction to form a feed mat 236 having enough integrity to permit subsequent handling; yet, not sufficient compaction as to cause hydrogen bonding of individual fibers.
  • NSWK Northern Softwood Kraft
  • the lightly compacted feed mat 236 of non-bonded fibers thus formed is fed through a full-width feed inlet 244 radially into rotor housing 172 by means of a feed roll 245.
  • the feed inlet 244 is preferably positioned downstream of air inlet 171 and upstream of discharge opening 178.
  • the arrangment is such that as'the feed mat 236 enters housing 172, it radially intersects the aerated bed 186 of fibers which is moving at a relatively high velocity such that the lightly compacted fibers of feed mat 236 are instantaneously and uniformly dispersed into the bed 186 of fibers.
  • the fibrous materials are, thereafter, selectively passed through screening means 180 disposed in outlet 178 or, alterna- . tively, through full-width tangential separator slot 179, in the manner previously described.
  • Those fibers passing through screening means 180 are conveyed through forming zone 79 and are air-laid on foraminous forming wire 80 to form web 60.
  • the lightly compacted feed mat 236 may be tangentially introduced into head 75 in the same position as the mat is feed radially in FIGURE 11, or the fibers of lightly compacted feed mat 236 may be fed into the lower end of conduit 170 after being opened by a full width lickerin located adjacent conduit 170.
  • the forming surface may take the form of a perforate or foraminous rotatable cylinder provided with an internal vacuum.
  • One or more forming heads 75 could be mounted in series thereon.
  • the forming head 75 may be mounted in any desired configuration above the forming wire 80, i.e. at a 90° angle to that shown in FIGURE 3, producing a relatively narrow, high . basis weight web, at a high forming wire speed.
  • the forming- head may likewise be angularly related to the forming wire in any manner producing the basis weight profile desired.

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Abstract

A method and apparatus for forming an air-laid web (60) of dry fibres suitable for use in a wide variety of products anging from bath and facial tissues having basis weights on :he order of 13 Ibs./2880 ft. to 181bs./2880 ft.2 to products laving basis weights on the order of 19 Ibs./2880 ft.2 to 40 bs./2880 ft2, or even heavier, on a high-speed production oasis, yet wherein the web produced, irrespective of basis weight, is characterised by random array of individualised fibres substantially undamaged by mechanical action and having a controlled cross-directional profile, and by its freedom from nits, pills, rice and the like, thereby improving both the appearance and the tensile strength of the web. The apparatus includes a 2-dimensional flow control and fibre screening system and a forming chamber (79) wherein a) substantially no cross-flow forces are created at the fibre feeding, screening and forming stages so as to ensure that the cross-directional profile of the web produced is controlled within desired limits and permitting formation of high-quality webs of virtually any desired width; b) the fibres are subjected to only minimal mechanical disintegrating action at all stages of the process subsequent to hammermilling, and, thus, shortening, curling and/or rolling of the fibres into pills, rice, or nits is minimized and, to the fullest extent possible, eliminated. Those pills, rice, nits and/or aggregated fibre masses present in the fibre stream fed to and/or through the flow control and fibre screening system are preferably centrifugally and tangentially separated from individualised fibres and soft fibre flocs across the full width of the apparatus.

Description

  • The present invention relates to a method and apparatus for forming non-woven fabrics and to the products produced thereby suitable for bath tissue or the like to heavier webs suitable for facial tissues, components for feminine napkins, diaper fillers, toweling, wipes, non-woven fabrics, saturating paper, paper webs, paperboard, et cetera.
  • Conventionally, materials suitable for use as disposable tissue and towel products have been formed on paper-making equipment by water-laying a wood pulp fibrous sheet. Following formation of the sheet, the water is removed either by drying or by a combination of pressing and drying. As water is removed during formation, surface tension forces of very great magnitude develop which press the fibers into contact with one another resulting in overall hydrogen bonding at substantially all fiber intersections; and a thin, essentially planar sheet is formed. It is the hydrogen bonds between fibers which provide sheet strength and, such bonds are produced even in the absence of extensive additional pressing. Due to this overall bonding phenomenon, cellulosic sheets prepared by water-laid methods inherently possess very unfavorable tactile properties (e.g., harshness, stiffness, low bulk, and poor overall softness) and, additionally, possess poor absorbency characteristics rendering such sheets generally unsuitable for use as sanitary wipes, bath and facial tissues, and toweling.
  • To improve these unfavorable properties, water-laid sheets are typically creped from the dryer roll with a doctor blade. Creping reforms the flat sheet into a corrugated-like structure thereby increasing its bulk and simultaneously breaking a signif cant portion of the fiber bonds, thus artifically improving the tactile.and absorbency properties of the material. But creping raises several problems. Conventional creping is only effective on low basis weight webs (e.g., webs having basis weights less than about 15 lbs./2880 ft.2), and higher basis weight webs, after creping, remain quite stiff and are generally unsatisfacto for uses such as quality facial tissues.
  • As will be apparent from the foregoing discussion, conventional paper-making methods have extreme water requirements which limit the locations where paper-making operations may be carried out. Such operations require removing a large quantity of the water used as the carrier, and the used process water can create an associated water pollution problem. Still further, the essential drying procedures consume tremendous amounts of energy.
  • Air forming of wood pulp fibrous webs has been carried out for many years; however, the resulting webs have been used for applications where either little strength is required, such as for absorbent products--i.e., pads--or applications where a certain minimum strength is required but the tactile and absorbency properties are unimportant--i.e., various specialty papers In the late 1940's and early 1950's, a system was proposed employing rotor blades mounted within a cylindrical fiber "disintegrating and dispersing chamber" wherein air-suspended fibers were fed to the chamber and discharged from the chamber through a screen on to a forming wire. However, serious problems with these types of forming systems were encountered as a result of disintegration of the fibers by mechanical co-action of the rotor blades with the chamber wall and/or the screen mounted therein which caused fibers to be "rolled and formed into balls or rice which resist separation" - a phenomenon more commonly referred to today as "pilling". Furthermore, fiber damage was encountered due to the disintegrating action of the rotor in the- cylindrical chamber.
  • A second type of system for forming air-laid webs of dry cellulosic fibers which has found limited commercial use has been developed. In general, this system employs a fiber sifting chamber or head having a planar sifting screen which is mounted over a forming wire. Fibers are fed into the sifting chamber where they are mechanically agitated by means of a plurality of mechanically driven rotors mounted for rotation about vertical axes. Each rotor has an array of symmetrical blades which rotate in close proximity to the surface of the sifting screen. The system generally employs two, three or more side-by-side rotors mounted in suitable forming head.
  • This type of sifting equipment suffers from poor productivity and other inherent disadvantages, especially when making tissue-weight webs. For example, the rotor action concentrates most of the incoming material at the periphery of the blades where the velocity is at a maximum. Most of the sifting action is believed to take place in these peripheral zones, while other regions of the sifting screen are either covered with more slowly moving material or are bare. Thus, a large percentage of the sifting screen area is poorly utilised and the system productivity is low. Moreover, fibres and agglomerates tend to remain in the forming head for extended periods of time, especially in the lower velocity, inner regions beneath the rotor blades. This accentuates the tendency of fibres to roll up into pills. Consequently, if the forming head is to be cleared of agglomerated material, it is necessary to remove 10% or more by weight of the incoming material from the forming head for subsequent reprocessing or for use.in less critical end products. The separating method used entrains a large number of good fibres with the agglomerates leaving the forming head. The severe mechanical action of the hammermills in the secondary processing system damages and shortens such otherwise good fibres, while breaking up the agglomerates. Another inherent shortcoming of these systems is a tendency to form webs having a non-uniform weight profile across their width. This is a condition which is very difficult to overcome. It is especially troublesome when making webs in the towelling and lightweight tissue ranges.
  • We have found that, when using high quality fibres - i.e., long, straight fibres, in a sifting type system - the above difficulties were aggravated. The rate of pill formation increased and it was necessary to remove and recycle more than 50% by weight of the incoming fibrous material to produce good quality tissue-weight webs. Productivity was unacceptably low and excessive damage was done to otherwise good fibres during the secondary hammermilling step. The tensile strength of the webs produced was decreased. Moreover, the circular movement of the rotors above the screen causes corresponding air and fibre movement in the forming region below the screen. Strong, unstable cross-flow forces are present and contribute to non-uniform formation of the web. Efforts to compensate for the low throughput of sifting type systems involve increasing the area of the screens and the forming surface. Thus, fibre is more thinly distributed over the forming surface and is not held in place as firmly by the suction box. The fibres are easily disturbed at higher speeds and wave patterns are formed in the resulting sheet. Fibres are also disturbed by the sea-1------ rollers which are required to maintain the forming region at sub-atmospheric pressure. The-difficulties described above compound each other and are especially troublesome when forming lightweight webs at acceptable production speeds.
  • In an effort to overcome the productivity problem, complex production systems have been devised utilising multiple forming heads - for example, up to eight separate spaced forming heads associated with multiple hammermills and each employing two or three side-by-side rotors. The most recent sifting type systems employing on the order of eighteen, twenty or more rotors per forming head, still require up to three separate forming heads in order to operate at satisfactory production speeds - that is, the systems employ up to fifty-four to sixty, or more, separate rotors with all of the attendant complex drive systems; feed arrangements, recycling equipment and hammermill equipment.
  • Moreover, it has been found that the foregoing sifting systems are also deficient in that there is only limited control of cross-directional uniformity of the web being produced thereby imposing severe constraints when attempting to scale the equipment ,up to make webs of 96 inches, 120 inches, 200 inches, or more, in width. The tensile properties of the web may suffer as a result of excessive mechanical action in the forming heads and non-uniformities in web weight and formation. The aesthetic appearance of the webs is often less than optimum as a result of wave patterns on the web surface resulting from the closely spaced rotor blades which are rotating in a horziontal plane just above the forming wire and the other factors described above.
  • To date, the foregoing problems have been so significant that this type of sifting system has been found totally unsuitable for making relatively lightweight webs at acceptable production speeds--e.g., webs having basis weights of from 13 lbs./2880 ft.2 to 18 lbs./2880 ft.2 suitable for use as bath or facial tissues--although such equipment can produce low basis weight webs at low forming wire speeds. Rather, the equipment has generally found application in forming heavier basis weight webs suitable for use in making towels or paperboard where the web imperfections inherently produced can be either tolerated or masked because of the bulk and thickness of the web.
  • During the 1970's we have proposed yet another approach to the formation of air-laid dry fiber webs. Our development has been found to resolve a number of the problems that have heretofore plagued the industry. For example, high productivity rates have been achieved and fiber webs can easily be formed at high machine speeds. However, the system requires preparatioi of pre-formed rolls of fibers having high cross-directional uniformity and is not suitable for use with bulk or baled fibrous materials. Because of this, problems are experienced when attempting to scale the equipment up to produce wide webs - i.e., webs on the order of 120 inches in width or greater - and the requirement for pre-formed special web rolls having the requisite uniformity in cross-directional profile has been such that, to date, the system has found only limited commercial application.
  • Indeed, heretofore it has not been believed that air- forming techniques can be advantageously used in high speed production operations to prepare cellulosic sheet material that is sufficiently thin, and yet has adequate strength, together with softness and absorbency, to serve in applications such as bath tissues, facial tissues and light weight toweling.
  • A method of forming an air-laid web of dry fibers in accordance with the present invention comprises a) conveying individual fibers and soft fiber flocs in a high volume air stream through a flow control and screening system wherein provision is made for substantially eliminating cross-flow and eddy current forces so as to maintain cross-directional control of the mass quantum of fibers being conveyed and wherein the fibrous materials are subjected to only minimal mechanical action so as to minimize the formation of undesired pills and nits; b) separating individual fibers and soft fiber flocs from undesired pulp lumps, pills, rice, nits and other undesired aggregated fiber masses with the individualized fibers and soft fiber flocs being permitted to pass through a separator screen into a forming zone while the undesired aggregated fiber masses are withdrawn from the air stream for secondary hammer milling operations and/or scrap or usage in inferior products; and, c) air-laying the dry individual fibers and soft fiber flocs on a relatively moving forming surface in a largely random pattern while maintaining cross-directional control of the mass quantum of fibers being air-laid across the full-width of the forming zone. i
  • The invention will now be further described by way of example with reference to the accompanying drawings, in which:-
    • Figure 1 is a schematic side elevation of one form of apparatus which may be employed for the air deposition of dry fibers to form a web continuum in accordance with the present invention:
    • Figure 2 is a schematic side elevational view of a conventional prior art fiber sifting system utilized in the commercial manufacture of dry formed webs, generally of the type having basis weights on the order of 24 lbs./2880 ft.2 or higher;
    • Figure 3 is an oblique view, partially cut away, schematically illustrating details of an exemplary novel fiber feed, educator, flow control, screening, and fiber forming arrangement in accordance with the invention;
    • Figure 4 is a diagrammatic plan view indicating in an idealised fashion, fiber movement through a conventional woven square-mesh screen under the influence of air movement and rotor action;
    • Figure 5 is a view similar to Figure 4, but depicting movement of fibers through a high capacity slotted screen in I which the slots are oriented parallel to the axis of the rotor;
    • FIGURE 6 is an enlarged, fragmentary side elevation depicting in diagramatic form the air/fiber stream as it moves through the rotor housing where an annular moving aerated bed of fibers is created and maintained and, thereafter, as it moves through the screening means and forming zone;
    • FIGURE 7 is a highly enlarged view of a portion of the system shown diagramatically in FIGURE 6, depicting how the differential relative velocities of the rotor bars and air stream serve to generate a rapidly moving full-width zone of negative pressure in the wake of each rotor bar;
    • FIGURE 8 is a graphic representation of a typical set of curves indicative of the functional relationships existing with air-laid web forming systems embodying features of the present invention between fiber throughput for specific representative screen designs and rotor assembly operating parameters--viz., rotor RPM and the number of rotor bars employed;
    • FIGURE 9 is a graphic representation of the functional relationships existing between nit levels in a finished air-laid web made in accordance with the present invention, fiber throughput, and the precentage of fibrous materials separated and/or recycled prior to deposition on a moving forming wire;
    • FIGURE 10 is a graphic representation depicting the relationship between fiber delivery rates expressed as fiber throughout in pounds per square inch per hour (Ibs./in. 2 /hr.) and both woven square-mesh screens and slotted screens having screen openings ranging from about 0.03" in at least one direction to about 0.08" in at least one direction when using both prior art systems and systems embodying features of the present invention;
    • FIGURE 11 is a view similar to the rotor chamber portion of FIGURE 1, but here depicting a modified arrangement in which a lightly compacted feed mat of non-bonded fibers is fed directly into the rotor chamber as contrasted with the system shown in FIGURES 1 and 9 wherein the fibers are pre-opened and fed into the chamber suspended in an air stream.
    Definitions
  • To facilitate an understanding of the ensuing description and the appended claims, definitions of certain selected terms and phrases as used throughout the specification and claims are set forth below.
  • The words "nit", "pill" and/or "rice" are herein each used to describe a dense, rolled up bundle of fibers, often including bonded fibers, having a bulk density greater than .2 grams per cubic centimeter (g./cc.) and which are generally formed by mechanical action during fiber transport or in a rotor chamber where the fibers are commonly, and often intentionally, subjected to mechanical disintegrating action.
  • The terms "floc" and "soft floc" are herein used to describe soft, cloud-like accumulations of fibers which behave like individualized fibers in air; i.e., they exhibit relatively high coefficients of drag in air.
  • "Bulk density" is the weight in grams of an uncompressed sample divided by its volume in cubic centimeters.
  • The phrase "2-dimensional" is used to describe a system for forming a web wherein: i) the cross-section of the system and the flows of air and fiber therein are the same at all sections across the width of the system; and ii), where each increment of system width behaves essentially the same as every other increment of.system width; thereby permitting the system to be scaled up or down to produce high quality webs of any suitable and commercially useful widths on a high-speed production basis and wherein a web's cross-directional profile in terms of basis weight can be controlled and, preferably, can be maintained uniform.
  • The phrase "coefficient of variation" is used herein to describe variations in the cross-directional basis weight profile of both the web being formed and the fibrous materials input to the system, and comprises the standard deviation (a) expressed as a percent of the mean. The coefficient of variation should not vary more than 5% and, preferably, should vary less than 3% in the cross-machine direction. The basis weight profile in the cross-machine direction of the web being formed may, for example, be determined by weighing strips of the web which are three inches in width (3" C.D.) by seven inches in length (7" M.D.).
  • The term "throughput" and the phrase "rate of web formation" are herein used generally interchangeably and are to be distinguished from the phrase "rate of fiber delivery". Thus, the phrase "rate of fiber delivery" is intended to mean the mass quantum or weight rate of feed of fibrous materials delivered to the forming head, and may be expressed, for example, in units of pounds per hour per inch of former width (lbs./hr./in.), pounds per minute per foot of former width (lbs./min./ft.), or in any other suitable units. "Throughput", on the other hand, is intended to describe the-screening rate for fibrous materials discharged from the forming head--i.e., the mass quantum or weight rate of fiber delivery through the former screen per unit area of screen surface--and may be expressed, for examole, in units of pounds per hour per square inch of effective screen surface area (lbs./hr./in.2).
  • Overall System Description
  • Briefly, and referring first to FIGURE 1, there has been illustrated an exemplary system for forming an air-laid web 60 of dry fibers, such system here comprising: a fiber metering section, generally indicated at 65; a fiber.transport or educator section, generally indicated at 70; a forming head, generally indicated at 75, where provision is made for controlling air and fiber flow, and where individual fibers are screened from undesirable aggregated fiber masses and, thereafter, are air-laid on a foraminous forming wire 80; a suitable bonding station, generally indicated at 85,.where the web is bonded to provide strength and integrity; a drying station, generally indicated at 87, where the bonded web 60 is dried prior to storage; and, a take-up or .reel-type storage station, generally indicated at 90, where the air-laid web 60 of dry fibers is, after bonding and drying, formed into suitable rolls 95 for storage prior to delivery to some subsequent processsing operation (not show-n) where the web 60 can be formed into specifically desired consumer products. In keeping with the present invention, the forming head 75 includes a separator system, generally indicated at 76, for continuous removal of aggregated fiber masses. Such separated aggregated fiber masses and individualized fibers entrained therewith are preferably removed from the forming area by means of a suitable conduit 77 maintained at a pressure level lower than the pressure within the forming head 75 by means of a suction fan (not shown). The conduit 77 may convey the masses to some other area (not shown) for use in inferior products, for scrap, or, alternatively, the undesirable aggregated fiber masses may be recycled to a hammermill where the masses are subjected to secondary mechanical disintegration prior to reintro--duction into fiber meter-65. Finally, the forming head 75 also includes a forming chamber, generally indicated at 79, positioned immediately above the foraminous forming wire 80. Thus, the arrangement is such that individual fibers and soft fiber flocs pass through the forming chamber 79 and are deposited or air-laid on the forming wire 80 to form a web 60 characterized by its controlled cross-directional profile andbasis weight.
  • Fiber Metering Section
  • While various types of commercially available fiber metering systems 65 can, with suitable modifications, be employed with equipment embodying the features of the present invention, one system which has been found suitable and which permits of the necessary modifying adaptations is a RANDO-FEEDERO (a registered trademark of the manufacturer, Rando Machine Corporation, Macedon, New York).
  • It is very desirable for proper operation - that a uniform density fiber mass is conveyed to the forming head 75 in the air stream in eductor 70. The Rando-FeederS has been found to provide a sufficiently uniform fiber stream to produce quality webs in the present apparatus.
  • Web Forming, Compacting, Bonding, Drying & Storage Section
  • A vacuum box 126 positioned immediately below the forming wire 80 and the web forming section 79 serves to maintain a positive downwardly moving stream of air which assists in collect- ing the web 60 on the moving wire 80. If desired, a second supplementary vacuum box 128 may be provided beneath the forming wire at the point where the web 60 exits from beneath the forming chamber 79, thereby insuring that the web is maintained flat against the forming wire.
  • After formation, the web 60 is passed through calendar rolls 129 to lightly compact the web and give it sufficient integrity to permit ease of transportation to conveyor belt 130. A light water spray can be applied from nozzles 131 and 135 in order to counteract static attraction between the web and the wire. An air shower 132 and vacuum box 134 serve to clean loose fibers from the wire 80 and thus prevent fiber build-up.
  • After transfer to the belt 130, the web 60 may be bonded in any known conventional manner such, merely by way of example, as i) spraying with adhesives such as latex, ii) overall calendering to make a saturating base paper--i.e., a bulky web with a controlled degree of hydrogen bonding--iii) adhesive print pattern bonding, or other suitable process. Such bonding processes do not form part of the present invention and, therefore, are . neither shown nor described in detail herein, but, such processes are well known to those skilled in the art of non-woven fabric manufacture. Bonding of the web as by rolls 136 and 138, and drying at 87, may be necessary prior to forming the roll 95.
  • Multiple forming heads 75 may be provided in series in order to increase overall productivity of the system.
  • Prior Art Sifting Systems
  • Referring next to FIGURE 2, there has been illustrated a conventional sifting system of the type described in
  • U.S. Pat No. 4,014,635 for forming air-laid webs of dry fibers. As here shown, a hammermill 141 disintegrates fiber provided through conduit 142, the fiber being thereafter conveyed to distributor 148 for distribution onto moving forming wire 80 through screen 150. A plurality of rotating impellers 151 rotate about vertical axes and "sift" the fiber through screen 150. Material to be recycled is removed through conduit 155a to the hammermill 141.
  • In operation, pulp or other fibrous material is subjected to intensive mechanical disintegration in hammermill 141, and the resulting individualized fibers, pills and pulp lumps are then fed into the fiber distributor 148 where they are subjected to severe mechanical agitation by impellers 151. Such mechanical agitation results in stratification of the fibrous materials, with the finer materials said to move downwardly, and the coarser materials rising upwardly where such coarse materials are recycled to hammermill 141 for secondary hammermilling operations. The finer materials include individual fibers, soft fiber flocs and relatively small nits which are mechanically propelled across the surface of and through the perforate bottom wall or screen . 150 by the agitating and sifting action provided by the impellers 151. That material passing through the perforate bottom wall or mesh screen 150 is then deposited on the forming wire 80 by means of gravity and the air stream generated by suction box 126 to form an air-laid web 60' of dry fibers.
  • The foregoing sifting system has proven suitable for forming relatively high basis weight webs--e.g., webs having basis weights on the order of 24 lbs./2880 ft. or greater. However, it has been found that extremely high fiber recycle percentages must be maintained when attempting to form webs, particularly when attempting to form relatively light basis weight webs suitable for bath and/or facial tissues. As a result, productivity of the fiber distributor is extremely low, and a large percentage of the input fibers are subjected to secondary hammermilling operations which tend to further shorten, curl and otherwise damage the fibers and which require excessive amounts of energy consumption. And, of course, the rotary sifting action of the impellers 151 tends to roll fibers between the impeller blades and the housing 149 and the screen 150 thus generating a large number of undesired pills which increase the recycle percentage.
  • In order to increase the productivity of this system, a number of distributor heads may be mounted in series over a single forming wire. In this manner each distributor lays a very thin layer of fibers on the layer from the preceding distributor. However, such systems are limited in width and generally have poor cross-directional profiles, poor formation, and low strength due to mechanical damage to the fibers.
  • The flow control and screening arrangement of our apparatus is of the 2-dimensional type employing an elongate rotor housing having a single rotor mounted for rotation about a horizontal axis located above the forming wire 80. Since the process of the present invention is essentially 2-dimensional with no component of flow in the cross-machine direction, it is significantly more manageable and predictable than a sifting type former employing multiple rotors rotating in a horizontal plane about vertical axes, thereby permitting the system to be conveniently and readily scaled up and/or down in-width-to-meet commercial web requirements.
  • In order for the apparatus shown in the drawings to function properly, it is necessary to provide uniform full-width feed of fibers having a controlled cross-directional profile in terms of the mass quantum of fibers. To this end, and as best illustrated in Figure 3, feed mat 116 may be formed which meets the preferred conditions of full-width uniformity in terms of the mass quantum of fibers forming the mat and the coefficient of variation of the fibrous materials input to the system. The mat thus formed is then fed into the teeth of lickerin 121 which serves to disaggregate the fibers defining the mat by combing such fibers (along with any pulp lumps, nits and other aggregated fiber masses which are present) out of the mat and feeding such materials directly into a high volume air stream 123.
  • In operation, the air-suspended fiber stream is conveyed through a suitable fiber transport duct 170 (FIG. 3) from the full-width eductor 70 to a full-width inlet slot 171 formed in the upper surface of, and extending fully across, a generally cylindrical housing 172 which here defines the 2-dimensional flow control, screening and separating zone 75. To insure that full-width mass quantum fiber control is maintained, the exemplary duct 170 is preferably subdivided into a plurality of side-by-side flow channels separated by partitions 174 extending the full length of the duct. It has been found that the desired coefficient of variation constraint in the web being formed can be obtained by spacing the partitions 174 apart by approximately four inches so as to form a plurality of adjacent flow channels extending across the full axial length of housing 172. It has also been found that a partitioned duct arrangement of the type shown in FIG. 3 can be advantageously used to accommodate width differences between the feed mat 116 formed in the fiber metering section 65 and the final air-laid web 60 deposited on'the foraminous forming wire 80. For example, excellent results have been obtained when attempting to form a web 60 forty-eight inches in width, utilizing a feed mat 116 only forty inches in width.
  • In carrying out the invention, air-suspended fibrous materials introduced radially into housing 172 through inlet slot 171 are conveyed by co-action of the air stream and the rotor assembly 175 through the housing 172 for controlled and selective discharge either a) through a full-width discharge opening, generally, indicated at 178 in FIG. 3, and into forming zone 79 for ultimate, air-laid deposition on forming wire 80 or, alternatively, b) through a full-width tangential separator slot 179 formed in housing 172 downstream of the discharge opening 178. The separator slot 179, which here forms part of the separation and/or recycle zone 76 (FIGS. 1 and 3), is preferably on the order of from 3/16" to 3/8" in circumferential width when working with wood fibers and, if desired, may be adjustable in any conventional manner (not shown) so as to permit circumferential widening or narrowing of the slot 179 to' optimize separation conditions.
  • To permit controlled, selective discharge of individualized fibers and soft fiber flocs through opening 178 and into forming zone 79, while at the same time precluding discharge of nits and other undesired aggregated fiber masses therethrough, suitable screening means, generally indicated at 180 in FIG. 3, is mounted within discharge opening 178. Such screening means 180 may simply take the form of a conventional woven square-mesh wire screen of the type shown at 180A in FIG. 4 and having openings sized to preclude passage of aggregated fiber masses provided that the screen openings do not exceed 0.1" open space from wire-to-wire in at least one direction and have between 38% and 46% open area. As best shown in FIG. 3, screening means 180 is formed with the same radius of curvature as the semi-cylindrical portion of housing 172 within which discharge opening 178 is formed.
  • In carrying out this aspect of the invention, rotor assembly 175 comprises a plurality of transversely extending rotor bars 181, each fixedly mounted on the outer periphery of a plurality of closely spaced spiders 182. The bars 181 move through the radially entering stream of air-suspended fibers entering at inlet slot 171. As a result of rotor bar movement and the high velocity movement of the air stream, the air and fibers tend to move outwardly towards the wall of housing 172, thus best illustrated at 186 in FIG. 6. Such annular aerated bed 186 of fibrous material is believed to be on the order of one-half inch to one and one-half inches thick (dependent upon actual operating parameters), and is believed to be moving rotationally at about half the speed of the rotor bars 181. The rotor assembly 175 is preferably designed a) to minimize pumping action which tends to reduce the relative speed differential between the rotor bars 181 and the aerated bed 186, thus causing the fibers to move over and beyond the screening means 180, and b) so as to minimize mechanical action between the rotor bars 181 and both the housing 172 and screening means 180, which action tends to disintegrate fibers and aggregated fiber masses carried in the air stream and to general pills. The rotor bars 181 are on the order of 3/4" in radial height by 3/8" in thickness, and are mounted so as to provide a clearance between the outer edges of the bars 181 and the inner wall surface of the housing 172 and screening means 180 of from 0.10 inches to 0.25 inches and, preferably, from 0.18 inches to 0.20 inches. To avoid generation of cross-flow forces, it is important that the rotor bars 181 are contznuous, extend the-full width of the rotor chamber, and are oriented parallel to the axis of the rotor assembly 175.
  • As the aerated bed--which contains individualized fibers, soft fiber flocs, nits and other aggregated fiber masses--passes over the screening means 180, some, but not all, of the individualized fibers and soft fiber flocs pass through the screening means into the forming zone 79, while the balance of the individualized fibers and soft fiber flocs, together with nits and other aggregated fiber masses, pass over the screen without exiting from the rotor housing 172. The undesired pills, rice and nits--i.e., aggregated fiber masses--have a bulk density generally in excess of .2 g./cc. and tend to be separated along with some individualized fibers and soft fiber flocs from the aerated bed 186 at the tangential separator slot 179, with those separated materials being centrifugally expelled through the slot 179 where they are entrained in a recycle or separating air stream generated by any suitable means (not shown) coupled to manifold 191 with the air-suspended separated particles moving outward through a full-width discharge passage 192 coupled to separator slot 179 and, ultimately, to conduct 77 (FIG. 1). Such separation is aided by a positive air outflow from housing 172 through separator slot 179.
  • Separation of undesired nits and aggregated fiber masses from individualized fibers and soft fiber flocs is accomplished with a full-width classifying air jet 194, provided upstream of the separator slot 179 and downstream of screening means 180; such air jet being positioned to introduce a full-width air stream generated by any conventional source (not shown) radially into rotor housing 172 just ahead of the separator slot 179. As a consequence, the positive classifying air stream introduced radially into housing 172 through air jet 194 tends to divert individualized fibers and soft fiber flocs within the aerated bed 186 radially inward as a result of the relatively high drag coefficients of such materials and their relatively low bulk density (which is-.generally on the order of less than .2 g./cc.). Since the nits and aggregated fiber masses have a relatively high bulk density in excess of .2 g./cc. and relatively low drag coefficients, the classifying air stream introduced through the full-width air jet 194 does not divert such materials to any significant extent and, therefore, such undesired materials tend to be cetrifuagally expelled through the tangential separator slot 179. It has been found that the introduction of classifying air through the full-width classifying air jev 194 into housing 172 at pressures on the order of from 30" to 100" H20 and at volumes ranging from 1.5 to 2.5 ft.3/min./in. is adequate for deflecting a significant portion of the individualized fibers and soft fiber flocs. The energy level of the classifying air jet is most conveniently controlled by adjusting its pressure.
  • In operation, it has been found that excellent results are obtained if at least 90% of the fibrous material introduced and, preferably between 95% and 99% thereof, ultimately pass through screening means 180 into the forming zone 79 and are air-laid on the foraminous forming wire 80 without requiring any secondary hammermilling operations and without being subjected to any significant mechanical disintegrating forces. The quantity of material separated may be controlled by the operator by varying the volume of recycle air supplied through manifold 191 and/or by adjusting the circumferential extent of full-width separator slot 179 in any suitable manner (not shown).
  • Although the present invention has thus far been described in connection with the use of a conventional woven square-mesh screen 180A (FIGURE 4) for the screening means 180 shown diagrammatically in FIGURE 3, it is preferred that the screening means 18.0 take the form of a high capacity slotted screen 1808--e.g., of the type shown in FIGURE 5. When utilizing a slotted type screen 180B with a 2-dimensional rotor assembly 175 mounted for rotation about a horizontal axis, it has been found essential that the screen slots be oriented with their long dimensions parallel to the axis of the rotor assembly. When so oriented, individualized fibers tend to move through the screen slots while nits and aggregated fiber masses are precluded from passing through the screen since they are generally larger in size than the narrow dimensions of the slots which, preferably, do not exceed 0.1" open space from wire-to-wire in at least one direction. However, when the slots of a slotted screen 180B are oriented with their long dimensions perpendicular to a plane passing through the rotor axis, it has been found that the screen tends to rapidly plug--indeed, when operating under commercial production conditions, it has been found that the screen tends to become completely plugged almost instantaneously.
  • The exemplary system herein described has eight rotor bars 181. However, the number and/or shape of the rotor bars may be varied, provided that such modifications are consistent with mechanical stability and low rotor "pumping" action. That is, the rotor assembly 175 must be dynamically balanced assembly and, therefore, it must include at least two rotor bars. However, it will be appreciated that it can include fewer or more than the eight bars illustrated in FIGURES 1 and 3--for example. excellent results have been achieved with a 4-bar rotor assembly. On the other hand, care must be taken to insure that the number of rotor bars employed--e.g., n rotor bars where n equals any whole interger greater than "l"--and the shape of the rotor bars are such that pumping action is minimized. Otherwise, the rotor assembly 175 will tend to sweep the aerated fiber bed 186 over and beyond the screening means 180 rather than permitting and, indeed, assisting fiber movement through the screening means. The rotor bars 181 need not be rectangular in cross-section. Rather, they can be circular, vane-shaped, or of virtually any other desired cross-sectional configuration not inconsistent with the objective of minimizing rotor pumping action.
  • It is significant to a complete understanding of the present invention that one understand the difference between the primary function of the rotor assembly here provided--viz., to lift fibrous materials upwardly and off the screen or, stated differently, to momentarily disrupt passage of the air-suspended fiber stream through the screen--and that stated for conventional cylinder rotor systems of the type where the rotor blades mechanically act upon the fibrous materials to "disintegrate" such materials and propel them through the screen.
  • Provision is made for insuring the individualized fibers passing through the screening means 180 are permitted to. move directly to the foraminous forming wire 80 without being subjected to cross-flow forces, eddy currents or the like, thereby maintaining cross-directional control of the mass quantum of fibers delivered to the forming wire through the full-width of forming zone 79. To accomplish this, provision is made for insuring that the upstream, downstream and side edges of the forming zone--i.e., the boundaries of the zone 79--are formed so as to define an enclosed forming zone and to thereby preclude intermixing of ambient air with the air/fiber stream existing housing 172 through screening means 180. It has been found that the air/fiber stream exiting from housing 172 through screening means 180 does not exit radially but, rather, at an acute .angle or along chordal lines or vectors which, on average, tend to intersect a line tangent to the mid-point of the screening means 180 at an included angle a. In the exemplary form of the invention where the screening means 180 covers an arc of approximately 86° and, where an 8-bar rotor is being operated at a rotor speed on the order of 1400-1450 RPM, it has been found that the angle a is generally on the order of 11°.
  • Consequently, the forming zone 79 is preferably provided with sidewalls.(a portion of one such sidewall. is shown at.199 in FIGURE 3), a full-width downstream forming wall 200, and a generally parallel full-width upstream forming wall 201, which are respectively connected to rotor housing 172 at the downstream and upstream edges of screening means 180, and which respectively lie in parallel planes which intersect a line tangent to the mid-point of the screening means 180 at included angles on the order of 11°. The upstream end of forming wall 201 is bent as indicated at 201A, 201B so as to form a shaped portion which generally accommodates the air/fiber flow pattern exiting the upstream portion of screening means 180. The walls 199, 200 and 201 serve to enclose the-forming zone 79 and to thereby preclude disruption of the air/fiber stream as a result of mixing between ambient air and the air/fiber stream. The enclosed forming zone 79 is preferably maintained at or near atmospheric pressure so as to prevent inrush and outrush of air and to thereby assist in precluding generation of cross-flow forces within the forming zone. Those skilled in the art will appreciate that angle a can vary with changes in operating parameters such, for example, as changes in rotor RPM. However, for operation at or near optimum conditions, it is believed that the angle a will generally lie within the range of 5° to 20° and, preferably, will lie within the range of 8° to 15°. The lower edges of forming walls 200, -201 terminate slightly above the surface of foraminous forming wire 80--generally terminating on the order of from one-quarter ; inch to one and one-quarter inches above the wire.
  • In the exemplary form of the invention shown in FIGURE 3, when the angle a is on the order of 11° and when the forming zone 79 is positioned over a horizontal forming surface 80, the upstream and downstream forming walls lie in planes which intersect the horizontally disposed forming surface 80 at included acute angles β where β is on the order of 33°. However, those skilled in the art will appreciate that the angular value of f is not critical and can vary over a wide range dependant only upon the orientation of the forming surface 80 relative to the forming zone 79.
  • Since constraining walls 200, 201 are parallel, there is no tendency to decelerate the flow (as would be the case where the walls diverge). This fact aids in preventing eddy currents and other unwanted cross-flow forces. There is, of course, some deceleration of the air/fiber stream as it exits the housing 172 through screening means 180; but, such deceleration occurs immediately upon exit from the screening means and produces only a fine scale turbulence effect which does not induce gross eddy currents or cross-flow forces. In some cases it might be desirable to have the walls 200, 201 converge slightly so as to accelerate, and therefore, stabilize the flow.
  • The forming zone is preferably dimensioned so that under normal adjustment of variable system operating parameters, the velocity of the fiber/air stream through the forming zone is at least 20 f.p.s. and the fibers are capable of traversing the entire length of the forming zone 79 from screen 180 to forming wire 80 in not more than .1 seconds.
  • I. Overall System Operation
  • Numerous system parameters may be varied in the operation of a forming system embodying the features of the present invention in order to form an air-laid web of dry fibers having specific desired characteristics. Let it be assumed that the operator wishes to form an air-laid web 60 one foot (1') in width (all ensuing assumptions are per one foot of width of the forming head 75) having a controlled uniform cross-directional profile and a basis weight of 17 lbs./2880 ft.2. Assume further:
    • a) Air-to-fiber ratio supplied through inlet slot 171 equals 350 ft.3/lb.
    • b) Inlet slot 171 is 5" in circumferential width--i.e., the dimension from edge 190 (FIGURE 3) to edge 202.
    • c) Rotor housing 172 is 24" I.D.
    • d) Rotor assembly 175 employs eight equally spaced rectangular rotor bars 181, each 3/4" in radial height by 3/8" in circumferential thickness and extending parallel to the axis of the rotor assembly continuously throughout the full width of rotor housing 172 and, each spaced from the rotor housing 172 by 0.18".
    • e) Rotor assembly 175 is driven at 1432 RPM.
    • f) Rotor bar 181 tip velocity equals 150 f.p.s.
    • g) Relative velocity between the rotor bars 181 and the aerated bed 186 is approximately 70 f.p.s.
    • h) Screening means 180 defines an arc of 86°, and has 40% open area.
    • i) Separation and/or recycle through separator slot 179 comprises 5% by weight of fibrous materials supplied through inlet slot 171.
    • j) The quantity of classifying air introduced through air jet 194 is between 1.5 and 2.5 ft.3/min./in. at pressures between 30" and 100" H2O.
    • k) Forming walls 200, 201 are parallel and spaced 9" apart in a direction normal to the parallel walls 200, 201 and 16" apart in a horizontal plane passing through their lower extremities just above the plane of the forming wire 80.
    • 1) Forming wire speed equals 750 f.p.m.
  • All of the foregoing operating parameters are either fixed and known, or can be pre-set by the operator, except for the relative velocity between the rotor bars 181 and the aerated bed 186 of fibers within the rotor housing 172. The actual speed of the aerated bed 186 is not known with certainty; but, it is believed to be on the order of half the tip velocity of the rotor bars 181. For convenience, it is here assumed to be approximately 80 f.p.s., an assumption believed to be reasonably accurate based upon observation of overall system behavior, thereby resulting in a relative velocity between the rotor bars 181 and the aerated bed 186 of approximately 70 f.p.s. (see assumption "g", Supra).
  • Accordingly, supply and velocity relationships within the foregoing exemplary system can be readily calculated as follows; and, such relationships have been illustrated in FIGURE 16:
    Figure imgb0001
    Figure imgb0002
    Figure imgb0003
    Figure imgb0004
    Figure imgb0005
    Figure imgb0006
    Figure imgb0007
    Figure imgb0008
    Figure imgb0009
    Figure imgb0010
    Figure imgb0011
    Figure imgb0012
    Figure imgb0013
    Figure imgb0014
    Figure imgb0015
  • Keeping the foregoing supply and velocity relationships in mind, it will be appreciated that the individualized fibers, soft fiber flocs, and any aggregated fiber masses present in the feed mat 116 (FIGURE 3) will be disaggregated and dispersed within the air stream passing through fiber transport duct 170 with essentially the same cross-directional mass quantum relationship as they occupied in feed mat 116. Under the assumed conditions, the air/fiber stream enters rotor housing 172 (FIGURE 3) at approximately 65 f.p.s. [Eq. VIII] and at a fiber feed rate of 4.65 lbs./min. [Eq. II]. The volume of air supplied to rotor housing 172--viz., 1,627 ft.3/min. [Eq. III]2-is such that a positive pressure of approximately 1.5" H 20 is maintained within the housing 172. Since the forming zone 79 is maintained at atmospheric pressure, there exists a pressure drop on the order of 1.5" H 20 across the screening means 180 through which the air-suspended fibers pass.
  • Although the air/fiber stream entering rotor housing 172 through inlet slot 171 is moving radially intitially, rotation of the rotor assembly 175 (counterclockwise as viewed in FIGURES 3 and 6) tends to divert the fibers outwardly towards the periphery of housing 172 so as to form an annualar aerated bed of fibers 186. Movement .of the rotor bars 181 through the annular aerated bed 186 of fibers at a rotor bar tip velocity of 150 f.p.s. tends to accelerate the air-fiber stream from its entry velocity of 65 f.p.s. [Eq. VIII) to approximately 80 f.p.s., thus resulting in a relative velocity of 70 f.p.s. between the rotor bars 181 and the aerated bed 186 of fibers. However, because of the clearance of 0.18" between the rotor bars 181 and housing 172, and the relatively small effective area of the rotor bars, only minimal pumping action occurs and there is little or no tendency to roll fibers between the rotor bars 181 and either housing 172 or screening means 180. Therefore, there is little or no tendency to form pills; and, since only minimal mechanical-disintegrating action occurs, curling or shortening of individualized fibers is essentially precluded. Rather, the rotor bars 181 sweep through the aerated bed 186 and across screening means 180, thus causing at least certain of the individualized fibers and soft fiber flocs within the aerated bed 186 to move through the screening means--such air-suspended fibers have a velocity vector normal to the screening means 180 of approximately 18 f.p.s. [Eq. IX] and a composite velocity vector of approximately 82 f.p.s. [Eq. XIV] directed towards screening means 180 at an acute angle--while, at the same time, sweeping nits and aggregated fiber masses over and beyond the screening means 180.
  • Since the rotor bars 181 are moving through the aerated bed 186 of fibers at a relative speed 70 f.p.s. faster than movement of the aerated bed, a negative suction zone of 1.7" H 20 is generated in the wake of each rotor bar 181, as best illustrated at 204 in FIGURE 6. Each such negative suction zone extends the full-width of the rotor housing 172 and is parallel to the axis of the rotor assembly 175. In the case of rotor bars having a circular cross-section (not shown), the negative suction generated would be on the order of 3.0" H 20. In either case, the negative suction generated is sufficient to momentarily overcome the pressure drop of approximately 1.5" H2O across the screening means 180 and, as a consequence, normal flow of the air/fiber stream through screening means 180 ceases momentarily in the region of the screen beneath the negative suction zone 204. The full-width negative suction zones 204 are, of course, also sweeping across the screening means 180 at the same velocity as the rotor bars 181--viz., 150 f.p.s.--and, as a consequence, the rapidly moving spaced full-width lifting forces serve twp o,[prtamt functions--viz., the generated lifting forces i) tend to lift individualized fibers and soft fiber flocs off screening means 180 in the wakes of the rotor bars across the full-width of rotor housing 172, thus preventing layering of fibers on the screen which tends to plug the screen openings and thus inhibits free movement of fibers through the screen; and ii), tend to lift nits and other aggregated fiber masses off the screening means 180 so as to facilitate their peripheral movement over and beyond the screening means and towards the full-width separator slot 1979. Such peripheral movement results from the movement of the annular aerated bed 186 and the sweeping action of the rotor bars 181.
  • Those individualized fibers, soft fiber flocs, and aggregated fiber masses within the aerated bed 186 of fibers which do not pass through the screening means 180 the first time they are presented thereabove are swept over and beyond the screening means 180 and, thereafter, past classifying air jet 194 (FIG. 3). Under the assumed conditions, the individualized fibers and soft fiber flocs tend to be diverted radially inward by the classifying air jet 194, while the undesired aggregated fiber masses are centrifugally and tangentially separated from the aerated bed 186 through full-width separator slot 179 at the rate of .22 lbs./min. [Eq. XV}. Those individualized fibers and soft fiber flocs remaining in the aerated bed 186 after transit of separator slot 179 are then returned to the region overlying screening means 180, where they are successively acted upon by the rapid succession of pressure reversal conditions from full-width negative pressure zones 204 alternating with full-width zones of positive pressure drops until all such materials pass through the screening means 180 into forming zone 79.
  • The air/fiber stream exiting from housing 172 decelerates almost immediately to approximately 36 f.p.s. [Eq. XI] within forming zone 79 and moves through the forming zone toward the foraminous forming wire 80 which is here moving at 750 ft./min. The fibers are air-laid or deposited on forming wire 80 at the rate of 4.43 lbs./min. [Eq. I]--i.e., the difference between the rate of fiber supplied [Eq. II] and the 5% of fibrous materials supplied which are separated and removed through separating slot 179--to form web 60. The fibers deposited on the forming wire 80 are held firmly in position thereon as a result of suction box 126 and its associated suction fan and ducting which serve to accommodate and remove the high volume of air supplied.
  • The web 60 deposited on forming wire 80 has more than adequate integrity to permit rapid movement of the forming wire. Indeed, if one desires to further increase productivity, n additional forming heads may be utilized and the speed of foraminous forming wire 80 may be increased by a factor equal to the number of separate forming heads used--e.g., under the assumed operating condition, two heads would permit operation at 1,500 f.p.m.; three heads would permit operation at 2,250 f.p.m.; et cetera. Moreover, as a result of the relatively high throughput capacity of each forming head 75, the mass quantum of fibers deposited on the forming wire 80 per unit area of former screen 180 will be on the order of ten times as great as that deposited by conventional prior art sifting heads of the type shown in , FIGURE 2; and, consequently, the forming wire may be operated at speeds considerably in excess of the 1,000 f.p.m. practical limit experienced with such prior art systems. Indeed, with the present invention, forming wire speed is no longer limited by the speed of web formation but, rather, by the speed of such subsequent processing steps as bonding in the web bonding station 85 (FIG. 1).
  • Experimentation has indicated that.a wide range of results are attainable dependent upon the particular operating parameters selected. For example, the rotor assembly.175 may be formed with n rotor bars 181 where n equals any whole integer greater than "I". However, it has been ascertained that fiber throughput--a limiting constraint when attempting to maximize productivity--is a function of rotor speed multiplied by the square root of the number of rotor bars employed--i.e., fiber throughput: i (RPM x 4No. of rotor bars 181). This relationship will, of course, vary with the particular screen employed; and, has been graphically illustrated in FIG. 8 wherein fiber throughput in lbs./in./hr. (the ordinate) has been plotted at various rotor speeds for each of a 2-bar, 4-bar, and 8-bar rotor assembly (the abscissa) when using both a coarse wire screen 10x2.75; .047" wire dia.; .059" screen opening; and 46.4%. open screen area) and a fine wire screen (16x4;..035" wire dia.; .032" screen opening; and 38.8% open screen area).
  • Thus, the line 209 represents the Regressor, or "line-of- best-fit", from which functional relationships between throughput and rotor speed can be determined when using a coarse wire screen of the type described above. Similarly, the line 210 represents the same functional relationships when using a fine wire screen of the type described above. The data thus cor- roborates experimental findings that rotor RPM can be reduced while fiber throughput is maintained, or even increased, by going, for example, from a 4-bar rotor assembly 175 to an 8-bar rotor assembly 175. However, when using an 8-bar rotor assembly 175, the forming system seems to be less tolerant of mismatches between forming air and rotor speed; and, where such mismatches occur, fibers tend to accumulate on the sidewalls 199 of the forming zone 79. This is readily corrected by reducing rotor speed, normally by less than 10%, while maintaining forming air constant.
  • It has further been discovered that both nit levels in the air-laid web 60, and fiber throughput in lbs./hr./in.2, are a function of the percentage of fibrous materials removed from the aerated bed 186 through the full-width separator slot 179 (FIGURE 3). Thus, referring to FIG. 9, line 211 graphically portrays the decreasing separation/recycle percentages (the abscissa); while, at the same time, increasing separatioh/recycle percentages are accompanied by increased fiber throughput in lbs./hr./in.2. Numerical nit levels range from "0" ("excellent"), to "1" ("good"), to "2" ("adequate"), to "3" ("poor"), to "4" through "6" ("inadequate" to "nonacceptable"). Such numerical ratings are subjective ratings based upon visual inspection of the formed web 60 and subjective comparisons of pre-established standards.
  • As the pressure of the recycle air supplied through manifold 191 is decreased and/or as separator slot 179 is widened, thereby modulating the pressure conditions within discharge conduits 192 (FIG. 3) and 77 (FIG. 1) which are maintained at a pressure level below that within the forming head 75 means of a suction fan (not shown), the amount of fibrous material removed from rotor housing 172 through separator slot 179 is increased. As the percentage of fibrous materials separated and/or recycled increases, nit level in the formed web 60 decreases.
  • FIG. 9 also shows that the throughput of the forming system was increased from .62 lbs./hr./in.2 while at the same time improving web quality from "poor" to "excellent" by increasing the fiber delivered to the system and increasing the percent recycle.
  • It has been found that a 2-dimensional air-laid web forming system embodying features of the present invention will, when operating at a proper balance of fiber supply, forming air supply, and rotor speed, not only deliver maximum fiber throughput with minimum recycle, but, moreover, will exert a "healing effect" on basis weight non-uniformities entering the forming head 75. That is, the screen 180, when properly loaded with a moving or transient aerated bed 186 of fibers (FIG. 6), acts as a membrane which tends to equalize or even out the passage of fibers through adjacent incremental widths of the screen. Such "healing effect" is only operative over distances of six inches (6") or less. However, the "healing effect" will tend to reduce the coefficient of variation within a forming head 75 supplied with an air/fiber stream delivered through a partitioned duct 170 of the type shown in FIG. 3--viz., the effect of non-uniformities present within each four inch wide segment of the air stream exiting the partitioned duct 170 will tend to be minimized. ! The "healing effect" will not function to even out gross irregularities in fiber basis weight over a wide expanse of former widths.
  • Comparative Forming Capacities and Web Characteristics Between Prior Art Air-Laid Web Forming Systems and 2-Dimensional Systems Embodying Features of the Present Invention
  • In order to facilitate an understanding of the significant improvements obtained in terms of productivity when comparing air-laid, dry fiber web forming systems of the present invention with prior art systems, Tables I and II represent the use of ; either a one meter prior art system (Table I) or the 2-dimensional system of the present invention having a semi-cylindrical screen 18" in circumferential length (Table II) to form webs having basis weights of 14 lbs./2880 ft.2 (bath tissue), 17 lbs./2880 ft.2 (facial tissue), and 26, 34 and 40 lbs./2880 ft.2 (toweling).
    Figure imgb0016
  • Thus, referring first to Table I, it will be observed that a conventional prior art air-laid web forming system of the type shown in FIG. 2 employing only a single fiber distributor 148 is capable of being set to produce a web having a bsis weight of 14 lbs;/2880 ft.2 at an anticipated average maximum operating speed for forming wire 80 on the order of 228 f.p.m. In order to produce formed webs having progressively increasing basis weights (assuming all other operating parameters remain fixed at the optimum settings), it is merely necessary to reduce the speed of the forming wire 80. Thus, when operating-the forming wire 80
    Figure imgb0017
  • Referring next to Table II, it will be observed that a single forming head 75 embodying the features of the present invention--e.g., the type shown in FIGS. 1 and 3--is capable of producing similar webs having basis weights ranging from 14-40 lbs./2880 ft.2 at forming wire speeds ranging from about 911 f.p.m. to about 319 f.p.m.--viz., speeds comparable to the speeds obtainable with a prior system requiring four tandem distributor heads. These realistically attainable forming wire speeds may be doubled, tripled, or even further multiplied by using two, three or more forming heads. Consequently, the formation of air-laid webs of dry fibers is no longer limited to low forming wire speeds; and, this is believed to be a direct result of the fiber throughput capacity of each forming head 75 which is capable of delivering in the order of ten times the at a speed on the order of 187 f.p.m., it is possible to produce a web having a basis weight of 17 lbs./2880 ft.2; while operation at forming wire speeds on the order of 122, 94 and 80 f.p.m. permits formation of toweling grade webs having basis eights of 26, 34 and 40 lbs./2880 ft.2, respectively. Such forming wire speeds--viz., speeds ranging from about 228 to about 80 f.p.m.-- are very low for commercial production facilities. However, it is possible to increase the anticipated average maximum speed obtainable by the simple expedient of increasing the number of distributor heads 148 employed. For example, a system employing four tandem distributor heads is capable of producing webs ranging from 14 to 40 lbs./2280 ft.2 at forming wire speeds ranging from about 911 f.p.m. to about 319 f.p.m.--i.e., four times the anticipated average maximum speeds attainable when using only a single forming head 148. Such a system, however, generally requires four hammermills and all of the attendant peripheral fiber conveying and recycling systems, together with their inherent disadvantages in terms of capital investment, space, and energy consumption requirements.
  • Still greater forming wire speeds are attainable with the conventional prior art systems by employing additional fiber distributor heads. For example, eight tandem distributor heads are capable of forming webs having basis weights ranging from 26 to 40 lbs./2880 ft.2 suitable for toweling at forming wire speeds respectively ranging from about 981 to about 638 f.p.m. mass quantum of fibers per square inch of former screen as can be delivered by a single prior art fiber distributing head 148.
  • Examples--Comparative Representative and/or Optimum Operating Parameters for Air-Laid Dry Fiber Web Forming Systems in Accordance with the Present Invention and the Prior Art
  • Examples I and II (Table III) include the actual operating parameters utilized for formation of the webs of a prior art apparatus and an apparatus of the present invention, respectively.
  • A further interesting comparative analysis may be made between the present invention of Example II and prior art web forming systems exemplified by Example III of Table III, page 36. Thus, when contrasting Example II and Example III, it will be noted that both processes produced a facial tissue having approximately the same basis weight. However, the prior art system required two tandem fiber distributor heads--together with the required peripheral hammermills, fiber conveying systems, and fiber recycling systems; as contrasted with Example II wherein the web was formed in accordance with the invention utilizing only a single forming head 75. Yet, fiber throughput in the Example II system embodying the invention was 8.7 times that of the Example III prior art system and, consequently, the speed of forming wire 80 was 500 f.p.m. for Example II as compared to only 250 f.p.m. for Example III. While the nit level of the Example III web produced by the prior art system was "1.1" ("good") as compared to "2.7" (between "adequate" and "poor") for the web 60 of Example II, it was necessary to recycle 34% of the fibrous material input to the prior art system as contrasted with only 5.6% in the Example II system. A large portion of the recycled material was comprised of good fibers which, when hammermilled with the aggregated fiber masses, are shortened and damaged.
    Figure imgb0018
    When contrasting the operating parameters used to generate the webs of Example II and any of the other Examples, one dif- ference is worthy of mention at this point--viz., the type of screen employed. In the case of Example II, the single forming head produced significantly higher throughput rates and employed a slotted screen 11x2.5 having 43.6% open screen area; whereas the other Examples employed woven square-mesh screens 10xlO or 12x12.
  • The dramatic improvement in throughput is evident upon inspection of the data as reproduced in graphic form in FIGURE 10. Thus, as here shown fiber throughput has been plotted versus the screen opening size in inches as determined in experiments run by applicant. The line 215 is thus representative of fiber throughput when using woven square-mesh screens in a conventional prior art system, and the remarkably improved throughput achieved with the present invention when using woven square-mesh screens is reflected by the line 216.
  • Even more remarkable throughput rates are attained when utilizing a slotted screen of FIGURE 5 with a 2-dimensional former of the present invention as reflected by line 218.
  • Surprisingly, although slotted screens produce improved throughput when used with the present invention only when the slots are oriented parallel to the axis of the rotor assembly, such orientation has been found to be not critical when working with prior art forming systems of the type shown in FIGURE 2. Thus, data recorded in experiments using a prior art system with a slotted screen has been used to generate the line 219 in FIGURE 10. It should, however, be noted that the present invention permits of greater throughput and, therefore, greater productivity, even when using woven square-mesh screens than do the prior art systems when using slotted screens (Cf., lines 216 and 219 in FIGURE 10).
  • Finally, reference is made to the cross-hatched line 220 in FIGURE 10 which is indicative of maximum throughputs obtainable with multiple head prior art web forming systems. Such data has been reported in publications, although the data does not reflect the particular screen characteristics used.
  • Alternative Lightly Compacted Feed Mat Delivery Systems
  • Turning next to FIGURE 11, there has been illustrated one form of system for feeding a lightly compacted feed mat having a controlled C.D. coefficient of variation directly into a forming head 75 embodying features of the present invention. As here shown, a feed mat such as that shown at 116 in FIGURE 3 is first conveyed between a pair of full-width compacting rolls 234, 235 which serve to lightly compact the web 116 so as to form a feed mat 236 characterized by its full-width uniformity and having a coefficient of variation of 5% or less. The compacting rolls 234, 235 are hardened steel rolls and are adjusted so as to provide sufficient web compaction to form a feed mat 236 having enough integrity to permit subsequent handling; yet, not sufficient compaction as to cause hydrogen bonding of individual fibers.
  • For example, when working with Northern Softwood Kraft (NSWK) fibers, it has been found that the requisite degree of compaction can be achieved with compacting forces on the order of 200 to 800 p.l.i. (pounds per lineal inch) when using two equal diameter hardened steel rolls 234, 235, each 6" in diameter.
  • In carrying out this modification, the lightly compacted feed mat 236 of non-bonded fibers thus formed is fed through a full-width feed inlet 244 radially into rotor housing 172 by means of a feed roll 245. The feed inlet 244 is preferably positioned downstream of air inlet 171 and upstream of discharge opening 178. The arrangment is such that as'the feed mat 236 enters housing 172, it radially intersects the aerated bed 186 of fibers which is moving at a relatively high velocity such that the lightly compacted fibers of feed mat 236 are instantaneously and uniformly dispersed into the bed 186 of fibers.
  • The fibrous materials are, thereafter, selectively passed through screening means 180 disposed in outlet 178 or, alterna- . tively, through full-width tangential separator slot 179, in the manner previously described. Those fibers passing through screening means 180 are conveyed through forming zone 79 and are air-laid on foraminous forming wire 80 to form web 60. It will be noted that in this arrangement, those fibers freshly introduced into the housing 172 through inlet 244 will, at least initially, be principally located within the radially outermost regions of the aerated bed 186 and, consequently, will be in close proximity to the screening means 180; whereas those fibers not discharged through the screen 180 on the first pass will tend to be principally located in the radially innermost regions of the aerated bed 186 of fibers. Consequently, it is believed that this arrangement will permit relatively high forming capacity since a high mass quantum of fibers are dispersed in the outermost regions of the aerated bed just upstream of the screening means 180 where they will have immediate access to the screening means. Alternatively, the lightly compacted feed mat 236 may be tangentially introduced into head 75 in the same position as the mat is feed radially in FIGURE 11, or the fibers of lightly compacted feed mat 236 may be fed into the lower end of conduit 170 after being opened by a full width lickerin located adjacent conduit 170.
  • Alternative Flow Control or Web Collection Systems
  • It is anticipated that acceptable results may be obtained by providing the screen 180 with a radius of curvature substantially greater than that of the rotor assembly 175, and offsetting the axes of rotation of rotor assembly 175 from the geometric center of head 75, such that the rotor bars coverage toward the screen and more heavily load the aerated fiber bed 186 and increase the fiber throughput.
  • It is also anticipated that the forming surface may take the form of a perforate or foraminous rotatable cylinder provided with an internal vacuum. One or more forming heads 75 could be mounted in series thereon.
  • Of course, the forming head 75 may be mounted in any desired configuration above the forming wire 80, i.e. at a 90° angle to that shown in FIGURE 3, producing a relatively narrow, high . basis weight web, at a high forming wire speed. The forming- head may likewise be angularly related to the forming wire in any manner producing the basis weight profile desired.
  • Those skilled in the art will appreciate that there has herein been described a novel web forming system characterized by its simplicity and lack of complex, space-consuming, fiber handling equipment; yet, which is effective in forming air-laid webs of dry fibers at commercially acceptable production speeds irrespective of the basis weight of the web being formed. At the same time, the absence of cross-flow forces insures that the finished web possesses the desired controlled C.D. profile which may be either uniform or non-uniform.

Claims (23)

1. A method of forming an air-laid web of dry fibres comprising conveying individual fibres and soft fibre-flocs in an air stream through a screen and a forming head onto a relatively moving forming surface so as to produce an air-laid web characterised in that the fibres are not subjected to any significant cross direction forces during their passage to, through and from the forming head so that a substantially uniform basis weight is maintained in the web in the cross direction throughout the forming process.
2. A method as claimed in Claim 1 in which from 1% to 10% of fibrous material is separated by the screening step.
3. A method as claimed in either Claim 1 or 2 further characterised in that the flow rate of fibres through the forming head is in the range of 5lbs./hr./sq. inch. to 1.501bs/hr./sq. inch.
4. A method as claimed in any of the preceding claims further characterised in that the nit level of the air-laid web is from 0 to 3, the basis weight being from 131bs/2880 sq. ft. to in excess of 40lbs/2880 sq. ft.
5. A method as claimed in any of the preceding claims characterised in that the air-laid web has a cross-directional coefficient of variation in the range of zero to 5%.
6. A method as claimed in any of the preceding claims further characterised in that the fibrous materials are fibres which are "opened" prior to delivery to the forming head and are delivered to the forming head suspended in an air stream in which the air-to-fibre ratio is in the range of 200 to 600 ft.3/lb., and such air-to-fibre ratio being maintained throughout the formation of the web.
7. A method as claimed in any of the preceding Claims 1 to 5 further characterised in that the dry fibrous materials delivered to the forming head are in the form of a lightly compacted feed mat having a controlled cross-directional profile.
8. A method as claimed in Claim 7 further characterised in that the fibrous materials in said lightly compacted feed mat are pre-opened adjacent the forming head and thereafter are delivered into the forming head.
9. A method as claimed in any of the preceding claims further characterised in that the fibrous materials are discharged from the forming head through a high capacity slotted screen.
10. Apparatus for forming a quality web of air-laid dry fibres on a high speed production basis comprising, a movable foraminous forming surface; at least one forming - head mounted over the forming surface; means for delivering dry fibrous materials to the forming head; means for conveying the dry fibrous materials through the forming head in a rapidly moving aerated bed of individualised fibres, soft fibre flocs, and aggregated fibre masses while maintaining the forming head substantially free of fibre grinding and disintegrating forces; means for continuously separating undesirable fibrous materials delivered to the forming head from the aerated bed and an enclosed forming zone situated between the forming head and the forming surface; means for conveying the fibrous material from the forming head through the forming zone to the forming surface in a rapidly moving : air stream and for air-laying the individualised fibres and soft fibre flocs on a movable foraminous forming surface so as to form an air-laid web of randomly oriented dry individualised fibres and-soft-fibre flocs on the surface during movement thereof wherein means are provided substantially to eliminate cross flow forces as the fibrous material passes through the apparatus so that the basis weight of the fibrous material may be maintained substantially constant in the cross direction.
11. Apparatus as claimed in Claim 10 wherein the means for moving the foraminous forming surface may be adjusted so as to select a speed so as to produce an air-laid web having a nit level of from "0" to "3" and any specific desired basis weight in lbs./2880 ft.2 ranging from at least as low as 131bs./2880 ft.2 to in excess of 401bs./2880 ft.2.
12. Apparatus as claimed in either Claim 10 or 11 wherein the forming head comprises an elongate housing having a semi-cylindrical wall portion, a full-width fibre inlet and first and second full-width discharge openings being formed in the semi-cylindrical wall portion, the first discharge opening having a semi-cylindrical slotted screen mounted therein having the same radius of curvature as the semi-cylindrical wall portion, the second discharge opening comprising a full-width tangential separator slot, means being provided for continuously introducing a high volume air stream into the housing.
13. Apparatus as claimed in any of Claims 10 to 12 wherein the means for conveying the individualised fibres and soft fibre flocs from the forming head towards the movable forming surface comprises substantially parallel, spaced, full-width upstream and downstream means for confining the air/fibre stream in the forming zone and which intersect a line tangent to the midpoint of the semi-cylindrical screen with an included acute angle in the range of 5° to 20° and which intersect the foraminous forming surface with an included angle of approximately 33°.
14. Apparatus as claimed in Claim 12 wherein the means for conveying the dry fibrous materials through the forming head in a rapidly moving aerated bed includes a rotor assembly having n (where "n" equals any whole integer greater than "I") elongate rotor bars each having a cross-sectional configuration suitable for generating a negative pressure zone in its wake during rotation of the rotor assembly and wherein the outermost surfaces of the bars are spaced inwardly from the semi-cylindrical wall portion and screen.
15. Apparatus as claimed in Claim 14 wherein the space between the outermost surfaces of the bars and the semi-cylindrical wall portion and screen is on the order of 0.10" to 0.25".
16. Apparatus as claimed in any of Claims 10 to 15 wherein the means for eliminating cross flow forces so as to maintain a controlled cross-directional mass quantum dispersion of fibres during transit of the air/fibre stream to the forming head comprises a duct having a series of spaced apart partitions extending the full-length of the duct and which separate the duct into a plurality of separate adjacent flow channels.
17. Apparatus as claimed in Claim 12 wherein a full-width classifying air jet is mounted in the semi-cylindrical wall portion upstream of the tangential separator slot for introducing a full-width classifying air stream radially into the housing so as to intersect the aerated bed of fibrous materials prior to transit of the aerated bed past the separator slot so as to divert a substantial portion of the individualised fibres and soft fibre flocs radially inward while permitting aggregated fibre masses to be centrifugally and tangentially discharged from the housing through the separator slot.
18. Apparatus as claimed in Claim 17 wherein the air defining the classifying air stream is supplied at a pressure in the range of 30" to 100" H20,
19. Apparatus as claimed in Claims 12, 17 or 18 wherein the slotted screen is oriented with the long dimensions of the screen extending longitudinally across the elongate housing,
20. Apparatus as claimed in Claim .19 wherein the short slot dimension of said slotted screen define screen openings in the range of .025 to 0.2 in width.
21. Apparatus as claimed in any of Claims 12 or 17 to 20 wherein the slotted screen has from 30% to 55% open area.
22. Apparatus as claimed in any of the preceding Claims 10 to 21 wherein the means for delivering the dry fibrous material to the forming head is such that the material is delivered in the form of a full-width lightly compacted feed mat.
23. Apparatus as claimed in any of the preceding Claims 10 to 21 wherein the means for delivering the dry fibrous material to the forming head is such that the material is delivered in the form of individual fibres separated from a full width lightly compacted feed mat, the separation occuring adjacent the forming head.
EP80304688A 1979-12-21 1980-12-22 Forming dry laid webs Expired EP0032044B1 (en)

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US10614179A 1979-12-21 1979-12-21
US10614479A 1979-12-21 1979-12-21
US10614379A 1979-12-21 1979-12-21
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WO1991005109A1 (en) * 1989-09-28 1991-04-18 Ove Ahlstrand Apparatus and method for producing a fiber material web
WO1999026496A3 (en) * 1997-11-21 1999-08-12 Reemtsma H F & Ph Biodegradable filter for cigarettes
WO2000073547A2 (en) * 1999-06-01 2000-12-07 Asselin Method for controlling the profile of a non-woven lap and related production installation

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GB2142351A (en) * 1983-06-29 1985-01-16 Copely Dev Ltd Extraction apparatus and method
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DE10153821A1 (en) 2001-11-05 2003-06-05 Hauni Maschinenbau Ag Multi-segment filter of the tobacco processing industry and method for producing the same
DE10153820A1 (en) 2001-11-05 2003-05-15 Hauni Maschinenbau Ag Filter segments or filters for cigarettes and processes for their manufacture

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Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO1991005109A1 (en) * 1989-09-28 1991-04-18 Ove Ahlstrand Apparatus and method for producing a fiber material web
WO1999026496A3 (en) * 1997-11-21 1999-08-12 Reemtsma H F & Ph Biodegradable filter for cigarettes
BG64687B1 (en) * 1997-11-21 2005-12-30 H.F. Ph. F. Reemtsma Gmbh Tobacco products filter
WO2000073547A2 (en) * 1999-06-01 2000-12-07 Asselin Method for controlling the profile of a non-woven lap and related production installation
FR2794475A1 (en) * 1999-06-01 2000-12-08 Asselin METHOD FOR CONTROLLING THE PROFILE OF A NON-WOVEN TABLECLOTH AND PRODUCTION FACILITY THEREFOR
WO2000073547A3 (en) * 1999-06-01 2002-10-17 Asselin Method for controlling the profile of a non-woven lap and related production installation
CN100390338C (en) * 1999-06-01 2008-05-28 阿斯兰迪搏 Method for controlling profile of non-woven lap and related production installation

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MX158498A (en) 1989-02-08
AU537637B2 (en) 1984-07-05

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