JPH10503247A - Bicomponent and long fiber product formation for splittable packs - Google Patents

Abstract

Abstract: A splittable pack (78) of long fibers (16) is disclosed by forming and attaching a wool pack (48) of long fibers (16) in a laminated relationship. The resulting wool pack (78) can be substantially separated along a plane (83) defined between binderless wool packs (48) for ease of installation around obstacles.

Description

DETAILED DESCRIPTION OF THE INVENTION               Bicomponent and long fiber product formation for splittable packs 〔Technical field〕   The present invention relates to mineral fiber wool materials, and in particular to long glass fiber insulation products. I do. The invention is also suitable for the manufacture of insulating products made of long wool fibers. (Background technology)   Small diameter glass fibers are useful in a variety of applications, including soundproofing or insulating materials. these Is made into a grid or web, commonly referred to as a wool pack. Glass fiber, which lacks strength or rigidity individually, can be formed into very strong products. Wear. The manufactured glass fiber insulation has light weight, high compressibility and elasticity. this For the purposes of the patent specification, the terms "glass fiber" and "glass composition" Means "glass" means glassy mineral materials such as rock, slag and basalt; Including a lot of traditional glass.   A common prior art method for producing glass fiber insulation products is to spin the glass Producing fiber. A single molten glass composition may be used in a centrifuge or spinner. Extruded through orifices in the outer wall, producing mainly straight glass fibers. The fiber is pulled downward by a blower and uses conventional air knife and wrapping techniques Is typically used to disperse the bale, allowing for an almost uniform fiber distribution I do. When the fiber is pulled downward, the fiber is glued into the wool product and the product is The binder required to provide integrity is sprayed onto the fibers. Then The fibers are collected to form a wool pack. Heat the wool pack further in the oven The wool pack is processed by cutting, mechanical forming and cutting Become an edge product. Once formed, wool packs can be used to reduce shipping costs. High compression is also desirable. Thus, the wool pack is also ready for use It is desirable to show a quick and reliable recovery from compression when unwound.   Once unwound, some product applications can separate the wool packs longitudinally. Is desirable for ease of installation. For example, used for wall and attic installation The wool bat installer must place the wool between the studs and the timber. Obstructions such as pipes, conduits, wires, and other building components when Often encountered. The traditional way is to split the staple bat almost flat Was to separate the short fiber bat in that area in the longitudinal direction. Then The separated portion of the pack is positioned over the obstacle. To the binder Thus, commercial wool packs of combined staple fibers are subject to It was easy to respond to the separation in the longitudinal direction.   Thus, nearly uniform density, product integrity, and fiberglass wool insulation material Desirable lattice properties, such as recovery from compression, as well as expectations, such as longitudinal It is necessary to use relatively short fibers to achieve better practical characteristics there were.   Long fibers may be loose due to their excessive entanglement tendency and the formation of ropes and strings. It is not used in wool products made of fiber. Thus, long fibers can be used without binder Also show some entanglement among the fibers, but the resulting wool pack is uneven. Uniformity has long made them commercially undesirable. Purpose of this patent specification Therefore, when using the terms "short fiber" and "long fiber", the term "short fiber" , About 25. The term "long fiber" is intended to include fibers of 4 millimeters (1 inch) or less. Wei '' is about 50. It is intended to include fibers longer than 8 millimeters (2 inches). Scripture Typeically, Wool packs of staple fibers manufactured by rotating fiber forming technology, Woo It contains some long fibers that make up less than 10% of Lupac.   Long fibers have different aerodynamic properties, Conventional wrapping technology Long or half Failure to remove the formation of ropes and strings on the veil of continuous fiber, Rather this Tends to increase. Even when not disturbed, Veil slowly descends to collection surface and when, Veils of long fibers tend to form ropes and strings. Transfer of collection surface Regardless of the movement, Long glass fiber (Like a disturbed bale of short fibers) Overlaps into an uneven pack of fibers, Tends to cumbersome fiber deposits You. These non-uniform packs, some of which are characterized by rope and string formation Is Significant commercial use of long fibers has long been hampered. Long fiber ropes are commercial Create an undesired look, More importantly, departures from an ideal uniform grid Make Reduce the insulation capacity of glass wool.   rope, string, And excessive entanglement of long fibers Commercially desirable longitudinal Direction separation characteristics, Makes practical installation more difficult.   However, Short fiber insulation does not have that problem. Even straight short fibers, Forming only a coincidental grid, Some of the fibers are bundled together and piled up. as a result, Already The existing glass wool insulation material is Has significant unevenness in the distribution of fibers in the product Keep going.   A further problem with short fiber wool is The binder used is expensive, How many It has some environmental disadvantages. Most binders contain organic compounds , Treating wastewater from manufacturing processes to improve the negative environmental impact of such compounds Must. in addition, The need to oven cure the binder is additional Energy is consumed, Incurs additional environmental cleaning costs. When you compress the product Come Additional problems with short fibers arise. Binder is used at the intersection of fibers. It is lit, When the stress on the fiber increases due to excessive compression, Fiber is Expires. Thus, While current insulation products still achieve sufficient recovery, Yes The amount of effective compression is limited.   Nevertheless, Because long fibers have problems in almost every respect, Lattice Uniform, The need for binders, And the shortcomings of short fibers with limited compressibility Nevertheless, Only straight short fibers for commercial wool insulation products of glass fiber Has been used for a long time. Therefore, Improve the characteristics of wool pack, Lower costs, environment There remains a need for further improvements in wool insulation products that eliminate the above problems.   [Disclosure of the Invention]   The present invention Provides a method to further define the shape of long glass fiber wool packs To fulfill that need, Each method almost maintains the uniformity of the grid, Removes the need for binders, Significant compressibility and desirability for commercial products This results in a wool pack that is resilient and recoverable.   According to the present invention, Long fibers of a single glass composition, As well as non-linear bicomponent fibers Long fiberglass wool pack containing fibers comprising two glass compositions to be produced I will provide a. Collection of long fiber in wool pack Bale from rotating fiber forming machine Received on a pair of high-speed rotating perforated drum-shaped surfaces, Suction of gas in the bale from drum surface Separated from the fiber by The remaining fibers are transported at high speed through the narrow gap between the drums. This is achieved by forming the web at The drum surface is Veil on drum Operated at high speed to have a surface speed in the range of about 50% to about 150% of the speed of the It is. Then The web is distributed to form a wool pack. Woo made The fibers of Lupac are distributed randomly and unevenly. As another example, Wool pad Collection of long fibers The second veil facing the bale produced by the rotating fiber forming machine 1 on the perforated conveyor surface, Remove the gas from it, Pass the remaining fiber through the passage Carry on the second conveyor side, Substantial fiber orientation established by the rotating fiber former Is achieved by maintaining The fibers of the resulting wool pack are Almost spiral Orientated to Interrelated.   The method for producing these wool packs is It was used together here, Book Assigned to the same person as the assignee of the request, Aschenbeck Wool pack forming method using high-speed rotating drum and low-frequency sound distribution according to () WOOL PACK FORMING PROCESS USING HIGH   SPEED ROTATING DRUMS AND LOW FREQ NCY SOUND DISTRIBUTION) May 1994 U.S. patent application Ser. No. 08/236, filed on the 2nd. No. 067, And Grant (Gr Direct molding method for collecting long wool fibers (DIRECT FO) RMING METHOD OF COLLECTING LONG WOOL   FIBERS), U.S. Patent Application No. filed May 9, 1994 08/239, No. 820 is described in great detail.   Wool packs of long fibers produced by either method have almost uniform distribution of fibers Has, There is almost no rope formation. Such a wool pack, First by forming process Formed into In order to form products by packaging with plastic, Or, Another example And may be formed by the method disclosed in more detail below.   As used here, The term “long fiber wool pack” Almost by number or weight A wool pack having a substantial proportion of 50% or more long fibers, I Woolpa having less than a few percent (greater than about 10%) long fibers May include Nevertheless, those having a higher percentage of long fibers Shows the properties of the tool pack.   The long glass fiber wool pack provided by the present invention, Unique product formation Problems. Long fibers are somewhat entangled compared to short fibers, Made without binder Built. Early wool pack shapes are provided as described above, Wrapped in film Can be held by wearing In wool packs for various products Larger formation is desired. No thicker binder for long fibers in the present invention Mat and wool pack, Products not previously adequately addressed by the prior art Has the problem of formation. The present invention Conventional binder combined with heat set Long fibers that tend to form bundles without being easily adapted to the shape by the application of Especially Attempts to give shape to wool packs containing irregular bicomponent fibers. Moreover, Long fiber Wei's entanglement While installing around obstructions, Commercial for longitudinal separation of packs Makes the desired features difficult, The present invention Longitudinally separable, That is, "Discount Attractable "packs.   Thus, The method of the present invention comprises: First, Long single component, And especially Two-component glass fiber Thick, Various binders that cause product formation in binderless wool packs Provide an alternative method. The method is Including the step of disrupting the fiber matrix of, Including adding the element to the fiber matrix, And the stage to melt the fiber They are grouped apart to include floors. Especially, Irregularly formed The long bicomponent fiber Because of the excess caused on the surface of the wool pack Engagement was found to have a negative effect on recovery. Moreover, For example, Needlin According to Excessive disturbance of the fiber matrix beyond the surface Wool pack The entangled irregularly formed fibers are straightened, Wool pack Have been found to lose some of the desirable volume filling properties that add value to the product. Scratch do it, Retains important commercial and functional characteristics, To provide the desired product formation Attention must be paid.   The method of the present invention for disrupting a fiber matrix comprises: According to the present invention, Thicker fiber Glass mat, That is, Use for mats that are over 76mm (3 inches) thick Includes rising water entanglement and air knife entanglement techniques. Heated A needle punch using a needle is further disclosed herein.   Those methods of the invention for adding an element to a fiber matrix include: Along multiple locations Adhesive string or thermoplastic string into the width of the wool pack That is, Activity Surface melting of thermoplastic resin spray or thermoplastic resin fiber by hot surface heating, the first Post-production addition of thermoplastic resin fibers to hot wool packs from the formation of And fiber Sutures in parts, including. These methods are generally less invasive than the first group , Defined parts in the fiber matrix, That is, It only disturbs multiple rows.   The method of the present invention, including the melting of the fibers, provides Use of the Surface area of fiber by heated hot plate or fiber by heated needle Melting of other groups of Wei, And lower melting temperature glass or other thermoplastic components Including the use of bi-component fibers containing one of the more easily meltable materials as one component . These latter methods of melting are the least intrusive, Write the matrix Without disturbing or introducing additional ingredients into the wool pack Partly, That is , Includes only multiple rows of fiber matrix.   The method of the present invention comprises: Second, Can be separated longitudinally as desired for mounting, That is, Various alternative methods of producing splittable packs are provided. Percent of long fiber Prepare a pack that can be used A predetermined first weight and a second weight of long-fiber wool pack; This is achieved according to the invention by laminating the layers. Each layer, Just mentioned Process sequentially into the desired packs formed by one of the methods. The upper layer, Up During or after formation of the part layer, Attaches to bottom layer. In addition to it, One or more planes The wool pack that can be separated along By stacking multiple wool pack layers Can be formed.   These methods and other features and advantages of the present invention are illustrated in the drawings and the detailed description below. The details are shown below. [Brief description of drawings]   FIG. 1 is a schematic side view of the method of the present invention.   FIG. 1 is a perspective detail of one embodiment of the invention performed at B in FIG. It is a schematic diagram.   FIG. FIG. 1 shows an apparatus representative of some embodiments of the present invention performed at B in FIG. FIG. 4 is a detailed schematic view in perspective.   4A to 4D are: Summary of Wool Pack Fibers Correlated by the Invention It is a schematic sectional drawing.   FIG. 5 is a schematic view of the laminating process representing the present invention in the perspective method.   FIG. Schematic sectional view of a wool pack in a laminated structure bonded according to the present invention It is.   FIG. 1 is a perspective view of a splittable wool pack according to the invention. [Embodiment of the invention]   The method of the present invention comprises: As shown diagrammatically in FIGS. It is used to make wool packs 78 that can be used.   Referring to FIGS. 1 to 7, The method for forming splittable wool packs is , Defining at least two binderless wool packs of long glass fiber (FIGS. 1 to 4D), Laminated relationship that allows wool packs without binders to be separated from each other It can be seen that the process is started by attaching (FIGS. 5 to 7). Long fiber shown below According to a preferred method of manufacturing the binderless pack 48 of the fiber 16, Each wool Pack 48 Having long glass fibers 16 distributed substantially uniformly, Almost oriented May have long glass fibers 16.   Defining the shape of each binderless wool pack 48 of long glass fibers 16 Is The wool pack 48 may be substantially reduced by any of the various methods further disclosed herein. Including correlating the first plurality of long fibers of a particular portion. The term "almost special Fixed) It is used to describe the parts of the wool pack 48 so interrelated. Used Almost certain of them are also Wool pack 48 "targeted" " It is referred to as "defined," "limited," "separate," "separated," and the like. FIG. As can be seen in FIGS. Many of them are Various methods disclosed A portion 88 (shown in FIG. 2) or region in a spaced relationship from group, Duplicate Sequence 100, Diagonal line 102, Flat part 104, Or in the connection of other fibers 16 is there. Nevertheless, Due to this relationship, wool pack 4 without binder 8 is maintained in the shape of the desired thickness.   Referring to FIGS. 5 and 6, The binderless wool packs 48 are laminated together Attached to a separable relationship Wool pack 48 adjacent almost specific Including interrelating the second plurality of long fibers 79 of the portion. Wool pack 4 8 is At least the top wool pack layer 82 is over the bottom wool pack layer 80 Positioning. Pack layer 80, The adjacent face of 82 Generally binder A flat surface 83 from which the wool-free pack can be separated. Middle wool pack layer 8 1 As shown in FIG. 6, a plurality of separating surfaces 83 may be further provided. Wool pack 48 is preferably of a predetermined weight, When stacked completely Offered as a formed wool pack, Or wool like a top wool pack Before attachment to an adjacent layer with at least one of the packs, Formed after or during deposition Be prepared to be. Thus, Determine the shape of the wool pack 48, Wool pad Can be attached to the stacked relationship. It is done sequentially or simultaneously.                                 Forming technology   As typically shown in FIGS. 1 to 4D, The method of the present invention uses a long glass fiber 16 Used to define the shape of the wool pack 48.   Referring to FIG. The method is A bag of long glass fibers 16 distributed almost uniformly. According to the present invention, it is possible to start by providing a wool pack 48 without an inder. I understand The rotating fiber forming device 11 is shown schematically. Then As widely described , Defining the shape of the long-fiber wool pack 48 can reduce the wool pack to a first thickness. Compress (as shown in B), First multiple long fibers of a particular portion of wool pack 48 Including interrelating fibers 16. afterwards, Release the pack (instruct C like), Moreover, First multiple long fibers 16 Wool pack 48 to desired thickness Remain sufficiently interconnected in tension to maintain the shape of the First Many fibers 16 of Unclear bundles with only the initial shape, That is, Pa Due to the tendency of the wool packs 48 to return to the pocket, they are placed in tension. For shipping (As shown by D) When further compressed to a smaller second thickness, Fiber 16 Ideally bend the fiber by the interrelation established between Further compression is reduced When Wool pack 48 recovers to its desired thickness.   Short glass fibers correlated with generalized application of binders during fiber formation Unlike conventional wool packs, The present invention Wool without binder of long fiber 16 Mainly discloses a post-production method for correlating specific parts of the Lepack 48 .   According to the method of the present invention, The first plurality of fibers 16 of the wool pack 48 are additional Whether they are interconnected by entanglement or interconnected Or both. However, Pour enough additional entanglement of fiber 16 Caused on the surface of the Giving good pack shape formation is After compression, Pack Was found to have a negative effect on the recovery of Therefore, Compression of wool pack 48 , Two sides of wool pack 48, Relative motion between the contacting compression surface 84 Preferably occurs substantially without The long fiber 1 thus in contact with the compression surface 84 Maintain the interrelationship between the six.   As shown in FIG. The compression surface 84 is a continuous belt, Instead parallel Or a plurality of smaller continuous belts in a row, Or move the wool pack 48 A plurality of rollers oriented transversely to the direction of movement, Or yet another structure or A combination of such elements may be used. Especially, The pack compresses the fibers and interconnects them Where to stop to The compression surface 84 By a plate or other harder stationary surface Provided. Anyways, The compression surface 84 Perform the necessary compression, Not required Without making a wool pack 48 (gap, space, Through the open structure ) As long as you can take the steps to interrelate, Accurate configuration of compression surface 84 And combinations are not essential to the invention.   First multiple long fibers 16 interrelated in wool pack 48 in accordance with the present invention Is Distributed randomly, Or, for example, Generally oriented in near horizontal or spiral relationship Is done. The long fiber 16 is straight, Formed of a single glass, Or, Irregularly It may be a formed bicomponent fiber. Moreover, The method disclosed here: First Separately or in combination to correlate the fibers of multiple wool packs Can be performed. The method of the present invention also Other thermoplastic polymers and mineral fibers I find use of Ip, Their application to long glass fibers without binder is preferred New   According to the present invention, To create the interconnections and more precisely the interconnections between the filaments 16 Several methods are provided, including fusing a number of long fibers 16.   In the first such method, Compressing the wool pack 48 to the desired thickness, Wool pad A first plurality of long fibers 16 of a particular portion of One side of wool pack 48 Correlated by contacting at least a portion with heated surface 86, First Many long fibers 16 of Heat the fibers to define the shape of the wool pack 48 Thereby bonding them together to that part of the wool pack 48. Referring to FIG. When, The heated surface 86 is preferably Applied to successive wool packs 48, excess It is good to move with the puck to avoid entanglement on the surface. With another example The heated surface 86 may be applied to a stationary wool bat. The heated surface 86 , For example, A hot plate that is actively heated may be used, Or by placing it in an oven It may be heated dynamically.   The heated surface 86 Edge of wool pack 48, corner, Or of a wool pack along the surface In part, Alternatively, the wool pack 48 is pressed into the mold at such a location. FIG. As indicated in part 88, The fibers 16 on the face and edge of the wool pack 48 Wool packs 48 are typically placed on track structures (not shown) to couple to each other. Figure 7 shows a series of heated surfaces 86 moving with. The heated surface 86 Melted Especially at the target power and temperature which determine the number of fibers 16 and the depth of penetration into the pack Designed. The texture of the melted surface portion 88 is bent from flexibility and flexibility. Changes in hardness and hardness.   The long fibers 16 In the case of a bicomponent fiber comprising two materials with different melting points, Heating surface Below the melting or softening point of one material, And the temperature above the melting point of the other material Heat each time, Therefore, The first plurality of long fibers 16 are interconnected by two bicomponent fibers. Melting substantially one of the materials, This is done by softening.   First multiple long fibers 16 Wool pack 4 in specific parts of wool pack 48 8 which are interconnected by positioning the heated surfaces inwardly from the surface 8 Is provided by the present invention. in this way, The heated surface is preferably Addition The heated needle 90. Compressing the wool pack 48 to the desired thickness, First many The contact with the number of long fibers 16 Reduce heated needle 90 with less wool pack 48 Both are done by inserting the wool pack 48 from one side. Heel Insert Constitute at least some portion of the path of movement of the needle, First many fibers The mutual connection of the fibers 16 is performed along the movement path of the needle. Needle movement The road is also the route of its retreat, And while being inserted into the needle, Wool pack 48 Includes any lateral movement with respect to. Thus, Needle has no binder An internal interconnect is formed between the first plurality of long fibers 16. 4A to 4D As shown, if, Move the heated needle 90 somewhat with respect to the wool pack 48 If you let Depending on the travel route, These interconnections are put in a plurality of rows 100, Diagonal Along the line direction 102, Or, it is oriented along the short plane portion 104. needle Penetration varies with depth and angle, Apply from both sides of wool pack 48 Can be All of the penetrations Depends on the special requirements of the product being manufactured. Preferably , A number of heated needles 90 Wool pack 48 whole for product formation Into each place. Some possible patterns in this regard Are shown in FIGS. 4A to 4D, The present invention Restrict to the illustrated example pattern Not something.   again, The long fibers 16 When two components of two materials with different melting points, D Dollars Below the melting point of one material, And heated above the melting point of the other material, Follow hand, The interconnection of the first plurality of long fibers 16 constitutes mainly one of the two materials of the bicomponent fiber. Melts, Alternatively, it can be performed by softening.   The needle used by this method is Preferably, Smooth conductive metal knee Dollars, Minimize entanglement of related fibers caused by its use And Or rough to intentionally create intertwining at some level of fiber May be.   First multiple long fibers 16 To heat the fiber part of wool pack 48 Wool inward from the surface of the wool pack by applying laser light energy A third method of interconnecting certain parts of the pack 48 is provided by the present invention. provide. Preferably, A row of laser light sources 92 (shown in FIG. 3) Laser light Apply energy to the wool packs 48 at spaced locations throughout each It is good to provide in. The laser source 92 Sufficient to cause melting between the fibers 16 Any conventional laser source capable of generating sufficient heat may be used. Woolpa Density of the hook 48, The shape of the fiber 16, And the strength of the product (shape) Power) and beam width. Changes in intensity and beam width Penetration depth and Affects the number of fibers 16 that are interconnected. Moreover, Glass fiber is Those Opaque, Or additives to better absorb the specific laser light applied including. The laser beam 94 The first plurality of fibers 16 are arranged in a plurality of rows 100 or diagonally. Vertical or diagonal to the wool pack 48 to melt into a group oriented in a linear direction Hit As exemplarily shown in FIG. From any side of wool pack 48 May be. This third method also Beam intensity One fiber component is replaced by the other Set goals to influence more than minutes, Or additives Laser of one fiber component -Includes to improve light absorption, Can be used with bicomponent fibers, Melted Let Provides the interrelationship between many types of fibers in addition to the glass fibers referred to here. Can be used to   According to the present invention, Polymer to provide an interconnect between the first plurality of fibers 16 Fourth to sixth methods comprising adding an element, such as a material, to the fiber matrix; and Several methods are also provided. Thus, again, Referring to FIG. The present invention The fourth method of Before or simultaneously with compressing the wool pack 48, Wool pack 4 8 (shown in A) on a portion of the surface of hot melted polymer spray or polymer fiber Distribute 96, Then Melting or softening the fibers, And the first many vines Wool packs 48 (B Heating) (as shown in FIG. 2). Polymer selected for polymer fiber 96 Is It is possible to bond glass fibers to each other when melted and softened, compression Release the power, When in tension, Strong enough to maintain such interconnections, During compression of wool pack 48, Any flexible polymeric material may be used.   At least some of the surface of the wool pack 48 of hot melt polymer spray or polymer fibers 96 Distribution on the part Whether on or near the face of wool pack 48, or Is being melted or softened to be located inward from the surface, Where the glass fiber is positioned Trying to The glass fibers 16 are interconnected. The method further comprises: Wool pack 4 By distributing a polymer fiber 96 of a size that snugs inwardly from the surface of FIG. Is implemented. The longer and shorter polymer fibers 96 are both , Dispersed to provide interconnection within the depth of the wool pack 48.   As another example, The fourth method is About 93 ° C to about 204 ° C (about Fahrenheit Wool pack coming out of the forming process at a temperature of about 200 ° F to about 400 ° F) It is preferably performed immediately after the formation of 48. Thus, The method is Has the latent heat of the product, A wool pack that distributes the polymer fibers 96 over a portion of the surface of the wool pack 48; And providing the client 48. The polymer fiber 96 is Before the compression stage (indicated by B) During or during the phase, Good to distribute. Fibers of different sizes, Wool pack 48 Utilized to provide interconnection at different depths. In addition to it, Polymer fiber 9 Even if the step of heating to further melt and soften 6 is omitted, Or polymer fiber This may be done to further melt and soften 96 (as indicated by H).   The elements are placed in a wool pack 48 to create an interconnect between the first plurality of fibers 16. A fifth method is provided that also includes an adding step. The fifth method is Long fiber without binder The mutual coupling of fibers 16 The flow of the polymeric material is directed to the first throughout the wool pack 48. Infused into a number of spaced apart locations of Bonded together by such a polymeric material Forming a first plurality of rows 100 containing the filled binderless filaments 16 And provided by. As exemplarily shown in FIG. The polymeric material is preferably The injection may be performed by a plurality of injection needles 98. The injection needle 98 C Roll pack 48, Preferably, At least one of the wool packs It may be injected into the wool pack 48 from one side. As explained above, The injection of the injection needle 98 with the heated needle 90 Flow of polymer material injected At least a portion of the travel path to be performed. Such an injection, Preferably, Woo The compression is preferably performed at the same time as the compression of the pack 48 to a desired thickness. again, if, note If the input needle 90 is moved somewhat with respect to the wool pack 48, 4A through As shown in FIG. 4D, The mutual connection formed by the movement path Diagonal direction 102 along, Or, it is oriented in a plurality of rows 100 along the short plane portion 104. Hide hand, The penetration of the injection needle 98 can vary in depth and angle, Wool pack 4 8 can be applied from both sides, All of the penetrations For special requirements of manufactured products Dependent. Moreover, The injection needle 98 From the tip of the polymer, Or its length At least one opening along Or both. Injection knee Dollar 98 is Determine the number of fibers 16 to be bonded and the depth of penetration into the pack Specially designed with target pressure and flow width.   Wool packs 48 are used to provide elements to provide interconnection between the first plurality of fibers 16. A sixth method is provided that also includes adding The sixth method is Simultaneously with the compression stage At least one fiber 106 into a wool pack 48 of long glass fibers 16 It consists of intermittent insertion. The thickness of the wool pack 48 is Typically 76. Greater than 2 mm (3 inches). According to the method, the plurality of discrete fiber portions 106 Is preferably inserted into the wool pack 48 at spaced locations. That's it The fibers 106 tend to deform, otherwise such deformations may occur. Correlate with binderless filament 16 to lock in place by shape, Thereby, the first plurality of fibers 16 are interconnected. As another example, FIG. Suturing with a row of suturing needles in a manner such as a heated needle 90 I will provide a. When the pack is compressed to a first thickness, a suture needle is used to Fibers or other material fibers are introduced into the pack. This can be fiber 106 or continuous A plurality of rows 100 of interrelated fibers 16 are made by the various fibers 108. But Meanwhile, the number of the fibers 106 put in the wool pack 48 and their interval are Depends on the amount of shaping of the particular product. Anyway, because the spacing is like that, The resulting entanglement of the wool pack 48 restores the entire wool pack 48 Is not adversely affected. In addition, the stitched fiber or the stitched continuous fiber 1 08 has a plurality of rigid rows in tension and a plurality of flexible rows in compression. Occurs. Threads 106 or fibers 108 maintain communication between the top and bottom surfaces of the pack. Specially designed with a weave that resists heat flow and strength.   Finally, the wool pack 4 is used to provide interconnection between the first plurality of fibers 16. A third group of methods comprising perturbing the fibrous matrix of claim 8 is provided by the present invention. Offer. These methods are based on the thick wool pack of long fibers 16 provided by the present invention. Water entanglement and air entanglement methods compatible with the hook 48. In particular, the eighth The method involves compressing the wool pack 48 into a desired shape while simultaneously providing a high speed, low volume flow of fluid. Of the long fibers 16 by injecting into Are interrelated. This means that, referring to FIG. Can be understood. The fluid is preferably water, but the Alternatively, it may be steam, air, another gas or a combination thereof. Fluid The flow drags the individual fibers 16 to a new location within the wool pack 48, and the area Causes entanglement of those fibers 16 with other fibers. Wool pack 48 After releasing the finished product will achieve the desired shape as a result of entangled fibers I do. The volume of the fluid used and the pressure to be injected depend on the fiber diameter, product density and product Depends on thickness.   Verdan (B), assigned to the same assignee as the assignee of the present application, incorporated herein by reference. erdan) and bicomponent and long-fiber product formation (BICOMPONENT A) ND LONG FIBER PRODUCT DEFINITION) Related Application, US Patent Application Serial No. 08/27, filed July 25, 1994. No. 9,613 describes this further.   The various methods mentioned above use wool to provide additional shape and product formation. Providing the desired correlation between the first plurality of fibers 16 of the pack 48. Of this method Implementation varies depending on the product being manufactured. Nevertheless, the method does not Especially with irregularly formed bicomponent fiber binderless wool packs 48. Share a common ending dealing with the unique issues raised.                                 Lamination technology   Referring now to FIGS. 5-7, the method of the present invention further provides To produce a pack 78 that is longitudinally separable, i.e., splittable. Provides alternatives. Thus, adhere the laminated wool pack The step of interconnecting the second plurality 79 of long fibers 16 in order to Bring the fibers into contact with a heated surface, such as a hot plate or needle, Heated with rubies, and the fibers are prepared with a polymer material, for example, by mixing or mixing the fibers. It can be done by injection or by a combination of these methods. These methods have in common the mutual relation of the second number of fibers by mutual bonding . According to the invention, heating a second plurality of long fibers with laser light energy Preferably, they are interrelated.   As disclosed above, a second plurality is required to apply the laminated wool pack. The step of interconnecting the 79 long fibers 16 may also include the use of a high velocity flow of fluid at a distance. At this point, the wool pack 48 is injected into a substantially specific part and the needles are spaced apart. Pour into the wool pack at the location where This can be done intermittently by inserting into the lock, or a combination thereof. This These methods result in a second plurality of fibers being interrelated by fiber entanglement. Have in common.   The technology used to construct the shape of the wool pack 48 is combined with the wool pack 48. When the technique used to deposit the layer relationships is the same, It is preferable to form the upper pack layer 82 after lamination. Thus, according to the invention After positioning the upper wool pack layer 82 on the lower wool pack layer 80, Correlating a first plurality of fibers of a wool pack with adjacent wool packs; The steps of correlating the second plurality 79 of the clips 48 are performed. Upper wool pack layer The formation of 82 may be performed simultaneously or sequentially with the deposition of layers 80,82. Some people Wool-pack structure laminated and formed by the same method with respect to the method Perform up to 76 different depths. That is, the first plurality of fibers are interrelated. Is performed to a first depth substantially extending only into the top wool pack layer 82, Correlating the second plurality 79 includes an upper portion in the top wool pack layer 80. This is done to approximately the second depth extending through the wool pack layer 82. in this regard, Hot needle injection, laser bonding, needle punch, water entanglement, and suturing , As well as the fastening technique, the interrelation of the second plurality 79 of long fibers 16 A first plurality of long fiber interactions is achieved simultaneously. The polymer material is Other techniques, such as injecting from the face of an opposing wool pack, involve needles in a second multiple By limiting the injection of polymer until it has been placed in Specially targeted to correlate only the second multiple 79 fibers .   An intermediate wool pack layer 81 is provided to constitute a number of separating planes 83 In each case, as just described for the exemplary two-layer structure described above, Lupac layer 81 is sequentially deposited or formed and deposited on one or more lower layers. It can be understood that it can be done.   However, in this regard, a second large number of fibers were laminated their methods. By performing from at least one side 77 of the woven wool pack structure 76. Special targeting by each of the methods outlined. As shown in FIG. When performed from side 77, a second plurality 79 of fibers are placed in rows 110, diagonals 112 Or between the adjacent portions of the planar portion 114 or the laminated wool pack 48. Can be correlated along or across an area positioned . The separating plane 83 of the splittable pack 78 is constituted by it and The method employs a second plurality 79 of fibers 16 without requiring penetration into the thickness of the layer. Is more accurately targeted. The approach from the side 77 of the stacked structure 76 Is advantageously configured in a splittable pack 78.   Before placing the wool packs 48 in a laminating relationship and joining, some laminating techniques may be reduced. Also need to be partially implemented. Forming technology and lamination technology are completely different The lamination technique is further illustrated. For example, referring to FIG. 5, how a wool pack Regardless of forming 48, heat wool pack 48 as typically shown. The molten polymer is sprayed or adhered in a laminated relationship with the applied polymer fibers 96. Polymer Is applied prior to the lamination step, and the polymer is applied to the At least one is applied to at least one surface. Thus, of the fibers being joined The second plurality 79 is generally on or near the sides or surface of the wool pack 48.   If a hot melt polymer spray is used, the polymer is preheated. Uses polymer fiber 96 If so, the polymer fibers are wooled to bond a second plurality 79 of fibers together. After application to the pack 48, it is melted. Melts the polymer and joins the glass fibers Heat is provided as latent heat in the manufacture of the wool pack 48. Instead, heavy Heat may be applied to the surface of the wool pack 48 before or after the application of the united fiber 96. Figure 5, typically by heated rollers 89 prior to application of the fiber, or Heating to a surface can be performed mechanically in the radial direction with a heating lamp. Moreover After the application of the fibers or the lamination of the wool pack 48, the polymer fibers are melted and Via a heating lamp or heated gas to join the packs 48 in a stacked relationship Heat can be applied.   The preferred polymer material for the hot melt polymer spray or polymer fibers 96 is polyether. Tylene, preferably linear low density polyethylene or polypropylene, ethylene Vinyl acetate, or combinations thereof, or other suitable polymeric materials. The hot melt polymer spray is preferably a polymer that is pressure sensitive, and thus When the layers of the pack 48 are compressed into contact, the second plurality 79 of fibers will adhere and form a phase. Interrelated and joining layers.   Thus, the shape of the wool pack 48 used for the splittable pack is determined. And the technique used to attach the wool packs 48 in a stacked relationship. The techniques may be the same or different. Nevertheless, wool packs When the shape of the wool pack 48 is determined later, the forming step is more preferable. Alternatively, compressing at least a portion of the laminated wool pack structure to a first thickness The first plurality of long fibers 16 to maintain the shape of the wool pack in the desired thickness. Including interrelating at substantially specific portions of the tool pack 48. Second majority 7 9 long fibers 16 are simultaneously inserted into adjacent almost specific portions of the wool pack 48 almost simultaneously. Preferably, they are maintained in a stacked relationship as desired, and then 1, releases the wool pack 48 from compression, as best illustrated in FIG. That Alternatively, the wool pack 48 is released from compression and then a second multiple 79 long fiber The fibers 16 may be interconnected.   According to the present invention, finally, defining the shape of the wool pack comprises two successive After laminating the wool packs and attaching them, the attached wool packs are as shown in FIG. Cutting into slicable wool packs 78 of defined length. Instead Alternatively, at least one of the wool packs 48 is placed in the laminating stage indicated in FIG. It may be cut into wool bats having a predetermined length. Anyway, the present invention Is a long binder that is substantially splittable along at least one plane 83. A glass fiber splittable wool pack 78 is produced.   Some representative embodiments and details have been set forth for the purpose of illustrating the invention. However, various modifications of the method and apparatus disclosed herein are set forth in the following claims. It will be apparent to those skilled in the art that modifications can be made without departing from the scope of the invention as set forth. Or maybe.

──────────────────────────────────────────────────の Continuation of the front page (51) Int.Cl. ⁶ Identification code Agency reference number FI E04B 1/86 0230-2E E04B 1/86 A (81) Designated country EP (AT, BE, CH, DE, DK) , ES, FR, GB, GR, IE, IT, LU, MC, NL, PT, SE), OA (BF, BJ, CF, CG, CI, CM, GA, GN, ML, MR, NE, SN , TD, TG), AP (KE, MW, SD, SZ, UG), AM, AU, BB, BG, BR, BY, CA, CN, CZ, EE, FI, GE, HU, IS, JP, KG, KP, KR, KZ, LK, LR, LT, LV, MD, MG, MN, MX, NO, NZ, PL, RO, RU, SG, SI, SK, TJ, TM, TT, A, UZ, VN

Claims (1)

[Claims] 1. Define at least two binderless wool packs of long glass fiber ,     The at least two binderless wool packs into a separable stacking relationship Produces splittable wool packs of long glass fibers, consisting of adhering to each other The way to build. 2. Shape at least two binderless wool packs of long fiberglass The step of forming includes, for each wool pack, forming the wool pack into a desired thickness. A first plurality of long fibers which are maintained in a shape, The method of claim 1, comprising the step of associating. 3. Bonding the at least two binderless wool packs in a stacked relationship to each other The step of maintaining the wool packs in a stacked relationship in a second multiple length. Correlating the fibers to adjacent substantially specific portions of the wool pack. The method of claim 1. 4. The step of correlating the second plurality of long fibers comprises laminating the second plurality. Heating with the light energy to bond the second plurality of long fibers to each other. 4. The method of claim 3, wherein the method is performed. 5. The step of correlating the second plurality of long fibers comprises the second plurality of fibers. Is brought into contact with the heated surface, and the second plurality of fibers are applied with laser light energy. Heating, bonding the second plurality of fibers with a polymeric material, or a combination thereof. 4. The method of claim 3, wherein the method steps are performed from a group. 6. The step of interconnecting the second plurality of long fibers comprises spacing the high velocity flow of the fluid. Inject into a nearly specific part of the wool pack at a separate location and separate the needles Into the wool pack at a distance from each other and remove at least one fiber from the wool pack. From the group consisting of intermittent packs or a combination thereof 4. The method of claim 3, which is a legal step. 7. The step of correlating the second plurality of long fibers comprises the second plurality of long fibers. 4. The method of claim 3, comprising melting the fibers. 8. The step of interconnecting the second plurality of long fibers comprises the second plurality of long fibers. A part of the binder-free wool pack consisting of fibers is formed and connected with a polymer material. 4. The method of claim 3, comprising dressing. 9. The step of depositing separates the at least two binderless wool packs. Prepare in a remote relationship,     Locating at least one said wool pack substantially near a surface of the polymeric material; Is applied to the second plurality of long fibers at the portion of     Positioning the at least two binderless wool packs in a stacked relationship , The surface of the at least one binderless wool pack to an adjacent woofer. Contact the opposing surfaces of the     By attaching the second plurality of long fibers with the polymeric material, 2. The method of claim 1, comprising associating. Ten. The step of applying the polymer material includes sprinkling and spraying the polymer material. 10. The method steps of claim 9, wherein the method steps are performed from the group consisting of: the method of. 11． Attachment step is to place at least the top wool pack on the bottom wool pack The method of claim 1, comprising determining. 12． The step of positioning comprises the at least two binderless wool packs. Further comprising defining at least one plane that is substantially separable. The method described in. 13. Shape at least two binderless wool packs of long fiberglass The step of forming includes, for each wool pack, forming the wool pack into a desired thickness. A first plurality of long fibers which are maintained in a shape, Including the step of associating,     The at least two binderless wool packs into a separable stacking relationship The method of depositing may include applying a second multiple to maintain the wool pack in a stacked relationship. Correlating a number of long fibers to adjacent substantially specific portions of said wool pack The method of claim 11, comprising a floor. 14. Said step of correlating the first majority and correlating the second majority Said steps to different depths, said step of correlating a first plurality. Is performed to a depth that extends substantially only into the top wool pack, and a second The step of interconnecting extends through the top wool pack and into the bottom wool pack 12. The method of claim 11, wherein the method is performed to a depth. 15． Said step of correlating the first majority and correlating the second majority 12. The method of claim 11, wherein said steps of performing are performed by different techniques. 16． The step of depositing includes removing at least one intermediate wool pack from the upper wool. Positioning between a pack and said bottom wool pack,     The steps of forming and adhering generally involve less wool pack separation. The method of claim 11, further comprising configuring two planes. 17． 2. The method according to claim 1, wherein the step of attaching is performed continuously after the step of forming. The method described. 18． The step of adhering includes forming at least one of the wool packs. 2. The method of claim 1, wherein the method is performed qualitatively simultaneously. 19. Compressing at least a portion of the at least two wool packs to a first thickness And     In order to maintain the shape of the wool pack in a desired thickness, a first plurality of long fibers are used. Interrelated at substantially specific parts of the wool pack,     To maintain the wool pack in a stacked relationship, a second plurality of long fibers Adjacent substantially specific portions of the tool pack at substantially the same time,     Releasing said at least two wool packs from compression;     Thereby, the first plurality of long fibers are formed into a shape having a desired thickness. Leave enough tension on at least one wool pack to maintain Maintaining the second majority of fibers in a laminar relationship that allows the wool pack to be separated;     19. The method of claim 18, comprising the step of forming further comprising the step of. 20. Performing the step of interrelating the first plurality of long fibers further comprises: 20. The method of claim 19, wherein the second plurality of long fibers are correlated. twenty one. Forming the at least one wool pack having a defined length The method according to claim 1, comprising cutting into wool bats. twenty two. After the attaching step, the wool pack has at least a defined length. The method of claim 1, further comprising cutting into one wool bat. twenty three. Long, attached in a stacked relationship and substantially separable along at least one plane Long glass with at least two binderless wool packs of fiberglass Wool pack with splittable fibers. twenty four. The at least two binderless wool packs comprise a first plurality of long fibers. The desired thickness due to the interrelationships at approximately specific parts of the wool pack 24. The splittable wool pack of claim 23, wherein the pack is maintained in the shape of a bulk. twenty five. The wool pack without binder is almost specified adjacent to the wool pack. 24. The split of claim 23, wherein the portion is attached to the second plurality of long fibers in a laminated relationship. Possible wool pack. 26. At least one of the binderless wool packs is substantially uniformly distributed. 24. The splittable wool pack according to claim 23, comprising elongated glass fibers. 27. The long glass fibers in at least one of the binderless wool packs 24. The splittable wool pack of claim 23, wherein the pack comprises substantially oriented fibers.