The present invention generally relates to non-woven media and methods of producing the same. More particularly, the invention relates to an apparatus and method for mixing fibers. Specifically, the present invention relates to delivering first and second fibers into a fluid medium to form a slurry, and introducing an agitating fluid into the slurry to mix the fibers.
Fiber mixtures are often used to form filter media and other non-woven media. In the formation of these media, fibers are mixed in a variety of ways. The fibers may be dry mixed in air, or other gas, or wet mixed in water, or other liquid. One common difficulty with dry mixing is the build up of a static charge that prevents the fibers from mingling. While the build up of static charge is less problematic in wet mixing this type of mixing has its own hurdles. In wet mixing, the fibers may gather at the surface forming a membrane that floats on the surface with out mixing at depth with fibers contained in the liquid below. The use of electrospun or other fibers that are quenched upon contact with the liquid exacerbates this problem because, as the fibers are quenched at the surface, they form a single tangled membrane. This membrane does not separate to mix with the other fibers.
To force mixing, attempts have been made to agitate the fiber containing slurry with mechanical elements such as an impeller. While this technique provides some relief by drawing the fibers downward within the slurry, the fibers unfortunately wrap themselves around the impeller and its shaft. With the fibers ensorceling the impeller, these fibers are not free to intermingle with the fibers in the surrounding liquid. Similar to the use of an impeller, introducing elements through the surface of the slurry is known to cause the fibers to wrap themselves around these elements. The central problem in each situation is the agglomeration of fibers preventing the mixing of two types of fibers to any depth. In other words, the short fibers are found at the surface of the resultant long fiber membrane without penetration into the matrix of long fibers.
It is thus an object of the present invention to provide an improved method of mixing fibers.
It is another object of the present invention to provide a method of mixing long and short fibers that improves penetration of short fibers within a long fiber matrix.
Generally, the present invention provides a method of mixing and its resultant article, where the method includes providing a slurry having a first fiber into a container, introducing an agitation fluid into the slurry to cause a mixing motion within the slurry; and delivering a second fiber into the slurry, whereby the mixing motion mixes the first and second fibers to create a fiber mixture.
The present invention provides a fiber-mixing apparatus including a container receiving a slurry having short fibers therein, a fluid delivery assembly in fluid communication with the container and a fluid supply, whereby said fluid delivery assembly delivers an agitation fluid into the slurry, and delivery assembly delivering long fibers into the slurry, whereby delivery of said agitation fluid causes mixing of the long fibers and short fibers.
The present invention still further provides a multi-fiber structure including a mixture of first fibers and second fibers forming a fiber matrix, where at least a portion of the first fibers penetrate the matrix.
At least one or more of the foregoing objects of the present invention, as well as the advantages thereof over existing prior art forms, which will become apparent from the description to follow, are accomplished by the improvements hereinafter described and claimed.
In a fiber-mixing process, according to the present invention, a first fiber is provided in a fluid to form a slurry, which is provided in a suitable container. A mixing motion is imparted to the slurry by a current generation assembly. Second fibers are provided into the slurry and the rolling motion of the slurry mixes the first and second fibers together. The resulting mixture has first fibers penetrating the matrix of second fibers or otherwise being dispersed within and throughout the resulting mixed fiber media. Since it is believed that the method and apparatus described herein could be used with fibers of any size, type, or relative length, the fibers will be referred to generally as fibers or, when referring to differing fibers, a first fiber and a second fiber. It will be understood that more than two fibers may be mixed and reference to first and second fibers does not limit the invention to a maximum of two fibers. It is believed that the invention may be used to mix any number of fibers.
When using two of more fibers of different relative lengths, the shorter fiber may have a length limited only by its ability to disperse within the slurry fluid. For example, fibers of about one millimeter or less may be used. Other suitable short fibers could fall within the range of about one micron to about ten microns in length. A long fiber, in such a case, would be longer in length than the short fibers. A fiber may be considered a long fiber when it is greater than one millimeter in length. The length of a long fiber could be, in the case of polymeric nanofibers, on the order of kilometers. It is believed that fibers having varying lengths may be used in the slurry and blends of long and short fibers may be used as long as they are able to disperse. This may largely depend on the volume of liquid in the slurry. As will be appreciated, the size of the container and other related apparatus components may be modified to accommodate virtually any fiber.
The above description of fibers is generally provided for background purposes. The apparatus described below is believed to be capable of mixing virtually any long and short fiber combinations. Further, the below described apparatus is capable of receiving manufactured, synthetic, and natural fibers. It will be understood that to accommodate different fibers, it may be necessary to vary the operating conditions of the apparatus. For example, the density, PH, temperature, pressure or other operating conditions of the process may be altered, as necessary. If desirable, the fibers may be treated by mechanical, electrical, or chemical means prior to mixing.
To perform mixing, the present invention includes a mixing apparatus referred to generally by the numeral 10 in the Figures. In general, the fiber-mixing apparatus 10 includes a container 20, a current generating assembly generally referred to by the numeral 30: and a fiber delivery assembly 40.
Container 20 may be of any shape, size, or configuration, and, thus, will be described in general terms. Container 20 has a floor 21 and at least one side wall 22 extending upwardly from floor 21 to define a cavity 23, in which a fluid 27 may be received. As best shown in
For the mixing process, a slurry 26 including a fluid 27 and a plurality of fibers 14 is received in container 20. As previously described, the particular fluid 27 may depend on the fibers being used in the mixture. As will be understood from the term fluid, fluid 27 may be liquid or gas with attention being paid to the ability of the particular fluid to disperse the fibers. In one representative embodiment, fluid 27 was water and glass fibers 14 were used.
The current generating assembly 30 is used to create a mixing motion within the container 20. As best shown in
In one representative current generating assembly, depicted in
It will be readily appreciated that other or additional current generating assemblies 30 may be used to generate a mixing motion within container 20. In its most basic form, the current generating assembly 30 is an opening through which the agitation fluid 31 enters the slurry 26. The current generating assembly may incorporate multiple openings randomly scattered or arranged in patterns along the inside surface of the container 20. To achieve different flow characteristics for the agitation fluid 31, the current generating assembly 30 may incorporate a nozzle. Also, other implements similar to the wand 35 may be placed into or inserted through the container 20 to the same effect.
The second fibers 16 are delivered into the container 20 in any known manner, including blowing, gravity feed, fluid jet, or electrospinning. As shown in
Since the second electrode 43 must electrically contact the slurry 26, there is a possibility that protrusion of the electrode into the slurry 26, such as when the electrode is passed through the surface 32 of the slurry 26, might cause the fiber 16, while being agitated, to wrap itself around or otherwise become entangled with the intruding electrode. Since the effects of such placement of the electrode may be minimal this method of contacting the slurry 26 should not be ruled out. To avoid passing the first electrode 42 through the surface 32, the first electrode 42 may contact the slurry 26 below its surface 32. In this instance, a sealed orifice 44 could be used to further minimize any risk of entanglement caused by the protrusion of the electrode 42 in the slurry 26.
In operation, first fibers 14 are provided in fluid medium 27 to form slurry 26. The slurry 26 is held within container 20. To aid in the attachment of fibers 14, 16, the slurry 26 may further comprise a suitable binder, a number of suitable binders are commercially available, such as, Carboset 560 from B. F. Goodrich. Agitation fluid 31 is provided from a supply to the current generating assembly 30, creating a mixing motion within the slurry 26. Second fibers 16 are delivered into the slurry 26 by fiber delivery assembly 40. When using the electrospinning technique, a power supply connected to the first and second electrodes 42, 43 is turned on and a bead of polymer is formed near the second electrode 43. The electrical forces between the electrodes 42, 43 eject second fiber 16 from the bead over the mixing apparatus 10, as previously described.
As the second fibers 16 fall onto the surface 32 of slurry 26, they are acted upon by the motion of the slurry 26 and drawn within the slurry 26 to mix with the first fibers 14. As the second fibers 16 fall onto the surface 32 of slurry 26, they are acted upon by the motion of the slurry 26 and drawn within the slurry 26 to mix with the first fibers 14. Since no mechanical elements attract the second fibers 16 and the mixing motion prevents the second fibers from agglomerating at the surface 32, the apparatus 10 forms a relatively uniform mixture of both fibers 14, 16 throughout the depth of the slurry 26. Like the slurry 26, any resulting multi-fiber structures made from the fiber mixture would exhibit the second fibers 16 having first fibers 14 located within the second fiber matrix. Photomicrographs of such multi-fiber structures, in this case a filter cake, are shown in
Floor 121 may be provided with an outlet 125 for draining the slurry 126. In the embodiment shown, outlet 125 is formed centrally within the floor 121, but may be located at any convenient point on the container 120. The floor 121 is sloped in the direction of the outlet 125 to facilitate drainage.
A splash shield 128 may be formed at the top of container 120. In the embodiment shown, shield 128 is made integral extending upwardly and inwardly from side wall 122 in an arcuate fashion. It will be appreciated that the shield 128 may take on other forms, such as an angular extension, or a separate shield 128 may be fastened or removably attached to the container 120. As shown, the shield 128 extends upwardly from the wall 122 of container 120. An opening 129 is formed centrally within shield 128 permitting access to the open end of container 120.
A current assembly 130 is provided to agitate slurry 126 as it rests in container 120. In contrast to the wand 35 of assembly 30, current assembly 130 generally includes a plurality of openings 136 located substantially at the perimeter 124 of floor 121. Openings 136 may be formed in floor 121 and spaced about the perimeter 124 thereof. In the embodiment shown, the openings 136 are radially spaced proximate the side wall 122.
Openings 136 introduce agitation fluid into the container 120 directing the agitation fluid upwardly from floor 121. Openings 136 receive the agitation fluid from a suitable supply. The agitation fluid may be channeled separately to each openings 136 or delivered to all of the openings 136 through a manifold. The agitation fluid 138 is delivered with sufficient pressure to develop a current 138 within slurry 126. This current 138 sets up a mixing motion and is used to mix the first and second fibers 114, 116, as described more completely below.
In the embodiment depicted in
As described previously, second fiber 116 are generally provided into the container 120 by a fiber dispensing assembly 140. Any number of appropriate fiber dispensing assemblies 140 are available in the art and including devices which blow fibers, drop fibers, or electrospin fibers. Therefore, the fiber dispensing assembly 140 is depicted schematically and referred to generally.
Once the fibers 114, 116 are mixed, formation of a multi-fiber structure may be carried out by a suitable forming assembly. One such assembly, generally referred to by the numeral 150, is shown in
As shown in
In still another embodiment in the
As will be readily appreciated, this process and apparatus for mixing fibers has wide application and may be used in paper-forming, mat-forming, filter-forming, membrane-forming processes, and other multi-fiber structure-forming processes. It is believed that any type of fibers may be used. The delivery of an agitation fluid provides a robust mixing force and can easily be modified in terms of the fluid itself or the delivery pressure to accommodate an infinite variety of fibers. If necessary, other process variables specific to certain fibers may be readily adjusted, as will be recognized by one of ordinary skill, to accommodate these fibers. For example, the pH level of the fluid making up the slurry may be adjusted to prevent the first fibers from clumping therein.
An experiment was performed using the above described apparatus to form a fiber cake useful in filtering applications. The following description of this experiment is provided for purposes of example and to aid the reader in understanding the utility and use of the apparatus. This discussion should not be read to limit the invention to the particulars contained herein. The experiment was initially conducted to observe the performance of simple glass filters in comparison to a filter containing a mixture of glass fibers and nanofiber. Filters found in the art typically contained only glass fibers and it was thought that mixing these fibers with a nanofiber could improve the performance of such filters. To form a glass and nanofiber mixture, an apparatus, similar to the one depicted in
The filtration capability of the cakes were tested by examining the outlet concentration of the cakes over time. Plots of the Mix 1 and Mix 2 cakes, shown in
Thus, it can be seen that the objects of the invention have been satisfied by the structure and its method for use presented above. While in accordance with the Patent Statutes, only the best mode and preferred embodiment has been presented and described in detail, it is to be understood that the invention is not limited thereto or thereby.
Accordingly, for an appreciation of true scope and breadth of the invention, reference should be made to the following claims.
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/US01/07594 | 3/9/2001 | WO | 00 | 11/18/2002 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO01/68228 | 9/20/2001 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
1872548 | Lowen | Aug 1932 | A |
2605084 | Reents et al. | Jul 1952 | A |
3039914 | Reiman | Jun 1962 | A |
3081239 | Clauss et al. | Mar 1963 | A |
3175807 | Gouveia | Mar 1965 | A |
3577312 | Videen et al. | May 1971 | A |
3754417 | Jamieson | Aug 1973 | A |
3773301 | Bergeron | Nov 1973 | A |
3998690 | Lyness et al. | Dec 1976 | A |
4112174 | Hannes et al. | Sep 1978 | A |
4196027 | Walker et al. | Apr 1980 | A |
4215682 | Kubik et al. | Aug 1980 | A |
4260265 | Faverty et al. | Apr 1981 | A |
4293378 | Klein | Oct 1981 | A |
4303472 | Walker et al. | Dec 1981 | A |
4335965 | Faverty et al. | Jun 1982 | A |
4523995 | Pall et al. | Jun 1985 | A |
4944598 | Steele | Jul 1990 | A |
5118942 | Hamade | Jun 1992 | A |
5607491 | Jackson et al. | Mar 1997 | A |
5728298 | Hamlin | Mar 1998 | A |
5871845 | Dahringer et al. | Feb 1999 | A |
5876537 | Hill et al. | Mar 1999 | A |
5877099 | Cohen | Mar 1999 | A |
5906743 | Cohen et al. | May 1999 | A |
5985112 | Fischer | Nov 1999 | A |
Number | Date | Country | |
---|---|---|---|
20030210606 A1 | Nov 2003 | US |