The present disclosure is directed to a paper mill threading system to thread a paper tail to start the paper process. More specifically, the present disclosure is directed to a web air threading system that is convertible between seating and lounging and having a minimally sized form factor.
A paper-making machine is an industrial process used in the pulp and paper industry to create large volumes of paper at high speed. Modern paper-making machines include three main sections: a wet end forming section creates a continuously moving wet mat of fiber, a wet press and/or drying section removes water from the wet mat of fiber to produce a dried paper web, and a dry-end section which may include sheet handling, calendaring, and winding steps. Within the dry-end section the calendar system thereafter consists of two or more rolls used to roll and apply pressure to the passing paper. Calenders are used to make the paper surface extra smooth and glossy, and set a uniform thickness to the paper.
Within a papermaking process the sheet being produced must be passed through the machine commonly terminating at a winding step. The wound web may then be finished or converted in subsequent unit operations after its initial production on a paper machine. Periodically, the web or sheet breaks within the papermaking process and must be rethreaded in order to reestablish winding of the full sheet. This is accomplished by cutting a small section of the sheet using a pick or water nozzle to cut a continuous, small section of the sheet, feeding this small section to the winding device, then widening the sheet to full width by indexing the pick/water nozzle in order to restore full width winding of the web.
Prior to the 1960's, the small continuous tail was often thrown by hand through the machine, usually through a series of nips, until it was finally thrown to the final winding device. Such an approach carried significant safety and operational challenges as an individual's hands were often in close proximity to the nip. Additionally, higher paper machine speeds made it increasingly difficult for a human to throw the sheet fast enough to approach the speed of the machine. Another early approach for rethreading entailed using rope runs to carry the small tail to the winding step. Again, this approach presented considerable safety issues to operators via pinch points, ingoing nips, and the risk the ropes would periodically break injuring an operator.
Various inventions were created during the 1960's and 1970's utilizing chutes with air nozzles to convey the small continuous section of sheet through sections of the machine and/or to the winding device. These inventions utilized the Coanda Effect, which asserts that air exiting a small slit or nozzle tends to follow an adjacent straight or curved surface and generates a low pressure region around itself by pulling in nearby ambient air, and thus pulls the paper web along the chute surface with the exiting air. Moreover, these inventions utilized the Bernoulli's Principle, which states that an increase in the speed of a fluid occurs simultaneously with a decrease in static pressure. Here a low pressure occurs above and around the air exiting a small slit or nozzle drawing or pulling the paper web toward the nozzle.
One prior approach of an air threading system utilizes the Coanda effect/Bernoulli principle to guide a small web section or section of paper sheet through different parts of a paper machine via nozzles and chutes. Such air threading system nozzles have included ⅛ inch tubing or larger sized pipe with an end cap and a small aperture therein are inserted proximate a sidewall of the chute and bent to exhaust compressed air in the direction of the flow of the paper web. One disadvantage or drawback to these approaches is that, these air threading systems having the continuous section of fibrous web, commonly referred to as the threading tail, fall out of one or more threading chutes before it reaches its intended target. This challenge is often made more difficult when the path to the target is not straight, such as the path around a calender stack. Another disadvantage or drawback to these approaches is that, these air threading systems pull the fibrous web into the highest velocity air causing the air stream to shred the paper web like confetti. Moreover, the task threading has been made further difficult by lighter, weaker, and structured sheets such as retail tissue, toilet paper, and towel that are more flexible and therefore more difficult to feed through the paper making process.
Therefore, it is readily apparent that there is a recognizable unmet need for a web air threading system and methods of use that may be configured to address at least some aspects of the problems discussed above common to rethreading the paper web via nozzles and chutes.
Briefly described, in an example embodiment, the present disclosure may overcome the above-mentioned disadvantages and may meet the recognized need for a web paper air threading system and methods of use, utilizing an air nozzle apparatus that includes an air orifice and a nozzle housing, said nozzle housing configured as u-shaped having a first elongated sidewall, a second elongated sidewall, and a third curved sidewall formed continuous with said first elongated sidewall and said second elongated sidewall to form a channel having an open end opposite said third curved sidewall, said air orifice positioned centered in said channel and proximate a base of said third sidewall facing said open end, wherein said first elongated sidewall, said second elongated sidewall, and said third curved sidewall are configured having an arched top surface, and, thus, functions to utilize the Coanda effect to position and convey the paper web through air threading chutes and delivering the thread tail to the final winding step.
Accordingly, in one aspect, the present disclosure utilizes compressed air to exploit the Bernoulli Theorem and Coanda effect to guide a small continuous portion of a fibrous web through sections of a papermaking process including conveyance to a winding device. The described disclosure is unique, however, in that the construction of the nozzles themselves including the geometry of the nozzle bodies, nozzle parameters, nozzle orifice geometry, and nozzle positions, are all tailored within the air threader design to amplify and optimize the Coanda effect while using less compressed air to guide a fibrous web. The combined result of these optimized parameters, thereby optimizing the Coanda effect, provides an air threading system that will hold and guide even the most delicate web tail within the guide chutes more effectively than any previous embodiments.
As described, there are three key nozzle design elements that serve to optimize the Coanda effect thereby creating a superior web air threading system compared to previous embodiments.
Accordingly, in another aspect, the present disclosure may include a threading system to guide a small continuous section of paper web through one or more threading chutes, the system includes a side wall of the one or more threading chutes, at least one nozzle body affixed to the side wall, the at least one nozzle body having a rounded top surface beginning from a leading edge positioned proximate the side wall, a trailing edge configured raised above the side wall, and at least one side extends from the trailing edge to the side wall, at least one aperture formed therethrough the at least one side, and thus, to provide a nozzle body and aperture configuration to generate an optimal Coanda effect in a chute in order to guide a small continuous section of the web paper through the guide chutes while holding the tail flat, keep it within the guide chutes during the tail feed process, prevent damage to the web as it is fed though the chutes, while using less compressed air consumption to perform the task.
Accordingly, in another aspect, the present disclosure may provide, a wide nozzle body including radiuses, angles, or slopes to form the sidewalls around the nozzle orifice, and abruptly drops off at the conclusion or end edge of the radiused or elevated surface, and is in physical contact with the side wall along all of the bottom, side, and end edges of the nozzle via side and end sections or consist of a base or bottom. By configuring the nozzle body geometry in this fashion, a wide low pressure region above and around the nozzle body is generated providing a significant low pressure zone in both size and magnitude compared to other previous embodiments utilizing a pipe, slit, aperture, or tube end.
Accordingly, in another aspect, the present disclosure of the nozzle body geometry not only assists in amplifying the Coanda effect generated by the air exiting the nozzle but is further amplified by the web traveling over and past it, as the web itself drags more air out of the exit pocket further decreasing the static pressure in the area of the nozzle orifice which in turn further assists in holding the tail within the guide chutes and proximate the side wall configured with a plurality of nozzle bodies. Moreover, the height of the nozzle body sidewalls create supports for the paper web, which provide a space or cushion between the web and the nozzle, and thus reduce or prevent tearing, snapping, or shredding of the paper web P.
Accordingly, in another aspect, the present disclosure of the nozzle orifice or aperture may be positioned as close as possible to the sidewall of the chute so as to a) increase the propensity of the air to follow the wall and b) maximize the distance between the nozzle and the high velocity air flow exiting the nozzle orifice so as to maximize the size and magnitude of the low pressure region created by the nozzle body geometry.
All together the combined nozzle architecture of the present disclosure including geometries of the nozzle body and nozzle orifice or aperture configuration and position not only amplifies the Coanda effect in the chutes, they also serve to insure the straight flow pattern through the guide chutes compared to tubing or pipes used in the vast majority of other embodiments of the device currently in use. The combined benefit of the present disclosure is its ability to hold the tail flat, keep it within the guide chutes during the tail feed process, prevent damage to the web as it is fed though the chutes, while using less compressed air consumption to perform the task.
Accordingly, in another aspect, the present disclosure may include any and all dimensional relationships, to include variations in size, material, shape, form, position, function and manner of operation, assembly and use, are intended to be encompassed by the present disclosure.
In an exemplary embodiment of the air threading apparatus may include an air orifice and a nozzle housing, the nozzle housing configured as u-shaped having a first elongated sidewall, a second elongated sidewall, and a third curved sidewall formed continuous with the first elongated sidewall and the second elongated sidewall to form a channel having an open end opposite the third curved sidewall, the air orifice positioned centered in the channel and proximate a base of the third sidewall facing the open end, wherein the first elongated sidewall, the second elongated sidewall, and the third curved sidewall are configured having an arched top surface.
In another exemplary embodiment of the air threading apparatus may include a nozzle housing, the nozzle housing configured having a plurality of u-shapes, each u-shape having a first elongated sidewall, a second elongated sidewall, and a third curved sidewall formed continuous with the first elongated sidewall and the second elongated sidewall to form a channel having an open end opposite the third curved sidewall, the each u-shape having an air orifice positioned centered in the channel and proximate a base of the third sidewall facing the open end, wherein the first elongated sidewall, the second elongated sidewall, and the third curved sidewall of the each u-shape are configured having an arched top surface.
In another exemplary embodiment of the air threading system to guide a small continuous section of web paper, may include a sidewall of an air threading chute; and a plurality of air nozzles, each the air nozzle having an air orifice and a nozzle housing, the nozzle housing configured as u-shaped having a first elongated sidewall, a second elongated sidewall, and a third curved sidewall formed continuous with the first elongated sidewall and the second elongated sidewall to form a channel having an open end opposite the third curved sidewall, the air orifice positioned centered in the channel and proximate a base of the third sidewall facing the open end, wherein the first elongated sidewall, the second elongated sidewall, and the third curved sidewall are configured having an arched top surface, the sidewall having the plurality of the air nozzles positioned linearly there along the sidewall.
In another exemplary embodiment of a method of traversing and threading a paper web, including the steps of providing a sidewall of an air threading chute, and a plurality of air nozzles, each the air nozzle having an air orifice and a nozzle housing, the nozzle housing configured as u-shaped having a first elongated sidewall, a second elongated sidewall, and a third curved sidewall formed continuous with the first elongated sidewall and the second elongated sidewall to form a channel having an open end opposite the third curved sidewall, the air orifice positioned centered in the channel and proximate a base of the third sidewall facing the open end, wherein the first elongated sidewall, the second elongated sidewall, and the third curved sidewall are configured having an arched top surface, the sidewall having the plurality of air nozzles positioned linearly there along the sidewall; rotating each the air nozzle to set a linear or optimal path for the web paper to traverse therethrough the air threading chute; and connecting each the air nozzle to a compressed air source to provide high velocity air to the air orifice.
A feature of the present disclosure may include a nozzle body that may vary in size and configuration length, width, and height, and may even span the entire width of the sidewall, top and bottom walls of the guide chute.
A feature of the present disclosure may include a nozzle orifice or aperture that may vary in size and configuration, may include considerable orifice depth therein the nozzle body, and may be positioned in a trailing side of the nozzle body valley.
A feature of the present disclosure may include a nozzle body with a smooth surface to reduce or prevent tearing, snapping, or shredding of the paper web WP.
A feature of the present disclosure may include a nozzle body with a curved or angled surface to reduce or prevent tearing, snapping, or shredding of the paper web WP.
A feature of the present disclosure may include a nozzle body with an interior height or depth therein a channel to position the nozzle orifice and its high velocity air exiting therefrom away from paper web WP to reduce or prevent tearing, snapping, or shredding of the paper web WP.
A feature of the present disclosure may include configuring a nozzle body and nozzle orifice to enhance the Bernoulli Theorem and Coanda effect.
A feature of the present disclosure may include providing a novel nozzle body configuration and aperture to generate an optimal Coanda effect in a chute to guide a small continuous section of the paper sheet through the guide chute while holding the paper sheet flat, keeping the paper sheet within the guide chutes during the tail feed process, to prevent damage to the paper sheet as it is fed though the chutes, while using less compressed air consumption to perform the task.
A feature of the present disclosure may include providing a nozzle body that may be configured in a variety of shapes and sizes provided it includes a rounded nose, sloped or curved or pointed end with adjacent rim extension arms extending therefrom the nose to form a valley therebetween the adjacent rim extension arms to create an air chute to direct compressed air escaping from an aperture positioned on the backside of the rounded nose opening up to the valley confined and directed by adjacent rim extensions arms, the aperture connected thereto compressed air source, positioned in line with airflow therethrough the guide chute, to push air flow along the back wall of the guide chute to create a low pressure area proximate, around, above nozzle body.
A feature of the present disclosure may include configuring a nozzle body that functions to be turnable or rotatable about the sidewall of the chute to optimize or manipulate the direction and velocity of the paper web WP traversing the chute and enable up and down directional airflow to assist with guide chutes changes in elevation, turns, or transitions between guide chutes during the tail feed process.
A feature of the present disclosure may include configuring a nozzle body that functions to be removable or replaceable therefrom the sidewall of the chute to perform maintenance or to reposition nozzles therein the chute.
A feature of the present disclosure may include configuring a nozzle body that functions to be connected or quick connected thereto plant air supply or connected to a plenum to receive compressed air therefrom.
A feature of the present disclosure may include configuring a nozzle body configured as angled/rounded/square/rectangular or the like to provide or offer straighter air flow therethrough one or more threading chute and therefore provide improved guidance of the threading tail versus existing nozzle bodies.
These and other features of the web air threading system and methods of use will become more apparent to one skilled in the art from the prior Summary and following Brief Description of the Drawings, Detailed Description of exemplary embodiments thereof, and Claims when read in light of the accompanying Drawings or Figures.
The present a web air threading system and methods of use will be better understood by reading the Detailed Description of the Preferred and Selected Alternate Embodiments with reference to the accompanying drawing Figures, in which like reference numerals denote similar structure and refer to like elements throughout, and in which:
It is to be noted that the drawings presented are intended solely for the purpose of illustration and that they are, therefore, neither desired nor intended to limit the disclosure to any or all of the exact details of construction shown, except insofar as they may be deemed essential to the claimed disclosure.
In describing the exemplary embodiments of the present disclosure, as illustrated in
Referring now to
Referring now to
Preferably, a cross-section of u-shaped housing 24 may be configured as an arc, arch, curved, dome shaped or other like configuration to reduce all sharp edges and surface transitions of air nozzle 20 to enable a medium, such as paper web WP to glide across its surface. Moreover, raised curved ridge housing 24 and its raised left or first sidewall 31, raised right or second sidewall 32, and raised back or third sidewall 33 relative to base 40 or air threading chute 10 may create a height differential or buffer relative to air orifice 22 to protect paper web WP from highest velocity air HVA exiting air orifice 22.
It is contemplated herein that air nozzle 20 may vary in size and configuration length, width, and height, and may even span the entire width of chute sidewall 11 of air threading chute 10. Moreover, air nozzle 20 may be configured as v-shaped, open ended square or rectangle, arcing, parabolic, rounded, semi-circle, or other like open end configuration, channel, or trough, such as channel 36 to funnel or direct air flow AF exiting air orifice 22.
It is further contemplated herein that air orifice 22 aperture may vary in size and configuration. Moreover, air orifice 22 may be configured as round, slotted, oval, square, rectangular, oblong, slit, or as a combination of smaller holes, slits, or apertures, or other like aperture configurations. Air orifice 22 may be positioned proximate base 40 or chute sidewall 11 of air threading chute 10 to project air parallel to base 40 or chute sidewall 11 of air threading chute 10 to provide or offer straighter air flow therethrough one or more threading chute and therefore provide improved guidance of paper web WP versus prior art.
Furthermore, air nozzle 20 may include connector stem 50 to mount air nozzle 20 to a plenum or conduit distributing compressed air via a compressed air system to air orifice 22 of air nozzle 20. Connector stem 50 may include first stem end 51 which may be affixed to an underside of third sidewall 33 or base 40 proximate third sidewall 33 and preferably positioned under or proximate air orifice 22. Connector stem 50 may include second stem end 52 being threaded 56 to receive or fit threaded attachment device, such as nut 60 to affix air nozzle 20 to third sidewall 33. It is contemplated herein that connector stem 50 may utilize one or more sealing gasket, such as first flexible washer 71 and second flexible washer 72. First flexible washer 71 may be utilized to air seal base 40 to one side of a plenum and second flexible washer 72 may be utilized to air seal nut 60 to another side of a plenum.
It is recognized herein that connector stem 50 may include a passageway, such as connector aperture 58 positioned therein connector stem 50. Connector aperture 58 may be connected to air orifice 22 via conduit 59 (having a first conduit end and a second conduit end) traversing or formed therein connector stem 50. Conduit 59 having a first conduit end and a second conduit end connects compressed air CA (via a compressed air system) entering connector aperture 58, traversing conduit 59 to discharge therefrom air orifice 22.
Referring again to
It is contemplated herein that air nozzle 20 may not include raised left or first sidewall 31, raised right or second sidewall 32 and end with curved sidewall 33, wherein top surface 38 of curved sidewall 33 may also be configured as slanted, angled, rounded, sloped, arc, curved, dome shaped or other like configuration to reduce all sharp edges and surface transitions of air nozzle 120 to enable a medium, such as paper web P to glide across its leading edge surface.
Moreover, in use upstream and current air nozzle 20/20B upstream high velocity air U-HVA (from an upstream air nozzle 20/20B) and high velocity air HVA (from current air nozzle 20/20B) linearly propel or carry paper web WP along a series of air nozzles 20/20B. Leading edge high velocity air L-HVA may be deflected upward from a plane parallel to base 40 by smooth arcing third sidewall 33 to lift paper web WP above and away from high velocity air HVA exiting air orifice 22. The pulling effect of air currents seeking low pressure ASLP of low pressure pocket LPP on paper web WP due to the Coanda effect/Bernoulli principle of air nozzle 20/20B pulls deflected leading edge high velocity air L-HVA and paper web WP close to or proximate a plane parallel to the top surface of raised curved ridge housings 24 of air nozzle 20/20B. Furthermore, the pulling effect of air currents seeking low pressure ASLP of low pressure pocket LPP on paper web WP due to the Coanda effect/Bernoulli principle of air nozzle 20/20B pulls trailing edge high velocity air T-HVA and paper web WP close to or proximate a plane parallel to base 40. High velocity air HVA from air nozzle 20/20B propels paper web WP to the next downstream air nozzle 20/20B to repeat and further linearly propel or carry paper web WP along a series of air nozzles 20/20B.
Referring now to
It is contemplated herein that air nozzle 120 may vary in size and configuration length, width, and height, number of orifices 22 and channels 36, and may even span the entire width of chute sidewall 11 of air threading chute 10. Moreover, air nozzle 120 may be configured as v-shaped, open ended square or rectangle, arcing, parabolic, semi-circle, or other like open end configuration, channel, or trough, such as channel 36 to funnel or direct air flow AF exiting air orifice 22.
It is further contemplated herein that air orifice 22 apertures may vary in size and configuration. Moreover, air orifice 22 may be configured as round, slotted, oval, square, rectangular, oblong, or as a combination of smaller holes or apertures, or other like aperture configurations. Air orifice 22 may be positioned proximate base 40 or chute sidewall 11 of air threading chute 10 to project air parallel to base 40 or chute sidewall 11 of air threading chute 10.
Furthermore, air nozzle 120 may include one or more connector stem 50 to mount air nozzle 20 to a plenum or conduit distributing compressed air to air orifice 22 of air nozzle 120. Connector stem 50 may include first stem end 51 which may be affixed to base 40 proximate third sidewall 33 end and preferably positioned under or proximate air orifice 22. Connector stem 50 may include second stem end 52 being threaded 56 to receive threaded attachment device, such as nut 60. It is contemplated herein that connector stem 50 may utilize one or more sealing gasket, such as first flexible washer 71 and second flexible washer 72. First flexible washer 71 may be utilized to air seal base 40 to one side of a plenum and second flexible washer 72 may be utilized to air seal nut 60 to another side of a plenum.
It is recognized herein that connector stem 50 may include a passageway, such as connector aperture 58 positioned proximate first stem end 51 of connector stem 50. Connector aperture 58 may be connected to air orifice 22 via conduit 59 traversing connector stem 50 from connector aperture through first stem end 51 to air orifice 22. Conduit 59 connects compressed air CA entering connector aperture 58, traversing conduit 59 to discharge therefrom air orifice 22.
Referring again to
Referring now to
Referring again to
It is contemplated herein that compressed air CA may be controlled individually via tubing connected to connector stem 50 by control of compressed air CA or together within a section of air threading chute 10, 410 via control of compressed air CA in plenum 420.
Referring now to
A cross section of
It is contemplated herein that compressed air CA may be controlled individually via tubing connected to connector stem 50 and control of compressed air CA or together within a section of air threading chute 10, 510 via control of compressed air CA in plenum 420.
It is contemplated herein that air nozzles 20/120 components may be constructed of stainless steel, aluminum, or the like materials and of different dimensions. This and other materials herein may be constructed of metal, steel, alloy, or plastic or more specifically high density polyethylene or similar high tensile or strengthened materials, as these material offers a variety of forms and shapes and provide strength with reduced weight; however, other suitable materials or the like, can be utilized, provided such material has sufficient strength and/or durability as would meet the purpose described herein to enable air nozzles 20/120 to discharge high velocity air HVA to float or carry paper web WP therein air threading chute 10/510.
It is contemplated herein that air nozzles 20/120 may be positioned anywhere on backside 412/512, chute top side 413/513, and chute bottom side 411/511 top, bottom, middle or other position of side or cover the whole side.
It is understood herein that various changes in the material used, shape, size, arrangement of parts, and parts are connected with bolts, pins, screws or similar fasteners or other rotating devices without departing from the spirit of the scope of the claims herein.
It is further understood herein that the parts and elements of this disclosure may be located or position elsewhere based on one of ordinary skill in the art without deviating from the present disclosure.
Referring now to
With respect to the above description then, it is to be realized that the optimum dimensional relationships, to include variations in size, materials, shape, form, position, movement mechanisms, function and manner of operation, assembly and use, are intended to be encompassed by the present disclosure.
The foregoing description and drawings comprise illustrative embodiments. Having thus described exemplary embodiments, it should be noted by those skilled in the art that the within disclosures are exemplary only, and that various other alternatives, adaptations, and modifications may be made within the scope of the present disclosure. Merely listing or numbering the steps of a method in a certain order does not constitute any limitation on the order of the steps of that method. Many modifications and other embodiments will come to mind to one skilled in the art to which this disclosure pertains having the benefit of the teachings presented in the foregoing descriptions and the associated drawings. Although specific terms may be employed herein, they are used in a generic and descriptive sense only and not for purposes of limitation. Moreover, the present disclosure has been described in detail, it should be understood that various changes, substitutions and alterations can be made thereto without departing from the spirit and scope of the disclosure as defined by the appended claims. Accordingly, the present disclosure is not limited to the specific embodiments illustrated herein but is limited only by the following claims.
To the full extent permitted by law, the present United States Non-provisional Patent Application hereby claims priority to and the full benefit of, U.S. Provisional Application No. 63/012,801, filed on Apr. 20, 2020, entitled “ADVANCED WEB AIR THREADING SYSTEM WITH NOZZLE AND SHAPEABLE SUBSTRATE TO PROVIDE AN EXTENSION”, which is incorporated by reference herein in its entirety.
Number | Date | Country | |
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63012801 | Apr 2020 | US |