CA2057225C

CA2057225C - Band fiber forming and placement delivery head

Info

Publication number: CA2057225C
Application number: CA002057225A
Authority: CA
Inventors: John A. Johnson; Noel I. Shepherd; Keith G. Shupe; James P. Nielsen
Original assignee: Hercules LLC
Current assignee: Northrop Grumman Innovation Systems LLC
Priority date: 1990-12-19
Filing date: 1991-12-06
Publication date: 1994-09-27
Anticipated expiration: 2011-12-06
Also published as: DE69122064T2; JP2933433B2; JPH04341830A; DE69122064D1; ES2094783T3; EP0491354B1; US5698066A; CA2057225A1; EP0491354A1

Abstract

A BAND FIBER FORMING AND
PLACEMENT DELIVERY HEAD
Abstract of Disclosure A delivery head assembly is provided for forming a tape band from a plurality of tows and applying the band as superimposed layers in a helical pattern on to a mandrel to produce non-uniform cross sectional articles. This head assembly is composed of a distribution section, ribbonizing section, coating section, add section, and compaction roller.

Description

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Thi~ invention relate8 to fiber placement devices that --.
apply Yuperimposed layers of ~ibrous rovings or tows, i~pregnated wlth a thermosetting re~in, in a helical pattern onto a mandrel to produce a generally tubular article havin~ ~ ;
~arying contours.
In most type8 of filament winding operation~, the tows pass through an aperture (a "delivery eye") or fro~ a deliv- :
ery roller acroas an air space onto the part. Thi8 type of . ~'`~-8y8tem i8 limited to geodesic-path or natural-path fiber pat-tern~ and the roving need to re~ain continuous. Therefore, a turnaround dome i~ required in the scrap area of the work-piece. Any compaction of the part i9 a re~ult of the tension ~ ~-induced on the roving whi~e the part i~ being ~anufactured.
Conventional tape laying device~ generally provide :
positioning o~ banda on ~lat or slightly contoured surfaces;
these ~y8tem8 cannot wind non-geodesic paths without fiber gaps or overlapg unless an i~practicably narrow band of tows i 8 employed.

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The inability to cut the band during laying down of ; ~-composite material making it necessary to have a turnaround dome on the mandrel, to be limited to the use of geodesic .
path~, and to use roving induced tension, result in a limited 5 system that would be co~tly to operate. The inability to --:~
accurately place fiber at the optimum angle result~ in heavier than neces~ary de~igns. In some case~ thi3 re~ults : ~ -in a de~ign that cannot be auto~at~d or i8 le88 c08tly and no heavier if designed in metal and thexeore ~ubject to other disadvantages.
U.S. Patent 4,8~2,444 discloses a filament winding me~hod that overcomes those disadvantages of known ~ethods, ~ .
but this method involvea a device in which the multiple rovings are tensioned, flattened, and guided into a .. .;
15 "~hingled" or alightly overlapped relationshlp a~ they are .;:~
applied to the rotating mandrel; as the shingled r~ving~l are placed on the mandrel, a con~inuous thermoplastic tape or ~
paper strip i8 applied to the roving~ upper surface between ~.
the rovings and payoff roller to ~aintain their overlapped position integrity and to prevent sticking to the payoff roller while being applie~ to the mandrel. U.S. Patent ~:
4,867,834 also discloses a fila~e~t winding method that overcomes the above mentioned tisadvantages of known ~ethods, but this methot atds individual tows without shaping and for~ing a tape. U.S. Pat~nt 4,790,898 also disclo~es a .
filament winding method where the tows are flattened and formed into a tape on the ~andrel by applying ~ufficient compre~sion force to the tows by the compaction roll~r while heating the tow~ with a hot air gun; this 8y8te~ al90 use~ a pair o~ rotating ~hear blates, o~e on each side of the plurality of tow~, to cut individual tows prior to forming the tape on the mantrel. :~
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There is a need for a compact delivery head to improve ~- .
prior art devices so as to permit the head to make a quality tape band from a plurality of tows with reliable cutting of such band using a single cutting mechani3m and adding it back 5 on demandt thus eliminating exce3sive scrap~ associated with . ;- .-tape laying. ` ` .
Thi~ invention is directed to a delivery head assembly . ;~
for a fiber placement machine, having an input end ~or fibrous tows and an output end for applying superimposed `.
layer~ of the tows in the for~ o~ a band in a helical pattern onto a mandrel to produce a generally tubular ar~icle having ;~: :
varying contours. The delivery head a~ss~bly compri3es~
distributing means being located at said input end of the assembly for receiving and spacing the tows in a single plane .
15 and passing the tows inwardly in said as~e~bly, b) : ;~
ribbonizing means for ~preading the towa to a desired wldth and thickne~s by heating and applying pressure, thus forming .. ..
a guality tape band, c) chilling means for cooling the tape band co~ing from the ribboni~ing ~ean , d) cutting means for cutting the complete tape in a single action while the head i8 in motion, e) add means upstream from said cutting ~eans for holding said cut tape band ant adding on de~and to per~it the application of tape band to the mandrel where desired, and f) co~paction roller ~ean~ for applying superimposed layers o~ the tape band onto a ~andrel.
Eigure 1 i~ a perspective view showing the various component3 of the fiber place~ent system a~sociated with this invention; Figure 2 i8 a front/~ide i~o~etric projection view of the telivery head of this i~vention; Figure 3 i8 a .
rear/side i80~et~ic projection view of the delivery head o~
this invention.

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Figure 4 i8 an exploded isometric pro~jection view of Figure 2 showing assembly; Figure 5 is a bottom vie~ showing -.
the reciprocating mechanism for the delivery head along lines 5-5 as shown in Figure 3; Figure 6 i8 an i~olated view of a S preheat system for nip point heating of the band being laid ~:
on the mandrel surface. ~:
Thi~ invention is a delivery head (or end e~fector) for --~
use in a co~pletely computerized sy~tem for laying down compo~ites on mandrels that are not necessarily ~y~metrical 10 or flat but rather can include concaYe or convex contours. .
On the instant delivery head, one or a plurality of tows can be processed into a band or tape for compaction on a mandrel in a ~anner similar to that used by tape laying machine8. Since the band or tape is Made up of a plurality 15 of tows, the tows can be fed to the delivery head at dif- `
~erent rates allowing the band to be placed on a curved ~ ~;
path, without ~ignificant buckling. Thi~ ~eature makes it pos~ible to lay down compo~ites on a wide variety of mandrel shape~ as mentioned above. The mandrel can be either statio~
nary or rotated depending on the nature of the workpiece.
In the fiber placement process o~ the in~tant invention, fiber tows are normally impregnated with a resin prior to u~ing in the proces~. ~ence, the te~perature o~ the tow~
must be controlled during the proces~ in vrder to keep the `~
tackiness down and, more i~portantly, to stop the resin in the tows from advancing to a ~tate of cure in the placement ~ :
machine. In other words, if the temperature o~ the tows is ,-not controlled, the tow~ could bind up the machine cau~ing ~ajor delays in the place~ent process. Therefore, it i8 `~
importan~ to control the te~perature of the tow~ during the placement process. The temperature o~ the tows in the delivery head i8 raised during ribbonizing to help in the shaping and for~ing in~o a band (or tape) o~ the tow~; in this ribbonizing zone, the temperature ~hould be maintained .`" ''`' ~

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in the temperature range of 88 to 163C for best results.
The temperature of the tows in the remainder of the delivery head i8 reduced (in a te~perature range of -250 to +10C), for the purpose of keeping the resin in the tows from coming out and off the surface of the tows onto the contact surfaces of the components of the delivery head. The temperature, n@vertheless, o~ the band at the nip point or compaction roller is raised to improve the band~ tackiness 80 as to obtain better adherence of the band to the mandrel or the previous layer of composites.
The fiber roving or tows that have been pre~ regnated with thermoset resin3 are transported through the delivery head. Once the tows enter the delivery head they are re-directed to a ~ingle plane. The tow~ are spaced to lS establish a band width that i8 determined by the ply thickness that meet~ the design criteria. Once the band width i~ established, ~he tows are passed through the ribbonizers and a tape quality band i8 ~ade. The band i8 then chilled to as~ist with further method~ of the band handling.
A band cutting mechanism i8 in place to cut the band as required in the part tesign as wel~ as an adding ~echanism to add the band bac~ into the syste~ when it i8 required. These mechanisms work to cut and atd o~ the ~ly (or while the 25 ~achine is in operation) 80 ti~e is not lo~t. Through the ~ ~
use of the cutting and adding mechanisms, the e~cessive ~ -scraps, nor~ally produced in the lay down, are eliminated.
Also, cu~-outs in the design of the part can be accomplished as required.
The band is deliveret onto the mandrel by way o~ a delivery roller. The delivery roller co~tacts the psrt ~;
surface and provides a compacting force as the fiber is placed. Through the use of the compaction ~orce the band can ,~, ~, , - 2 0 ~ ~ % ~
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be placed into negative contours and follow non~geodesic fiber paths. The band i9 guided around the surface of the compaction roller by means of a band biasing device that i~ a curved deflector that has a contour parallel to the compaction roller and of$set from the complaction roller at a nominal clearance. The purpose of this device i~ to keep the band in a ready po~ition for accurately pcsitioning the band on demand for laying down in each sequential lay down pa88.
As the band i8 layed down onto the ma~drel, optionally, a heat source is provided at the point where the fiber i~
being placed ~o that the fiber being placed and the underlying ~iber will stick together. This heating 8tep al80 make~ the fiber and resin (in and/or on the fiber) soft and compliant enough 80 that good consolitation of the layer~
lS will take place in the part, i.e., no air bubbles or areas of bridging will form. This heating ~tep i8 referred to a~l "nip point heating" because it mu0t be accomplished quickly in the ~ ~:
region between the compaction roller and the ~andrel where they are closest together yet with the lea~t possibility of heating the composite 90 hot that it will cause an e~other~ic reaction, or have localized areas of cured resin. This nip point heating can be acco~plished by any heating device where the te~perature can accurately be con~rolled in a narrow area; heating device~ such as an electrically powered air heater or laser jet heater can be used for this nip point heating. ~.
All of the component part~ of the delivery head (i-e-t entry comb, band width adjusting comb, ribbonizing section, chilling section, cutter, add section and compaction roller section) of the instant invention can be in the ~or~ of ~odular component~ that can readily be removed ant replaced in the head ~or servicing. A modular unit i held in place with a quick acting mechanis~ locking device such as ca~
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lock. The modular units can be e~changed rapidly with a duplicate modular component with minimal down time using .
little effort.
For a more detailed and comprehensive illustration of S the invention, the invention will be described in rePerence to the drawings. -Figure 1 illustrates the various components of a fiber placement 8y8tem 1 of the instant invention. As shown, the ~.
fiber tow~ winding band 2 pa89e8 through the delivery head 3 -~
and i9 applied by a compaction roller 4 to a winding mandrel 5 that could be in various shapes, such as aircraf~ inlet ducts and ~hroud8. Roller 4 presses against ~andrel 5 during operation of laying down the fiber band onto mandrel 5. The :
delivery head 3 i9 mounted directly to a fiber placement : :
machine 6 through an arm and wrist asse~bly generally shown as 7. As shown in Figure 1, a control computer 75 is also provided to control ~in addition to the ultimate control of the entire system) the actions of cutting and adding of the fiber band 2 in the delivery head 3 and the ~ultiple a~es 20 movement of the fiber placement ~achine 6. -~
Figure 2 shows the several sections of the delivery head 3 through which the band 2 of fibers pa~ses. The band 2 iB
composed of several individual tow8. These tow~ are blended together to form the bant. The sec~ion~ 13, 14, 15, 16, 17, and 4 of the delivery head 3 are mounted to a bou3ing formed by plates 8, 9 and 10. Figure 3 show~ the same components as mentioned above in Figure 2 only fro~ a rear view. Figure 4 shows an exploded vi~w with the components isolated in pro~imate location to their asse~blet disposition ~or a be~ter view of the exact structure of each co~ponent.
Figure 5 i8 the botto~ view of~the delivery head 3 as illu8trated from line8 5-5 of ~igure 3 showing reciproca~ing mechanism 12. This ~echanism 12 is responsible for the mounting of the delivery head 3 onto the Piber placement ..

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machine 6. It include~ an attachment base plate 22, a left and right support gusset 23 and 24, and a top plate 25.
These parts are assembled to form mounting platform 12 for holding delivery head 3 as shown in Figurs 2 and 3. An air cylinder 18 is attached to the underneath ~ide o~ the top plate 25 and ~upplies the compaction force, with the use of pressure regulators, and pu119 the deliv@ry head 3 off the mandrel 5 when required. The raM of the air cylinder 18 i~
attached to the base pla~e 10 of the delivery head 3 by the u~e of jam nuts 21. Ball rail support shafts 19 and ball rail shafts 20 attach to the top of the mounting top plate 25. They allow the delivery head 3 to reciprocate with the use o~ pillow block linear bearings 11 (Figures 2 and 3) that ~ .
attach to the base plate 10 o~ the delivery head 3.
15The individual tows that ~orm the band 2 enter the ~ :
delivery head 3 through a tow distributing section 13 that is . ;~.
composed of an entry comb mounting base 26 and the entry co~b teeth 27. This section keeps the ~ow~ separated from each other 80 proces~ing will be more workable in the delivery head 3. The entry comb base 26 and teeth 27 are attached to the side plates 8 and 9 as well as the top roller 28 and bottom roller 29. The rollers keep the band for~ing tows in ;~
the center plane ~or further processing.
The adjustable co~b asse~bly 14 shown in Figure 4 rotates about its ~ounting ba~e 30. The ~wivel comb bracket 31 flt~ onto the pin 64 in the ~ounting base 30. The co~b 36 is attached to 31 and rotat~s about pin 64 to e~tabli~h a predetermined band witth. The attach~ent bracket 32 i8 mountet to ~ide plate 8 and supports the thread~ bushin~ 33.
A threaded adjust~ent shaft 35 with knob 37 threads through the bushing 33 and threaded bushing 34, which i8 attached to the ~wivel comb bracket 31. Retaining means such as snap rings (not ~hown) on each side of the bushing 34 keep the 2 ~ ~ 7 2 ~

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bu~hing from moving off the shaft 35. As the adjustment : :
shaft 3S i9 turned via knob 37, the comb 36 turn~ or 8wiv~
about it~ attachment point (pin 64) and changes the band width.
Once the width of the band 2 is set, the band enters the ribbonizer section 15 (Figure~ 2, 3 ant 4). The individual ~-tows forming the band 2 pass over the single ribbonizing tube ~ :
38 and the double ribbonizing tubes 39 and exit under the ~ -cold roller 43 in a ~erpentin~ path to blend the individual tows together and make a tape quality band 2. The ribbonizing tubes 38 and 39 are hea~ed with the u3e of cartridge heaters 42 that are placed insite the ribbonizing :~
tubes 38 and 39. The heated ribbonizing tubes are insulated from the side plate~ 8 and 9 with insulators 37 and 40. An attach~ent ring 41 clamps the insulator 40 that holds the ribbonizing tubes 39 to the site plate 8 ~or the double : ::
ribbonizer; and the single ribbonizing tube 38 i~ bolted through the insulator 37 into side plate 9. The double ribbonizing tubes 39 can be adjusted by rotating the attach~ent ring 41, thuE changing the angle o~ the tubes 38 and 39 in relation to themselves for i~creasing or decreasing the pressure o~ the tows; thi8 cau8e~ the flattening of the .
tow~ for inti~ate contact with each other and fu~ing of the tows into a high guality band (tape). The changing the angle Z5 of tube~ 38 and 39 determines the a~ount of pressure to be ~::
applied to the tow~ which in turn determines the thic~ness to which the tow~ are flattened. The cold roller 43 c0018 the .
heated band 2 after it i8 for~ed to main~ain ~hs prop2r band width. It also helps to form a rigid band to a~sist ~ith further processing require~ents.
The formet tape band 2 ~hen passes into the band add a3sembly 16. The drive roller 47 as sho~n in Figure 4 i8 .
attached to the top side of mounting plate 49. The drive ,~ 2~722~ ::
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roller 47 is held in place to band guide tray 48 wi~h .
attachment brackets 46. A coupling 45 connect~ the drive motor 44 to the drive roller 47. The motor itsel~ attaches ::
to the side plate 9. Guide 48 guides the band 2 into the cutting portion of the head. Pinch roller 53 of the add qection 16 i~ mounted in attachment brackets 52 that are attached to pinch plate 51 to the mounting plate 49 with the .
attachment brackets 50. An air cylinder 5!5 i8 the actuation force for the pinching motion and i8 mounted to the head ba~e plate lO under the pinch plate 51. Pinch ~late return mechanism 54 (a bolt with a spring) keeps the pinch plate pushed do~n to the air cylinder ram and supplie3 the return .
when the pinch is not required.
The cutting section 17 i8 next (Figure 4). The cutter 15 17 includes a mounting body 56, an actuation cylinder 57, a i4' top cutting blade 60 that ~ounts to a reciprocating mechanis~
59 with linear bearings and ball rail~ 58, and a botto~ blate 61. The top blade co~es down and shears the band 2 be~ween the top and bottom blades 60 and 61.
~iand 2 is cu~, when it i8 no longer desired, such a3 at the end o~ a winding circuit. Then it i8 adted back in, when required, such as when the neat circuit ~tarts. The band i8 added through to co~paction roller section 4. The compaction roller housing 62 i~ mounted to the front ent of the deliver .
head 3 by bolting to the side pla~e 9 and ha~ a ~ounting bracket 65 that holds the delivery roller 63 in the housing : .
62. The band 2 i~ guided around the under surface of the compaction roller 63 by ~ean~ of a band biasing device 77 (Figure 6) that i8 a curved deflector that has a contour parallel to the co~paction roller 63 and offset from the co~paction roller at a no~inal clearance. 8ant 2 pas3es under the delivery roller 63 being guided by biasing device 77 and, it i8 placed onto the surface of the mandrel 5. The delivery roller 63 rides on the surface of the mandrel 5 on 35 top o~ the band 2 and applies compaction force. .

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As the band 2 i~ layed down onto the mandrel 5, optionally, a heat source 66 i8 provided at ~he nip point for ~ :~
heating the fiber being layed down and the underlying layer of fiber ~o that good con~olidation o~ th~! layers will occur. As shown in Figure 6 the air heater 68 heats the layer of resin impregnated fiber on the ma.ndrel 5, or ~ay heat the band 2 being fiber plac~d, or both. The heat source 66 is composed of nip-point heating controller 67 that regulates th~ temperature of the hot air ~rom heater 68 by way of thermocouple 71, power ~upply line 70, air ~upply line 69, heat sensor 72 via control line 73. Te~perature of the :~
heated area i8 monitored by the infrared temperature sensor 72. Fiber speed i8 ~easured by the tachometer 74 as it i8 driven by the compaction roller 63. Additional proce~ input `
is obtained by air te~perature measuring thermocouples 71.
Air flow through the heater 68 i8 controlled by the air ~low and control devices 67. Te~perature i~ ~aintained by varying the amount of power with the power control and regulating system 67.
Closed loop control i8 achieved by monitoring the temperature of the co~posite on the ~andrel 2 with the :~
in~rared te~peratur~ sensor 72 te~perature along with fiber speed a~ determined by the tacho~eter 74 are processed by the control 67. I~ addition to the above ~entioned para~eters of fiber temperature and speed, the co~puter deter~ine~ what air ~low and air temperature i8 required by asses~ing require~ents of the proce~s a~ input from the main ftber place~ent ~achine co~trol co~puter 8. :: ;
Additional con~rol i8 achieved by mod~iing the effect o~
30 heat on the co~posite resin. ~ces~ive heat ca~ cause areas : -o~ localized cure of in estreme cases and esothermic reaction can re3ult. Conversely insu~ficient hea~ to the fiber would not supply the required tack or compliance required to ~ake a good part. A~ the temperature oP the composite is a function ', '.,',;~

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of the difference in temperature between the air source and ~ .
fiber heing hsated, as well a~ the length of time the~: :
temperature i9 applied, modeling i3 nece~sary to keep ~iber temperature within re~uired limits as the speed of the fiber 5 varies. ..
Rédundant regulation i8 accomplished by monitoring the temperature o~ the air leaving the heater with a thermocouple 71. Should the temperature rise too high for too long as :~-pre-determined by operator e~perience, the process will be ~i interrupted by a separate safety mo~itoring system (not ~hown).
Several of the component3 identi~ied in thi~ telivery :~
head 3 may be coated with a synergistic coating (such as a :
Teflon coating) to assist with the durability and ..
15 serviceability. :;~

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Claims

1. A delivery head assembly for a fiber placement machine, having an input end for entry of a plurality of fibrous tows and an output end for applying superimposed layers of the tows in the form of a band in a helical pattern onto a mandrel to produce an article having varying contours, comprising: a) distributing means being located at said input end of the assembly for receiving and spacing the tows in a single plane and feeding the tows inwardly in said assembly, b) ribbonizing means for spreading the tows to a desired width and thickness by heating and applying pressure, thus forming a quality tape band, c) Chilling means for cooling the tape band coming from the ribbonizing means, d) cutting means for cutting the complete tape in a single action while the head is in motion, e) add means upstream from said cutting means for holding said cut tape band and adding on demand to permit the application of tape band to the mandrel where desired, and f) compaction roller means for applying superimposed layers of the tape band onto a mandrel.

2. The delivery head assembly of claim 1 wherein the distributing means comprises an entry comb attached to side plates of the delivery head and an adjustable comb attached to a mechanism that swivels the adjustable comb about an axis for changing the band width of the tows as desired.

3. The delivery head of claim 2 wherein the ribbonizing means comprises three tubes with heating means therein offset from each other in such a way so that the band passes over them in a serpentine path that can be adjusted for changing the amount of pressure on the tows that determines the thickness to which the tows are flattened.

4. The delivery head of claim 1 wherein the delivery head has a band biasing device adjacent to the compaction roller at a nominal distance therefrom for guiding the band around the compaction roller.

5. The delivery head of claim 4 wherein the delivery head includes a nip point heating means for heating the band as it is applied to a mandrel and/or for heating the layers of a composite material already on the mandrel.

6. The delivery head of claim 5 wherein the nip point heating means comprises a heating controller and a heat sensor for precisely controlling the temperature of the heat applied to the mandrel and/or layers of composite material.