Patent Grant
7627933
Embodiments of the invention relate to forming heads used in manufacturing non-woven materials.
In a typical dry-laid process, fiber material is supplied to an enclosed space (sometimes called a forming box or head) through an air stream. The fiber material is mixed and opened (separated into individual fibers) inside the forming head by means of pin-wheels, agitators, and the like. In many instances, the fiber is then passed through some type of screen before being deposited onto a belt (sometimes called a forming wire), through which a vacuum or suction is usually applied to form a sheet or web of fiber material. The intended use of such a screen is to prevent the passage of unopened lumps of fiber. Unfortunately, a screen also impedes the flow of fiber, thereby requiring considerably more vacuum or suction air than is used with a forming head without a screen. The use of a screen is also disadvantageous because it reduces the productive through-put of a forming head, particularly as attempts are made to process fiber of greater length.
In addition to problems caused by screens, current processes for forming non-woven materials are not completely satisfactory for other reasons. In many known systems, circular air ducts are used to transport fiber to forming heads. Large volumes of air are required to transport fibers to a forming head in an air stream within such ducting. The circular ducting is sometimes transitioned to rectangular ducting before the air stream reaches the forming head. These transitions are intended to act as flow-spreaders but do not achieve a thoroughly uniform distribution of fiber. The use of other devices such as spouts and nozzles in the fiber-delivery air stream also fail to ensure an even distribution of fiber across the entire width of a forming head. Non-uniform fiber distribution can degrade the uniformity of the produced web, especially cross directionally (across the width of the forming head). Other problems in forming heads are caused, at least in part, by air turbulence, which is introduced as a result of the air stream required to transport fiber to the forming head. This turbulence creates uneven and unpredictable distributions of fiber within the forming head. The large volume of air used to transport fibers may also tend to force fibers through the forming box before they have been sufficiently opened.
Problems with non-uniform fiber distribution are especially problematic when a forming head has no screen, which by impeding the flow of fiber also limits somewhat the extent to which the produced web is affected by the uniformity of the fiber delivery method. Accordingly, there is a need for improved devices and techniques for forming sheets or webs of fiber material with improved uniformity, without the reduced throughput and fiber length limitations resulting from the use of a physical screen barrier.
In one embodiment, the invention provides a device for depositing fibers onto a forming wire or surface located outside of the device (one or more external forming surfaces may be used). The embodiment includes a fiber reservoir having an inlet configured to accept a supply of fiber, possibly in a stream of air or gas (hereafter referred to simply as “air”), a first outlet configured to pass air, and a second outlet configured to pass fiber. (The method of fiber delivery to the reservoir could instead be performed by a belt conveyor or other manner). The embodiment also includes one or more rolls or other devices used to deliver a metered flow of fiber out of the reservoir into a forming head via a mechanical action that is substantially independent of any air stream. The configuration used to deliver fiber from a reservoir to a forming head is hereafter referred to simply as a “fiber meter.” A forming head is positioned to receive fiber from the fiber reservoir and includes one or more agitators and one or more air inlets. The forming head is configured to interface with a vacuum source that is used to draw air into the forming head through the one or more air inlets. The one or more air inlets are configured to affect the volume and velocity of air drawn into the forming head, and to thereby affect the flow of fiber through the machine and the action on the fiber by the agitators.
The fiber meter can be configured to deliver a curtain of fiber along substantially the entire width of the forming head. This can be accomplished by ensuring that the width of the forming head, the reservoir, and the fiber meter are substantially the same.
Another embodiment of the invention provides a device for blending and opening fibers. The embodiment includes a first fiber reservoir having an inlet and at least one outlet through which fiber is passed; a first fiber meter positioned adjacent to the at least one outlet of the first fiber reservoir; a second fiber reservoir having an inlet and at least one outlet, the second fiber reservoir positioned adjacent to the first fiber reservoir; and a second fiber meter positioned adjacent to the at least one outlet of the second fiber reservoir. More configurations of fiber reservoirs and meters may be included in the same manner as the first and second described above. A forming head is positioned to receive fiber from the fiber reservoirs. The forming head includes a first retention section; a first angled side wall and a second angled side wall; a funnel section positioned below the first retention section and between the first and second angled side walls; a second retention section positioned below the funnel section; a distribution section positioned below the second retention section; and an outlet or bottom positioned below the distribution section. The bottom is configured to interface with a vacuum source such that an air stream flows from a source (that is substantially independent of any air stream used to provide fibers to the fiber reservoirs) toward the outlet of the forming head.
Another embodiment provides a method of depositing fibers on an external forming wire or wires. The method includes delivering fiber to a fiber reservoir via an air stream; passing air out of the fiber reservoir such that fiber accumulates in the reservoir; moving fiber out of the fiber reservoir substantially via a mechanical action; opening fiber from the reservoir with one or more agitators in a chamber; and applying a vacuum to the chamber to draw air into the chamber. The method also includes affecting the volume and velocity of the air using one or more air inlets in the chamber; and depositing fibers on a forming wire located outside of the chamber.
Other embodiments of the invention will become apparent by consideration of the detailed description and accompanying drawings.
Before any embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting.
The second fiber reservoir 28 is similar to the first fiber reservoir. The second fiber reservoir 28 includes an inlet 50 and an air vent 52. A second raw material, which is generally but not always different from the first raw material, is provided from an external source to the reservoir 28 via an air stream 54. Fibers such as bi-component or binder fibers may be used as the second raw material. The air stream 54 follows a path P2 from the inlet 50 to the vent 52. The vent 52 holds a filter, screen, or similar device 60 that allows air to escape from the reservoir 28, but prevents fibers from doing the same. As a consequence, a quantity of fibers 62 accumulates in or is amassed at the bottom of the reservoir 28. Angled or inclined side walls 64 and 66 help direct fiber to a fiber outlet 68.
Fiber metering assemblies 70 and 72 (best seen by reference to
The metering assembly 72 is similar to the metering assembly 70. The metering assembly 72 includes a first metering roll 84 (driven in a clockwise direction when viewed from the sectional view in
Although the metering assemblies 70 and 72 are described in particular, other devices or fiber meters could be used to meter fiber into or deliver the fibers to the forming head 20. For example, it might be possible to form a slit or similar opening in each of the reservoirs 26 and 28 (in place of the outlets 48 and 68) and use a vibrator, pusher paddle, or other device to dispense fiber out of the slit. One desirable characteristic of such devices is that they be able to provide a relatively uniform, cross-directional delivery of fibers.
In one embodiment the outlets 48 and 68 have a width that matches the width of the forming head 20. Generally, the width of the forming head determines the width of the sheet or web of fiber formed. One way of obtaining or enhancing uniform thickness across a web or sheet (such as in a cross direction CD (
In some embodiments, an air duct 83 (
A retention section 90 (best seen by reference to
As shown, the retention section 90 also includes a first agitator 100 (such as a pin wheel, spike roll, or the like) that is driven in a counter-clockwise direction and a second agitator 102 (driven clockwise). In the embodiment shown, the agitators 100 and 102 are positioned a distance D1 (
The agitators in the retention section 90 are driven such that they tend to throw fiber back up toward the metering assemblies 70 and 72 to impede the direct downward passage of fiber into the remainder of the forming head 20. This impedance to downward flow provides more opportunity for the agitators to act on and open the fiber fed into them by the metering rolls. These agitators also tend to direct fibers toward the side walls or perimeter of the forming head 20. Air introduced through the vents 94 and 98 generates an air stream that tends to blow the fiber away from the walls 92 and 96 and back into the retention section 90, further retaining or delaying the downward motion of the fibers and providing more time for the agitators to act on the fiber.
In the illustrated embodiment, the forming head 20 includes a first angled side wall 111 and a second angled side wall 112 extending from walls 92 and 96, respectively. The side walls 111 and 112 also include a third vent 114 and a fourth vent 116. The third and fourth vents 114 and 116 are similar to vents 94 and 98, thus vents 114 and 116 need no further description. The use of angled side walls helps ensure that fibers do not pass through the forming head without being acted on by the agitators (particularly those that are located below the retention section 90). When the walls are angled (such as at an angle of about 15°), the agitators may be positioned in a pyramid-fashion such that lower rows of agitators extend beyond the width of prior, higher rows of agitators. This helps prevent fibers from dropping straight through the forming head without being opened. While angled side walls are beneficial, they are not required in all embodiments.
A funnel section 120 of the forming head 20 is positioned between the angled walls 111 and 112 and below the first retention section 90. In the illustrated embodiment, the funnel section 120 includes a seventh agitator 122 that is driven in a clockwise direction and an eighth agitator 124 driven in a counter-clockwise direction. The funnel section also includes a ninth agitator 126 driven in a clockwise direction and a tenth agitator 128 driven in a counter-clockwise direction. The ninth and tenth agitators 126 and 128 are positioned below the seventh and eighth agitators 122 and 124. The longitudinal axes of the ninth and tenth agitators 126 and 128 are substantially parallel and in a horizontal plane. The longitudinal axes of the ninth and tenth agitators 126 and 128 are also substantially parallel and in a horizontal plane. Agitators 126 and 128 are closer to the central axis CA than agitators 122 and 124. The manner in which the agitators are driven in the funnel section 120 tends to direct fibers toward the center or center axis CA of the forming head 20 and down to a second retention section 130.
The second retention section 130 is positioned between the angled walls 111 and 112 and below the funnel section 120. The second retention section 130 includes an eleventh agitator 132 that is driven in a counter-clockwise direction and a twelfth agitator 134 driven in a clockwise direction. In the illustrated embodiment, the agitators 132 and 134 are positioned such that their longitudinal axes are substantially parallel to each other and in a horizontal plane. Thirteenth, fourteenth, fifteenth, and sixteenth agitators 136, 138, 140, and 142 are positioned below the eleventh and twelfth agitators 132 and 134, such that their longitudinal axes are substantially parallel to each other and in a horizontal plane. Agitators 136 and 138 are driven in a counter-clockwise direction, and agitators 140 and 142 are driven in a clockwise direction. Agitators 138 and 140 are located closer to the center axis CA of the forming head 20 than agitators 136 and 142. Like the retention section 90, the manner in which the agitators are driven in the retention section 130 tends to impede the direct downward movement of fiber while also directing fibers toward the side walls or perimeter of the forming head 20. Air introduced through the vents 114 and 116 generates air streams that tend to blow the fiber away from the angled walls 111 and 112 and back into the retention section 130, further retaining or delaying the downward motion of the fibers and providing more time for the agitators to act on the fiber.
A distribution section 150 is positioned between the angled walls 111 and 112 and below the second retention section 130. The distribution section includes agitators 152, 154, 156, and 158, which are positioned such that the longitudinal axes are parallel to each other and in a horizontal plane. Agitators 154 and 156 are closer to the center axis CA than agitators 152 and 158. The agitators 152, 154, 156, and 158 may be driven in either a counter-clockwise or clockwise direction, mainly for the purpose of spreading or distributing the fibers exiting the second retention section 130. The distribution section also includes agitators 160, 162, 164, 166, and 168 positioned below agitators 152, 154, 156, and 158. Agitators 160, 162, 164, 166, and 168 are positioned such that their longitudinal axes are parallel to each other and in a horizontal plane. The agitators 160-168 are typically driven in a direction opposite to the direction of the rotation of the agitators 152-158. However, the directions in which the agitators are driven as described above are exemplary. Modifications of the drive directions are possible. In the configuration shown, the distribution section 150 helps to evenly distribute the fiber along the machine direction (direction MD, shown in
In general, fiber is provided into the forming head 20 by the metering assemblies 70 and 72. The fiber is then initially blended and opened by the retention section 90. Additional blending and opening occurs in the funnel section 120, the second retention section 130, and the distribution section 150. The sections of the forming head 20 help break the lumps of fiber and evenly distribute the fiber on a surface or forming wire 170 located outside the forming head 20. The forming wire 170 may be a belt, a screen, a sieve-type body, or any suitable device operable to allow a suction air stream or vacuum 172 generated by a vacuum box or device 174 to pass therethrough and to retain the fibers expelled from the forming head 20. The fibers are expelled from the forming head 20 by action of the suction air stream 172 produced by the device 174. In the embodiment shown, the device 174 is positioned below the forming head 20.
In the illustrated embodiment, the forming head 20 defines an enclosed space having vents (or inlets) 87, 94, 98, 114, and 116, and a fiber exit opening or bottom 176. The suction air stream 172 causes a flow of air through the vents 87, 94, 98, 114, and 116, into the forming box 20, and out of the bottom 176. In some embodiments, it is possible to adjust the force or intensity of the suction air stream 172 (by adjusting the device 174). In addition, the vents 87, 94, 98, 114, and 116 can be adjusted to affect volume and velocity of the air flow in the forming head 20. For example, the vents may include doors, louvers, and the like that may be closed, partially opened, or fully opened to adjust the volume and velocity of air flow. The doors and louvers may be moved by microprocessor- or similarly-controlled actuators. The microprocessor or other control may receive air stream velocity and volume information from sensors located in the forming head 20. Also, in the illustrated embodiment, the suction air stream 172 is independent from air streams 34 and 54.
In embodiments described, fiber is introduced substantially across the width of the forming wire or web (which generally matches the width of the forming head). Mechanisms other than those shown that introduce fiber to the forming head (and, therefore, onto the forming wire) in this manner may be used.
In some embodiments of the invention, the humidity of air introduced into the forming head as well as the humidity of the air used to transport fibers to the reservoirs 26 and 28 may be controlled. (Too little humidity can cause a build up of static electricity and static attraction between fibers.) For example, humidifiers may be connected to the ducting used to transport the fibers to the reservoirs 26 and 28. The humidity in the ducting may be monitored (using a control system having sensors and a processor) and the output of the humidifier controlled (using commands from the processor) to adjust the humidity in the ducting. In addition, air from humidity-controlled sources may be delivered through ducting or conduits to the vents in the forming head (such as vents 94, 98, 114, and 116) to ensure proper humidity in the forming head.
Thus, embodiments of the invention provide, among other things, devices and methods for depositing fibers on a forming wire. Various features and advantages of the invention are set forth in the following claims.
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