Patent Grant
10183309
1. Field
The present disclosure generally relates to composite materials, and deals more particularly with a method and apparatus for impregnating a continuous fiber reinforcement with a matrix material.
2. Background
Composite structures may be fabricated using composite build materials such as strips of preimpregnated fiber reinforcement (prepreg) that are applied over a supporting tool by automated fiber placement (AFP) machines. The prepreg used in automated fiber placement comprise a resin such as an epoxy that is reinforced with fiber such as carbon fibers. In some applications, however, where the structure is subjected to high temperatures, it may be necessary to use composite build materials such as ceramic matrix composites (CMCs). In addition to their ability to withstand high temperatures without degradation, CMCs are desirable for certain applications because of their light weight and resistance to corrosion.
CMCs typically comprise a ceramic matrix material such as a glass, a glass-ceramic or a crystalline ceramic in which refractory inorganic fibers are held. In one known process, CMCs are produced by preparing a liquid suspension of the ceramic matrix material in powdered form, and then immersing the inorganic fibers in the suspension. The suspension comprises a solvent such as water or an organic liquid as the carrier for the ceramic powders. In one variant of this process, known as slurry infiltration, the reinforcing fibers are passed through a ceramic slurry which penetrates the porous structure formed by the fibers. The driving force of the infiltration is largely capillary effect, but may be enhanced by vacuum or pressure. After the fibers have been infiltrated with the suspension, solvent is removed by evaporation. The materials discussed above are challenging to process and difficult to convert into build materials that are well-suited for high-volume production using techniques such as automated layup of prepreg.
Accordingly, there is a need for a method and apparatus for fabricating CMC build materials such as CMC prepregs. There is also a need for a method and apparatus as described above which are capable of producing continuous strips of CMC prepreg that may be used by AFP machines to automate the layup of CMC structures.
The disclosed embodiments provide an automated method and apparatus for producing CMC build materials in the form of continuous strips of prepreg that may be used in AFP machines for automated layup of composite structures. Large quantities of CMC prepreg strips may be manufactured relatively quickly and economically. The disclosed embodiments allow production of CMC prepreg strips of various thicknesses and widths that are suitable for fiber placement processing. The apparatus comprises a supply reel containing a continuous strip of dry fibers such as tows, and a matrix fluid bath into which the strip of dry fibers is immersed. The continuous strip of dry fibers travels in a serpentine path around an array of impregnation wheels within the bath which force the matrix fluid into the fibers, thereby wetting out the fibers and impregnating the fiber strip. The impregnation wheels include paddle-like protrusions that provide constant mixing of the matrix fluid to maintain a homogeneous mixture in the bath, thus eliminating the need for a separate mixing mechanism. The impregnated strip then passes through air knives which remove excess matrix fluid from the strip, following which the strip passes through rollers that adjust the width and thickness of the strip. The impregnated strip is dried using infrared heat energy, and is then spooled onto an AFP-compatible take-up reel to facilitate automated fiber placement.
According to one disclosed embodiment, apparatus is provided for impregnating a continuous fiber strip with a matrix material. The apparatus comprises a continuous fiber strip supply reel configured to hold a length of the fiber strip, and a matrix fluid bath configured to contain a matrix fluid. The apparatus also includes a plurality of rotatable wheels immersed in the bath for guiding the continuous fiber strip through the bath and forcing the matrix fluid into the continuous fiber strip to thereby impregnate the continuous fiber strip with the matrix fluid. The apparatus further includes a take-up reel for taking up the continuous fiber strip after the continuous fiber strip has been impregnated with the matrix fluid. The wheels are arranged in a staggered pattern forming a serpentine path of travel of the continuous fiber strip through the bath. Each of the wheels includes through holes therein allowing the matrix fluid to pass therethrough, and at least certain of the wheels includes at least one paddle-like protrusion for mixing the matrix fluid as the wheel rotates. The apparatus also includes a pair of air knives for stripping away excess matrix fluid from the continuous fiber strip. The air knives include nozzle openings respectively located on opposite sides of the fiber strip, and the nozzle openings are configured to jet curtains of pressurized, laminar air flow onto the continuous fiber strip. The apparatus may also comprise a width control for controlling the width of the impregnated fiber strip after it has been impregnated with the matrix fluid, a thickness control for controlling the thickness of the continuous fiber strip after the fiber strip has been impregnated with the matrix fluid, and a dryer for drying the continuous fiber strip after the continuous fiber strip has been impregnated with the matrix fluid. In one variation, the apparatus may include one or more reels adapted to contain a backer tape for adding one or more one backer tapes to the continuous fiber strip.
According to another disclosed embodiment, apparatus is provided for producing a ceramic prepreg strip, comprising a supply reel configured to hold a strip of dry ceramic fibers, and a ceramic slurry bath configured to contain a slurry of a ceramic matrix fluid. The apparatus also includes a plurality of impregnation wheels for guiding the strip of dry ceramic fibers through the bath and forcing the ceramic matrix fluid into the strip of dry ceramic fibers to thereby impregnate the strip of dry ceramic fibers with the ceramic matrix fluid. A thickness control is provided for controlling the thickness of the strip of dry ceramic fibers after the strip of dry ceramic fibers has been impregnated with the ceramic matrix fluid. The apparatus further includes a take-up reel for taking up the strip of dry ceramic fibers after the strip of dry ceramic fibers has been impregnated with the ceramic matrix fluid. A dryer is provided which includes a heater for drying the ceramic matrix fluid in the fiber strip, along with a temperature sensor for sensing the temperature of the fiber strip, and a controller for adjusting the heater based on the temperature of the fiber strip sensed by the temperature sensor. The heater may include infrared lamps, and the sensor may be located between the dryer and the take-up reel. The apparatus further comprises at least one air knife for stripping away excess ceramic matrix on the fiber strip after the fiber strip has been impregnated, and a width control for controlling the width of the fiber strip after the fiber strip has been impregnated. The air knife and the width control are substantially vertically aligned with each other above the ceramic slurry bath. The impregnation wheels are arranged in a staggered pattern defining a serpentine path of travel of the fiber strip through the ceramic slurry bath. The apparatus may further comprise at least one pivoting swing arm. The impregnation wheels are mounted on the swing arm for pivoting movement between an operative position immersed within the ceramic slurry bath, and a standby position raised above the ceramic slurry bath.
According to still another embodiment, apparatus is provided for impregnating a continuous fiber strip with a matrix material. A supply reel is configured to hold a length of the continuous fiber strip, and a matrix fluid bath is configured to contain a matrix fluid. At least one wheel is provided within the matrix fluid bath for forcing the matrix fluid into the continuous fiber strip. A device is provided for stripping excess matrix fluid from the continuous fiber strip. A take-up reel is provided for taking up the continuous fiber strip after the continuous fiber strip has been stripped of excess matrix fluid. The device for stripping the continuous fiber strip includes air knives for jetting curtains of laminar air flow onto the continuous fiber strip, and includes air nozzle openings located on opposite sides of the continuous fiber strip.
According to another embodiment, a method is provided of impregnating a continuous ceramic fiber strip with a ceramic matrix material. The method includes immersing a plurality of impregnation wheels in a bath of a ceramic slurry, drawing the continuous ceramic fiber strip through the bath and around each of the impregnation wheels, and forcing the ceramic slurry into the continuous ceramic fiber strip as the ceramic fiber strip is drawn around each of the impregnation wheels. Forcing the ceramic slurry into the continuous ceramic fiber strip is performed by tensioning the continuous ceramic fiber strip against each of the impregnation wheels. The method may further comprise stripping excess matrix fluid away from the continuous fiber strip after the continuous fiber strip is drawn through the bath, including jetting curtains of air onto the continuous fiber strip. The method may also include controlling the width of the continuous fiber strip by drawing the fiber strip between a pair of rollers, and controlling the thickness of the continuous fiber strip by drawing the continuous fiber strip between a pair of rollers suitably spaced to produce a desired thickness.
The features, functions, and advantages can be achieved independently in various embodiments of the present disclosure or may be combined in yet other embodiments in which further details can be seen with reference to the following description and drawings.
The novel features believed characteristic of the illustrative embodiments are set forth in the appended claims. The illustrative embodiments, however, as well as a preferred mode of use, further objectives and advantages thereof, will best be understood by reference to the following detailed description of an illustrative embodiment of the present disclosure when read in conjunction with the accompanying drawings, wherein:
The disclosed embodiments relate to an apparatus suitable for producing strips of composite build material that may be employed in AFP (automated fiber placement) machines for automated layup of composite structures. In the exemplary embodiment, the strips comprise ceramic fibers that are impregnated with a ceramic matrix, however as will be explained below in more detail, the disclosed apparatus and related method may be employed to produce other types of composite build materials in strip form, such as organic prepreg, where it is necessary to impregnate a fiber reinforcement with a slurry or similar suspension of a flowable materials.
Referring to
A fiber strip supply reel 22 is rotatably mounted on the front side of the mounting plate 82, and holds a length of a continuous dry fiber strip 52 that is to be impregnated with a desired matrix material. As used herein, the terms “fiber strip”, “strip”, “ceramic strip”, “fiber reinforcement”, “continuous fiber strip” and “reinforcement strip” all refer to a continuous strip or ribbon of an impregnable fiber reinforcement material that include fibers. The fiber reinforcement material may be arranged in any of a variety of configurations, including unidirectional and bidirectional fibers, as well as dry fibers that are woven, knitted or braided. The fiber strip 52 may be in the form of tape, or split tape sometimes referred to as tows.
The fiber reinforcement material will depend upon the application, and in the case of applications using CMCs, the fiber reinforcement material may comprise organic fibers such as carbon fibers, or inorganic fibers including metal fibers and nonmetallic inorganic fibers such as ceramic fibers, glass and mineral fibers and single crystal fibers. The matrix material used in CMCs employing these fibers may include ceramic, ceramic-glass and glass matrices such as, without limitation, alumina, silica, glass, mullite, silicon carbide and silicon nitride to name only a few.
The continuous fiber strip 52 is drawn from the fiber strip supply reel 22 onto a wheel 64 that redirects the fiber strip 52 into a tank 24 containing a bath 85 (
After being impregnated with the matrix fluid within the bath 85, the impregnated fiber strip 52 is drawn vertically, in succession, from the tank 24 through a pair of air knives 36, a width control 42 and a thickness control 44. The air knives 36, the width control 42 and the thickness control 44 are substantially vertically aligned with each other, above the tank 24. When the impregnated fiber strip 52 initially exits from the tank 24, the fiber strip 52 may contain an excess amount of matrix fluid and may have a width and/or thickness that is greater than a desired nominal width and thickness.
The air knives 36, discussed below in more detail in connection with
A strip of backer tape 54, which may comprise a polymer film, is drawn from a backer supply reel 68 and trained around a feed wheel 70 which directs the backer tape 54 onto the impregnated fiber strip 52 as the impregnated fiber strip 52 enters the thickness control 44. The backer tape 54 may have a width that is slightly greater than the width of the fiber strip 52, and functions to prevent the still-wet matrix fluid in the fiber strip 52 from being accumulated on or adhering to a redirect wheel 74 and other downstream components of the apparatus 20. For example, and without limitation, in one embodiment where the fiber strip 52 has a width of approximately ½ inch, the backer tape 54 may have a width of approximately 1 inch. The backer tape 54 is also useful in providing the fiber strip 52 with support as the latter travels through downstream processing components of the apparatus 20.
With the width and thickness of the fiber strip having been adjusted to desired values, the fiber strip 52 is then drawn around the redirect wheel 74 into a drying station 55 comprising an elongate dryer box 46. The fiber strip 52 is supported between redirect wheel 74 and another redirect wheel 78 as the fiber strip 52 passes through the dryer box 46. The dryer box 46 may include a heater such as electrically powered infrared lamps (not shown), that is operative to dry the matrix fluid that has been impregnated into the fiber strip 52. The energy supplied by the infrared lamps reduces the volatile components of the matrix fluid through evaporation. The amount of evaporation of the matrix fluid may be controlled by altering the speed at which the fiber strip 52 passes through the dryer box 46, as well as the amount of energy that is supplied by the infrared lamps. The redirect wheels 74, 78 maintain the fiber strip 52 at a desired, constant distance from the infrared lamps. A contact or non-contact temperature sensor 48 may be used to sense the temperature of the fiber strip 52, or the air temperature in close proximity to the fiber strip 52, as the fiber strip 52 exits the drying station 55, and may form part of a feedback loop with the controller 30 used to control the amount of evaporation that takes place. The air temperature in close proximity to the fiber strip 52, for example, within 0.10 inch of the fiber strip 52, is directly related to the degree of dryness of the matrix in the fiber strip 52. The desired degree of dryness will depend on the particular application, and the matrix material.
After being dried, the fiber strip 52 is redirected by a wheel 78 onto a take-up reel 80. Optionally, a second strip of a backer tape 56, which may comprise the polymer film, may be drawn from a backer supply reel 76 and directed onto the fiber strip 52 as it is being spooled onto the take-up reel 80, resulting in the fiber strip 52 being sandwiched between the two strips of backer tapes 54, 56. Optionally, the end of the fiber strip 52 spooled onto on the take-up reel 80 may be sealed with a plastic strip (not shown) to prevent evaporation of the matrix material.
Referring now to
The drive motor 32 drives rotation of the take-up reel 80 through the hubs 91, 92 and the drive belt 96. The take-up reel 80 may pivot 94 along with the swing arm 90, as required, to adjust for changes in tension in the fiber strip 52 and the clutch 95 in order to prevent excess tension from damaging or breaking the fiber strip 52. Although not shown in the drawings, a drag brake may be coupled with the fiber supply reel 22 or other components of the apparatus 20 to maintain proper tension of the fiber strip 52 as it passes through each of the processing stations.
Referring to
Referring now to
The impregnation wheels 66 are arranged in a staggered pattern, and the fiber strip 52 is wrapped around and tensioned against the wheels 66 so as to move through the bath 85 in a serpentine path of travel, causing opposite faces of the fiber strip 52 to alternately be forced into contact with the wheels 66. In other words, after one face of the fiber strip 52 contacts one of the wheels 66, the opposite face then contacts the next-in-line wheel 66 as the strip 52 travels in a serpentine path through the array of wheels 66. As the fiber strip 52 comes into contact with the wheels 66, the matrix fluid is forced into the fiber strip 52. In effect, the wheels 66 squeeze or press the matrix fluid into the fibers of the strip 52. Penetration of the matrix fluid into the fiber strip 52 is aided by the changing rotational directions of the wheels 66, and the tension that is maintained in the fiber strip. The staggered arrangement of the wheels 66 results in the fiber strip 52 wrapping around and coming into contact with more than 180 decrease of each of the wheels 66, thereby assuring that the matrix material is adequately worked into the fiber strip 52. The size of the wheels 66, i.e. the wheel diameter will depend upon the application, and particularly, the minimum bend radius of the fibers in the fiber strip 52. The wheel diameter should be sufficiently large to avoid damaging or breaking the fibers as they are bent around the wheels 66. A handle 93 attached to the outer end of one of the swing arms 60 allows the retractable dipper assembly 58 to be manually raised, lifting the wheels 66 from their operative position inside the tank 24 (
Attention is now directed to
Multiple through-holes 104 extend transversely through each of the wheels 66 to allow the matrix fluid to readily flow through the wheels 66, and thereby facilitate mixing of the bath 85 of the matrix fluid. The outer side of each of the wheels 66 includes a plurality of circumferentially spaced, axially extending, paddle-like protrusions 106. The protrusions 106 aid in mixing the matrix fluid to maintain the bath 85 homogeneous as the wheels 66 rotate within the bath of matrix fluid. Constant mixing of the matrix fluid may also extend the processing time for a given batch of the matrix fluid remains usable. In some embodiments, depending upon the constituents of the bath 85, and the amount of settling of particulates within the tank 24, it may be necessary or desirable to provide an auxiliary means of stirring the bath 85, which may comprise a mixer (not shown) that is either manually or automatically operated. Depending upon the particular matrix being employed as a constituent in the bath 85, it may be necessary to either heat or chill the bath 85 in order to achieve a desired matrix fluid viscosity, while in other embodiments, the bath 85 may be maintained at room temperature.
As best seen in
Attention is now directed to
Embodiments of the disclosure may find use in a variety of potential applications, particularly in the transportation industry, including for example, aerospace, marine, automotive applications and other application where structural members formed of ceramic matrix composites may be used. Thus, referring now to
Each of the processes of method 144 may be performed or carried out by a system integrator, a third party, and/or an operator (e.g., a customer). For the purposes of this description, a system integrator may include without limitation any number of aircraft manufacturers and major-system subcontractors; a third party may include without limitation any number of vendors, subcontractors, and suppliers; and an operator may be an airline, leasing company, military entity, service organization, and so on.
As shown in
Systems and methods embodied herein may be employed during any one or more of the stages of the production and service method 144. For example, components or subassemblies corresponding to production process 152 may be fabricated or manufactured in a manner similar to components or subassemblies produced while the aircraft 146 is in service. Also, one or more apparatus embodiments, method embodiments, or a combination thereof may be utilized during the production stages 152 and 154, for example, by substantially expediting assembly of or reducing the cost of an aircraft 146. Similarly, one or more of apparatus embodiments, method embodiments, or a combination thereof may be utilized while the aircraft 146 is in service, for example and without limitation, to maintenance and service 160.
As used herein, the phrase “at least one of”, when used with a list of items, means different combinations of one or more of the listed items may be used and only one of each item in the list may be needed. For example, “at least one of item A, item B, and item C” may include, without limitation, item A, item A and item B, or item B. This example also may include item A, item B, and item C or item B and item C. The item may be a particular object, thing, or a category. In other words, at least one of means any combination items and number of items may be used from the list but not all of the items in the list are required.
The description of the different illustrative embodiments has been presented for purposes of illustration and description, and is not intended to be exhaustive or limited to the embodiments in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. Further, different illustrative embodiments may provide different advantages as compared to other illustrative embodiments. The embodiment or embodiments selected are chosen and described in order to best explain the principles of the embodiments, the practical application, and to enable others of ordinary skill in the art to understand the disclosure for various embodiments with various modifications as are suited to the particular use contemplated.
| Number | Name | Date | Kind |
|---|---|---|---|
| 1595474 | Minton | Aug 1926 | A |
| 2473599 | Liebel | Jun 1949 | A |
| 3130076 | Gruber | Apr 1964 | A |
| 3460978 | McGovney | Aug 1969 | A |
| 5174822 | Nabhan | Dec 1992 | A |
| 5250243 | Allaire et al. | Oct 1993 | A |
| 5817223 | Maloney | Oct 1998 | A |
| 5936861 | Jang | Aug 1999 | A |
| 7153379 | Millard et al. | Dec 2006 | B2 |
| 7857111 | Moore | Dec 2010 | B1 |
| 20030200064 | Bay | Oct 2003 | A1 |
| 20130149425 | Caridis | Jun 2013 | A1 |
| Entry |
|---|
| Guglielmi et al., “Production of Oxide Ceramic Matrix Composites by a Prepreg Technique,” Materials Science Forum, Advanced Powder Technology VIII, vols. 727-728,Chapter 2: Ceramics I, Aug. 2012, pp. 556-561. |
| Kopeliovich, “Fabrication of Ceramic Matrix Composites by Slurry Infiltration,” SubsTech.com, last modified Jun. 2012, 2 pages, accessed Aug. 20, 2014. http://www.substech.com/dokuwiki/doku.php?id=fabrication_of_ceramic_matrix_composites_by_slurry_infiltration. |
| Luthra et al., “Emerging Applications and Challenges in using Ceramics at General Electric,” Ceramic Leadership Summit, Aug. 2011, 24 pages. |
| Downey et al., “Frontiers,” The Boeing Company, vol. XIII, Issue V, Sep. 2014, 46 pages. |
| Zhu et al., “Manufacturing 2D carbon-fiber-reinforced SiC matrix composites by slurry infiltration and PIP process,” Ceramics International, vol. 34, Jul. 2008, pp. 1201-1205. |
