The invention relates to papermaking machinery and methods. The invention relates more particularly to the manufacture of creped tissue paper.
In the production of tissue for use in personal hygiene products and the like, it is desired to produce a tissue with good tactile qualities (i.e., soft to the touch) while also achieving a high machine speed and efficiency. The speed and efficiency are often limited by the performance of the dry end of the machine between the final dryer and the winding station or reel-up. Tissue is extremely delicate and difficult to handle, especially at high machine speeds. Generally, improving the tactile qualities of tissue has been achieved by reducing the basis weight and the tensile strength of the web. Lower tensile strength translates into improved softness. Unfortunately, the reductions in basis weight and tensile strength have made it more difficult to achieve high machine speeds because of the difficulty of handling and controlling the weak web in the dry end from the creping doctor to the reel-up.
It would be desirable to provide a method of making a creped tissue paper providing improved tactile qualities while improving the handling and control of the web in the dry end.
The above needs are met and other advantages are achieved by the present invention, which provides a method and apparatus for making a creped tissue that leads to improved tactile qualities of the paper and also facilitates handling and control of the web in the dry end. An apparatus in accordance with the invention comprises a heated drying cylinder on which a tissue paper is dried, a creping doctor for creping the tissue paper from the drying cylinder so as to form a creped tissue paper, at least one carrying fabric spaced downstream of the creping doctor and forming an endless loop about a plurality of guide rolls, a web support extending from proximate the creping doctor to the carrying fabric and supporting and carrying the creped tissue paper thereon, and a reel-up for winding the creped tissue paper onto a building paper roll in the reel-up, the carrying fabric being urged against the building paper roll so as to wind the web thereon.
In some embodiments of the invention, the apparatus includes at least one compression device for compressing the web on the carrying fabric such that the web is substantially reduced in thickness and is improved in surface softness.
A method in accordance with the invention includes steps of creping a tissue paper from a heated drying cylinder, using a web support to guide the web from the creping doctor onto a carrying fabric, carrying the web on the carrying fabric up to the reel-up, and winding the web onto a building paper roll in the reel-up.
In some method embodiments of the invention, there is a further step of transporting the web on the carrying fabric through a compression device where the creped web is compressed to substantially reduce its thickness and improve its surface softness.
In some embodiments of the invention, the carrying fabric and web pass through a compression nip formed between two opposed rolls; optionally, the web can be sandwiched between the carrying fabric and another fabric when it passes through the compression nip. In other embodiments, a first carrying fabric supporting the web forms a nip with a first roll arranged to contact one side of the web to perform a one-sided calendering of the web. The web is then transferred from the first carrying fabric onto a second carrying fabric that forms a nip with a second roll arranged to contact the opposite side of the web to perform calendering on the opposite side of the web.
The compression of the creped web has been found to significantly improve the tactile quality of creped tissue, and in particular gives the tissue a silky feel. By guiding the tissue paper on the web support and then carrying the web on the supporting fabric all the way from the creping doctor to the reel-up, the stability problems associated with open draws are avoided, and the resulting improved web handling ability facilitates high machine speeds.
The compression roll(s) can be room temperature or heated. Preferably, the (or each) carrying fabric is permeable and one or more suction devices (e.g., blow boxes) are arranged within the loop of the/each carrying fabric.
In some embodiments, the web support that guides the web from the creping doctor onto the carrying fabric comprises an air foil. Preferably, the air foil is an active air foil. In other embodiments, the web support comprises another fabric. The other fabric preferably is permeable and a suction device preferably is disposed within the loop of the fabric to ensure that the web adheres to the fabric. The other fabric can pass through the compression nip such that, as previously noted, the web is sandwiched between the two fabrics when it passes through the nip; alternatively, the two fabrics can be arranged in sequence such that the web is transferred from one to another, and each fabric can form a compression nip with a roll as previously noted.
The peripheral speed of the paper roll in the reel-up preferably is greater than the speed of the carrying fabric that carries the web to the reel-up, so that slack in the web is avoided during the reeling.
When a compression roll contacts the web on a carrying fabric, the roll preferably is operated at a peripheral speed less than the speed of the fabric. In this manner, the roll creates slack in the web upstream of the roll and reduces slack in the web downstream of the roll.
The above and other objects, features, and advantages of the invention will become more apparent from the following description of certain preferred embodiments thereof, when taken in conjunction with the accompanying drawings in which:
The present invention now will be described more fully hereinafter with reference to the accompanying drawings, in which preferred embodiments of the invention are shown. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. Like numbers refer to like elements throughout.
The air foil 24 guides the creped tissue paper onto a traveling carrying fabric 26 that forms an endless loop about a plurality of guide rolls 28 and about a reeling drum 30 at a downstream end of the fabric loop. In the illustrated embodiment, the carrying fabric 26 is a permeable fabric. The fabric can be woven or non-woven, and can be made of various materials including composite material or metal (including a rolled sheet).
To ensure that the tissue paper remains adhered to the carrying fabric 26, one or more vacuum devices preferably are arranged within the loop of the carrying fabric 26 for exerting suction through the fabric on the web. Thus, a vacuum device 40 is disposed against the inward-facing surface of the carrying fabric 26 just downstream of the air foil 24, a second vacuum device 41 is disposed downstream of the first vacuum device, and a third vacuum device 42 is disposed just upstream of the reeling drum 30. The vacuum devices can be vacuum boxes or any other device that creates an underpressure, such as a device marketed by Metso Corporation under the trademark BLOWBOX, which creates an underpressure by blowing air to induce a Coanda effect.
The carrying fabric 26, as noted, loops about a reeling drum 30 for the reel-up. The reeling drum 30 with the fabric 26 looped thereabout forms a reeling nip with a building paper roll 44 wound on a reel spool (not shown) in the reel-up. Thus, the fabric 26 guides the creped and compressed tissue paper onto the building paper roll 44.
The carrying fabric, in this embodiment as well as subsequently described embodiments, preferably is a substantially smooth-surfaced fabric, by which is meant that the fabric surface that contacts the web does not create any embossed structure in the web for increasing an effective thickness of the web when the fabric is pressed against the paper roll 44 to wind the web onto the roll. To the contrary, the pressing of the web in the nip between the fabric and paper roll can result in a very slight reduction in web thickness. Further thickness reduction can be accomplished, if desired, by the addition of a compression device, as described below in connection with further embodiments of the invention.
As noted, in some embodiments of the invention, the web after creping and prior to reeling is subjected to at least one compression operation to substantially reduce the caliper of the web. Thus, in the embodiment of
Although a pair of rolls are illustrated for forming the compression device, it is also possible to use a press member and a roll forming an extended nip therebetween. For example, the press member can be a shoe roll or the like.
Preferably, the web thickness is reduced by about 20 to 50 percent by the compression device. The compression of the creped tissue paper substantially improves the tactile quality of the tissue, and in particular gives the tissue a silky surface texture. The tissue paper as reeled in the reel-up preferably has a basis weight of about 9 to 25 pounds per 3000 ft2, a caliper of about 0.004 to 0.028 inch, a machine-direction (MD) tensile strength of about 150 to 800 g/in, and a cross-direction (CD) tensile strength of about 100 to 700 g/in.
The creped tissue paper, as shown, can be carried through the compression device while sandwiched between two fabrics. Thus, the dry end includes a second fabric 36 that forms an endless loop about the press roll 34 and about a plurality of guide rolls 38. The guide roll 38 at the downstream end of the second fabric loop is located upstream of the reeling drum 30. The second fabric 36 is permeable. The vacuum device 42 within the loop of the fabric 26 is located relative to the downstream guide roll 38 of the second fabric 36 so that the web is caused to follow the fabric 26 rather than the second fabric 36 when the two fabrics diverge.
The eighth embodiment of
The tactile quality imparted to the creped tissue in the compression nip(s) depends on various factors, including the surface characteristics of the fabric(s) in contact with the web through the nip(s), the linear nip load exerted in the nip(s), whether heating is carried out in the nip(s), and other factors.
The thickness of the web preferably is reduced by a substantial amount (e.g., 20 to 50 percent) as a result of the compression of the web in the compression nip(s). A consequence of the thickness reduction is a lengthening of the web in the machine direction, which creates slack in the web on the belt downstream of the nip. To avoid winding difficulties in the reel-up, the peripheral speed of the paper roll 44 preferably should exceed the speed of the belt 26 (which is equal to the peripheral speed of the reeling drum 30 in those embodiments employing a reeling drum) so that slack is removed from the web before the web is wound onto the paper roll. For instance, the peripheral speed of the paper roll 44 advantageously should be about 0–10% higher than the speed of the belt 26.
When the web is sandwiched between two belts (e.g., 26 and 36, or 26 and 46) and passed between two rolls (32 and 34), the two belts advantageously have the same speed, which is less than the peripheral speed of the paper roll 44 as noted above.
In contrast, when the web is subjected to a one-sided calendering in a belt calender formed between a roll and a belt (e.g., between roll 34 and belt 26, or between roll 32 and belt 46), it is believed to be beneficial for the peripheral speed of the roll to be less than the speed of the belt. In particular, it is believed such a speed relationship between the roll and belt improves tactile qualities of the web, reduces slack in the web downstream of the roll (and correspondingly creates slack upstream of the roll), and improves runnability of the web. For instance, the peripheral speed of the roll advantageously should be about 0–20% less than the speed of the belt.
The invention enables improved softness or silkiness of a creped tissue while at the same time facilitating handling of the tissue paper so that increased machine speeds are attainable. Additionally, compressing of the web enables paper rolls in the reel-up to be wound more densely (i.e., more paper for a given diameter of roll) and reduces the tendency toward telescoping and other roll defects.
The linear nip load in the reel-up preferably is relatively low, and desirably is about 100 to 250 N/m.
Many modifications and other embodiments of the invention will come to mind to one skilled in the art to which this invention pertains having the benefit of the teachings presented in the foregoing descriptions and the associated drawings. As an example, other types of compression devices than those shown can be used. For instance, it is possible to compress the web between two fabrics that each have portions stretched between spaced guide rolls and in contact with each other, whereby tension in the fabrics urges the fabrics against each other to press the web therebetween. Therefore, it is to be understood that the invention is not to be limited to the specific embodiments disclosed and that modifications and other embodiments are intended to be included within the scope of the appended claims. Although specific terms are employed herein, they are used in a generic and descriptive sense only and not for purposes of limitation.
This application is a divisional of U.S. application Ser. No. 10/375,824, filed Feb. 26, 2003 now U.S. Pat. No. 6,797,115, which is incorporated herein by reference and which claims the benefit of the filing date of U.S. Provisional Patent Application Ser. No. 60/369,018, filed Mar. 29, 2002, the disclosure of which is incorporated herein by reference.
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Number | Date | Country | |
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Parent | 10375824 | Feb 2003 | US |
Child | 10901486 | US |