Patent Publication Number: US-8118967-B2

Title: Methods of manufacturing paint roller covers from a tubular fabric sleeve

Description:
IDENTIFICATION OF RELATED APPLICATION 
     This patent application is a continuation-in-part of copending U.S. patent application Ser. No. 12/132,774, filed on Jun. 4, 2008, entitled “Methods of Manufacturing Paint Roller Covers From a Tubular Fabric Sleeve,” which is in turn a continuation-in-part of U.S. patent application Ser. No. 12/100,050, filed on Apr. 9, 2008, entitled “Methods of Manufacturing Paint Roller Covers From a Tubular Fabric Sleeve,” which is in turn a continuation-in-part of U.S. patent application Ser. No. 12/015,612, filed on Jan. 17, 2008, entitled “Methods of Manufacturing Paint Roller Covers From a Tubular Fabric Sleeve,” now U.S. Pat. No. 7,905,980, each of which patent applications are assigned to the assignee of the present invention, and each of which patent applications are hereby incorporated herein by reference in their entirety. 
    
    
     BACKGROUND OF THE INVENTION 
     Field of the Invention 
     The present invention relates generally to the manufacture of paint roller covers, and more particularly to methods of manufacturing paint roller covers from a seamless, tubular fabric sleeve having at least one of a backing material and a pile surface constructed at least in part of a low melt material that forms an integral core member and including a spray adhesive applied to the integral core member to enhance the rigidity thereof. 
     The two inventions which have had the greatest impact on paint application are the invention of the paint roller in the 1930&#39;s and the development of water-based paint in the late 1940&#39;s. While water-based paints are easy to mix, apply, and clean up, there is little doubt that the paint roller has been the greatest single time saving factor in the paint application process, allowing large surfaces to be painted with a uniform coat of paint quickly and easily. Typically, paint rollers are comprised of two components, namely a handle assembly and a paint roller cover for installation onto the handle assembly. 
     The handle assembly consists of a grip member having a generally L-shaped metal frame extending therefrom, with the free end of the metal frame having a rotatable support for a paint roller cover mounted thereon. The paint roller cover consists of a thin, hollow cylindrical core which fits upon the rotatable support of the handle, with a plush pile fabric being secured to the outer diameter of the paint roller cover. The core may be made of either cardboard or plastic material, with which material is used for the core generally being determined based upon the selling price of the paint roller cover. The pile fabric is traditionally applied as a strip which is helically wound onto the outer surface of the core with adjacent windings of the fabric strip being located close adjacent each other to provide the appearance of a single continuous pile fabric covering on the core. 
     Typically, the pile fabric is a dense knitted pile fabric, which may be knitted from natural fibers such as wool or mohair, synthetic fibers such as polyester, polypropylene, acrylic, nylon, or rayon, or from a blend of natural and synthetic fibers. The knitting is typically performed on a circular sliver knitting machine, which produces a tubular knitted backing or base material with a knit-in pile in tubular segments which are approximately fifty-eight inches (1473 millimeters) in circumference by thirty to fifty yards (27.43 meters to 45.728 meters) long (depending on fabric weight). 
     Generally, sliver knitting is a knitting process which locks individual pile fibers directly into a lightweight knit backing or base material in a manner wherein the pile fibers extend from one side of the knit base material. The knit base material itself is made from yarn, which may be knitted in a single jersey circular knitting process on a circular knitting machine, with closely packed U-shaped tufts of the fibers being knitted into the knit base material which anchors them in the completed pile fabric. The free ends of the fibers extend from one side of the knit base material to provide a deep pile face. The knit base material is typically made of synthetic yarns, with the pile being made of a desired natural or synthetic fiber, or a blend of different fibers. 
     Such fabrics are illustrated, for example, in U.S. Pat. No. 1,791,741, to Moore, U.S. Pat. No. 2,737,702, to Schmidt et al., U.S. Pat. No. 3,226,952, to Cassady, U.S. Pat. No. 3,853,680, to Daniel, U.S. Pat. No. 3,894,409, to Clingan et al., U.S. Pat. No. 4,236,286, to Abler et al., U.S. Pat. No. 4,513,042, to Lumb, and U.S. Pat. No. 6,766,668, to Sinykin, all of which patents are hereby incorporated herein by reference. Sliver knit high pile fabrics have been widely used for many years in the manufacture of imitation fur fabrics, and also have found use, for example, as linings for overcoats and footwear, as coverings for stuffed toys and floors, in applications in pet beds, case liners, boot and slipper liners, medical pads, and blankets, and, of course, as coverings for paint roller covers. 
     The components of the knitted fabric are a yarn, which is used to knit the fabric&#39;s knit base material, and fibers which are supplied in a “sliver” rope, which consists of fibers which are all longitudinally oriented in a rope which is typically less than three inches (76 millimeters) in diameter. The fibers are loose fibers of either a single type or a uniform blend of multiple types of fibers. The fiber mix will determine the performance, density, texture, weight, patterning, and color of the finished pile fabric. 
     The fibers are typically blown together in an air chamber to blend them, and then are carded in carding machines that “comb” the fibers to align them in parallel with each other. The fibers are then gathered into a soft, thick rope which is called “sliver” (which is the derivation for the term “sliver knit”) or “roving.” The yarn and the sliver are supplied to the circular knitting machine, which typically has eighteen heads and produces a tubular knit pile fabric which is approximately fifty-eight inches (1473 millimeters) in circumference. (Thus, when the tubular knit pile fabric is slit longitudinally, the fabric is approximately fifty-eight inches (1473 millimeters) wide.) 
     Such knitting machines are well known in the art, and are illustrated in U.S. Pat. No. 3,894,407, to Clingan et al., U.S. Pat. No. 3,896,637, to Thore, U.S. Pat. Nos. 4,532,780 and 4,592,213, both to Tilson et al., U.S. Pat. Nos. 5,431,029, 5,546,768, 5,577,402, 5,685,176, and 6,016,670, all to Kukrau et al., and U.S. Pat. No. 6,151,920, to Schindler et al., all of which patents are hereby incorporated herein by reference. Examples of commercial versions of such knitting machines are the Model SK-18 Sliver Knitter and the Model SK-18J Sliver Knitter which are available from Mayer Industries, Inc. of Orangeburg, S.C. 
     The first commercial circular sliver knitting machine had seven heads, and commercially-available circular knitting machines today have between seven and eighteen heads. Eighteen head knitting machines have upwards of one thousand needles, and produce tubular knitted segments that are approximately nineteen inches (483 millimeters) in diameter (fifty-eight inches (1473 millimeters) in circumference). All of these circular sliver knitting machines produce tubular knitted pile fabric segments having the pile located on the inside. Such circular sliver knitting machines are incapable of either producing tubular knitted pile fabric segments having the pile on the outside or small diameter tubular knitted pile fabric segments. 
     Following the manufacture of the tubular knitted pile segments on a circular sliver knitting machine, the tubular knitted pile segments are slit longitudinally to produce extended knitted pile segments of fabric which are typically fifty-eight inches (1473 millimeters) wide by thirty to fifty yards (27.43 meters to 45.728 meters) long. These extended knitted pile segments of fabric are then tensioned longitudinally and transversely, stretched to a sixty inch (1524 millimeter) width or greater to guarantee the proper number of two and seven-eighth inch (73 millimeter) strips, and back coated (on the non-pile side of the knit base material) with a stabilized coating composition such as a clear acrylic polymer. The coating composition which is coated onto the non-pile side of the knit base material is then processed, typically by heat, to stabilize the coated, extended knitted pile segment. The heating operation dries and bonds the coating composition to the knit base material, producing a fabric which is essentially lint-free. 
     The coated, extended knitted pile segment can then be subjected to a shearing operation to achieve a uniform pile length, with the sheared fibers being removed by vacuum, electrostatically, or by any other known removal technique. The pile density, the nap length, and the stiffness of the fibers are varied based upon custom specifications and the particular characteristics of the paint roller cover that are desired. 
     The sheared, coated, extended knitted pile segment is then slit into a plurality of two and seven-eighths inch (73 millimeter) wide knitted pile fabric strips, of which there are typically twenty for a sixty inch (1524 millimeter) wide fabric segment. During this slitting operation, the strips may be vacuumed to remove stray fibers and lint. The knitted pile fabric strips are rolled onto a core to produce twenty rolls of knitted pile fabric strips, each of which is thirty to fifty yards long. These rolls of knitted pile fabric strips may then be shipped to a paint roller cover manufacturer. Alternately, a plurality of standard lengths of the fabric may be seamed together to produce an extended length fabric strip which may be helically wound in consecutive rows upon a core as taught in U.S. Pat. No. 6,502,779, U.S. Pat. No. 6,685,121, U.S. Pat. No. 6,902,131, U.S. Pat. No. 6,918,552, and U.S. Pat. No. 6,929,203, all to Jelinek et al., all of which patents are hereby incorporated herein by reference. 
     Both the standard length rolls of knitted pile fabric strips and the rolls of extended length knitted pile fabric strips have substantial material costs and labor costs that are incurred in the manufacturing process after the circular knitting process. The material costs include the cost of the coating material, losses due to fly (fly are extra fibers that come loose from the knitted pile fabric), losses during the cutting of the sixty inch (1524 millimeter) wide fabric segment into twenty knitted pile fabric strips, and seam losses throughout the operation. The labor costs include the costs to perform the coating process, the brushing, the second pass shearing, and all of the finishing steps within the traditional sliver knit operation including slitting and continuously coiling the fabric slits. 
     Paint roller covers are manufactured by using a hollow cylindrical core made of cardboard or thermoplastic material which has the knitted pile fabric strip helically wound around the core. During the manufacture of paint roller covers, the knitted pile fabric strips are secured to the core either by using adhesive or epoxy, or by thermally bonding the knitted pile fabric strip in place on a thermoplastic core. For examples of these manufacturing processes see U.S. Pat. No. 4,692,975, to Garcia (the “&#39;975 Patent”), U.S. Pat. No. 5,572,790, to Sekar (the “&#39;1790 Patent”), and U.S. Pat. No. 6,159,320, to Tams et al. (the “&#39;320 Patent”), each of which are hereby incorporated by reference. 
     The &#39;975 Patent uses a core that is cut from preformed thermoplastic (e.g., polypropylene) tubular stock. The core is mounted on a rotating spindle, and a movable carriage mounted at an angle to the spindle feeds a continuous strip of knitted pile fabric onto the core, with the carriage moving parallel to the spindle in timed relation to its rotation so that the knitted pile fabric strip is wound on the plastic core in a tight helix. Also mounted to the movable carriage is a heat source for heat softening the thermoplastic core just in advance of the point where the knitted pile fabric strip is applied to the thermoplastic core, such that the knitted pile fabric is heat bonded to the thermoplastic core as it is wound thereupon. The bond formed between the knitted pile fabric and the thermoplastic core is a strong one not subject to separation from exposure to paint solvents. 
     The &#39;790 Patent uses a core that is formed from a strip (or multiple strips) of thermoplastic material that is (are) helically wound about a stationary mandrel. Alternately, the core may be formed by applying liquefied thermoplastic material to a drive belt which transfers the thermoplastic material to the mandrel. A layer of adhesive is then applied to the outer surface of the core, and the knitted pile fabric strip is applied to the core by helically winding the knitted pile fabric strip onto the core. Alternately, the paint roller cover may instead be made by bonding, in a single step, a knitted pile fabric strip to a wound strip of thermoplastic material that is wrapped about the mandrel. 
     The &#39;320 Patent extrudes a cylindrical plastic core through a rotating extruder head that is cooled, with the outer surface of the core then being plasma treated. The knitted pile fabric strip is secured onto the plasma treated outer surface of the core by extruding thin films of first and second epoxy resin subcomponents onto the outer surface of the core as it is extruded, cooled, and plasma treated in a continuous process. 
     Other variations are also known, particularly in technologies relating to manufacturing pile fabric suitable for use on paint roller covers. For example, instead of using knitted pile fabric, woven pile fabric can be substituted. Woven pile fabric consists of three yarns—a knit base material or warp yarn, a filling or weft yarn, and a pile yarn. The threads of warp yarn are held taut and in a parallel array on a loom, and the threads of weft yarn are woven across the threads of warp yarn in an over/under sequence orthogonal to the threads of warp yarn, with threads of pile yarn being woven into the weave of warp and weft yarns such that the threads of pile yarn extend essentially perpendicularly from one side of the fabric. Such woven pile fabric may be processed in a manner similar to that described above with regard to the processing of knitted pile segments of fabric to produce strips of woven pile fabric that can be helically wound onto paint roller cover cores. 
     However, all paint roller covers manufactured using the methods described above have a seam. As the strips of fabric are helically wound around the cores, the fabric strips wrap contiguously around the core, thereby creating a helical seam that is located throughout the cover. The seam inevitably produces a less than optimal paint roller cover since a seam can interfere with the uniform application of paint from the paint roller cover. The helical winding process of manufacturing a paint roller cover requires careful attention to contiguous winding. Errors resulting in overlapped fabric or gaps in the contiguous winding process often occur, resulting in increased scrap or marketing poor quality covers. Such seams have the potential, particularly with short nap paint roller covers, to produce a seam mark or stippling effect on the surface being painted, particularly if the paint being applied combines with the seams to produce a more pronounced defective characteristic in the surface being painted. 
     An examination of prior technology in the paint roller cover arts reveals that this problem has been recognized in the past, with several solutions that have been proposed to deal with the challenge presented by the presence of seams in paint roller covers. The first of these, U.S. Pat. No. 2,600,955, to Barnes et al., which patent is hereby incorporated herein by reference, discloses a paint roller cover made from a segment of canvas tubing that has yarn loops sewn therethrough, with the ends of the loops on the outside of the segment of the canvas tubing being cut. This approach is certainly far too expensive to represent a viable solution, and would not compare well to currently commercially available paint roller covers in the quality of the paint coat that could be applied. 
     Another approach is shown in U.S. Pat. No. 2,704,877 and U.S. Pat. No. 2,752,953, both to Arnold Schmidt, which patents are hereby incorporated herein by reference, which patents are related and disclose a tubular knitted pile fabric that is stated to have been manufactured on an apparatus disclosed in U.S. Pat. No. 1,849,466, to Moore, which patent is hereby incorporated herein by reference. The apparatus disclosed in Moore, which is hand operated, was stated in several related patents to Sannipoli et al. (U.S. Pat. No. 2,920,372, U.S. Pat. No. 2,944,588, and U.S. Pat. No. 3,010,867, which patents are hereby incorporated herein by reference) to be capable of manufacturing a seamless tubular knitted sleeve in which the pile is located on the interior of the sleeve, thereby requiring that the sleeve be inverted prior to mounting it on a core to form a paint roller cover. As such, the apparatus disclosed in Moore is incapable of manufacturing a knitted sleeve in which the pile is located on the exterior of the sleeve. 
     The Sannipoli et al. patents inverted the tubular knitted sleeve by positioning it within a hollow tube and pulling one end of the tubular knitted sleeve around the end of the tube and pushing successive portions of the tubular knitted sleeve along the outside of the tube. The Arnold Schmidt &#39;877 patent (which failed to disclose how it inverted the knitted sleeve with the pile on the interior thereof) disclosed a machine for treating and shearing inverted tubular knitted sleeves, and the Arnold Schmidt &#39;953 Patent disclosed using the inverted, treated, and sheared tubular knitted sleeves by stretching them and pulling them over a tube or shell to form a paint roller. 
     The problem that has prevented the inventions of the Arnold Schmidt patents and the Sannipoli et al. patents from being either practical or commercially successful is that the process of inverting a tubular knitted sleeve having the pile on the interior of the sleeve inevitably damages the fabric of the tubular knitted sleeve. When the fabric is inverted, the material of the fabric is deformed due to stretching that occurs during the process of inverting the tubular knitted sleeve. This deformation tends to increase the diameter of the tubular knitted sleeve, thus requiring it to be stretched lengthwise to restore it to its former diameter. Not only is this process difficult and expensive, but it also results in variable density of the fabric as well as introducing the prospect of adhesive or thermoplastic bleed-through within the stitches. Such problems will result in unacceptable product quality in paint roller covers made from this type of fabric. 
     It has been determined that the inverting approach taught by the Sannipoli et al. patents and useable by the Arnold Schmidt patents has three drawbacks that make it impracticable. The first drawback of the inverting method is that it requires a high degree of manual operation in that it requires cutting of the tubular knitted sleeves to size and placement of the tubular knitted sleeves into the tubes of the inverting machine. The second drawback of the Sannipoli et al. method is that only relatively short length tubular knitted sleeves representing a single paint roller cover (typically nine inches (229 millimeters)) can be processed at a time, which makes the method inherently unsuitable for mass production. 
     The third, and by far the most serious, drawback of the Sannipoli et al. method is that the process of inverting the tubular knitted sleeves inevitably results in stretching the tubular knitted sleeves so that they will not snugly fit on the paint roller cover cores, potentially creating creases in a high percentage of them when they are adhesively secured to the paint roller cover cores. This results in an unacceptably high percentage of them being defective and necessitating them being scrapped, resulting in an unacceptably high scrap cost. Predictably, the inventions taught in the Sannipoli et al. patents and the Arnold Schmidt patents have never found commercial acceptance due to these serious disadvantages. 
     The above-incorporated by reference U.S. patent application Ser. No. 11/740,119 discloses a tubular sliver knitted pile fabric which is manufactured with the sliver pile side facing outwardly rather than inwardly and with a diameter suitable for mounting on a paint roller cover core in a seamless manner. The above-incorporated by reference U.S. patent application Ser. No. 12/116,022 discloses a tubular knit fabric which is manufactured with a cut pile made of yarn which pile faces outwardly rather than inwardly and with a diameter suitable for mounting on a paint roller cover core in a seamless manner. 
     The above-incorporated by reference U.S. patent application Ser. No. 12/015,612 discloses a method of manufacturing paint roller covers from the tubular knitted pile fabric sleeve by initially placing the tubular knitted pile fabric sleeve upon the outside of a thin hollow cylindrical mounting tube, providing an adhesive bonding material on the exterior surface of a core member, and inserting the core member into the interior of the mounting tube. By withdrawing the mounting tube from the knitted pile fabric sleeve while maintaining the respective positions of the knitted pile fabric sleeve and the core member, the knitted pile fabric sleeve is installed onto the exterior surface of the core member and retained thereupon by the adhesive bonding material. The pile fabric covered core member is then finished into paint roller covers by cutting it to a desired size, combing and shearing the pile fabric to a desired length, beveling the edges of the paint roller covers, and vacuuming stray fibers from the paint roller covers. 
     The above-incorporated by reference U.S. patent application Ser. No. 12/116,022 discloses a method of manufacturing paint roller covers from either of the tubular knitted pile fabric sleeves described above by providing an adhesive bonding material that has a relatively non-tacky outer surface on the exterior surface of the outside of the core member. The knitted pile fabric sleeve is installed onto the exterior surface of the core member over the adhesive bonding material. The adhesive bonding material is then rendered tacky, whereupon the knitted pile fabric sleeve becomes adhesively secured by the adhesive bonding material to the exterior surface of the core member. The pile fabric covered core member may be finished into paint roller covers by combing and shearing the pile fabric to a desired length, beveling the edges of the paint roller covers, and vacuuming stray fibers from the paint roller covers. 
     While these methods of installing tubular knitted pile fabric sleeves onto core members have been found to be quite satisfactory, it is desirable to provide still other methods by which a paint roller cover may be manufactured from a tubular pile fabric. It is further desirable that the knitted pile fabric need not be stretched during the manufacturing process, and that the manufacturing process ensure that the knitted pile fabric will not have any wrinkles or other surface defects introduced therein during the manufacturing process. It is also desirable that the tubular pile fabric, which is manufactured with the pile side out, need not be inverted during the process of manufacturing a paint roller cover from the tubular pile fabric. 
     It is highly desirable that the manufacturing method results in an acceptable pile which extends from an acceptably rigid core that can be installed on and used with any conventional paint roller frame. In order to facilitate the mass manufacture of paint roller covers, it is also desirable that the method facilitate either the manufacture of a paint roller cover of a desired finished length, or the manufacture of an extended length segment from which can be cut segments of any desired size for finishing as paint roller covers. It is also desirable that both tubular sliver knitted pile fabric and tubular knitted yarn cut pile fabric as well as a number of different backing materials can be used in the manufacture of paint roller covers. 
     The method used to manufacture a paint roller cover from the tubular pile fabric must result in a construction which is both durable and long lasting, and which, when accomplished, should yield a paint roller cover of superior quality. In order to enhance the market appeal of the method of the present invention, it should also minimize the cost of manufacture of paint roller covers when compared to conventional methods of manufacturing paint roller covers to thereby afford it the broadest possible market. Finally, it is also desirable that all of the aforesaid advantages and aspirations of the paint roller cover manufacturing method of the present invention be achieved without incurring any substantial relative disadvantage. 
     SUMMARY OF THE INVENTION 
     The disadvantages and limitations of the background art discussed above are overcome by the present invention. With this invention, a method of manufacturing paint roller covers is provided which forms a substantially rigid, integral core for the paint roller cover. In particular, at least one of the knit base material of a tubular knitted pile fabric segment, the pile of the tubular knitted pile fabric segment or both the knit base material and the pile of the tubular knitted pile fabric segment are comprised, at least in part, of a low melt yarn. The tubular knitted pile fabric segment is preferably knitted in a pile side-out manner. The pile may include sliver fibers, cut pile yarn segments or a combination of both. The low melt component of the backing yarn and/or the cut pile yarn used in the tubular knitted pile fabric segment of the present invention preferably comprises bicomponent fibers. 
     Bicomponent fibers are comprised of two polymers that have different chemical and/or physical properties and which are extruded from the same extrusion device with both polymers contained within the same fiber. Most commercially available bicomponent fibers are configured with their two constituent polymers arranged either in a sheath-core arrangement, a side-by-side arrangement (also referred to as a bilateral arrangement), an eccentric sheath-core arrangement (which is a geometric variation of sheath-core construction), a matrix-fibril arrangement (also referred to as an inlands-in-the-sea arrangement), and a segmented pie arrangement (also referred to as a citrus arrangement). The bicomponent fibers used by the present invention are “low melt” bicomponent thermal binder fibers that utilize polymer combinations such as a sheath-core arrangement in which the core material has a relatively higher melting point than the sheath material. These alternatives are examples, since many other low-melt configurations can also be manufactured. (It will be appreciated that the low melt yarn can be made from more than two polymer constituents, as is well known to those skilled in the art, and as described below.) 
     Such low melt bicomponent fibers are available from Fiber Innovation Technology, Inc. of Johnson City, Tenn., and from Kuraray Co., Ltd, of Tokyo, Japan. Typical higher melt (which may be used in a core) materials are polyester (most preferred) or polypropylene, and typical sheath materials are polyethylene terephthalate (PET, most preferred), polyethylene, and copolyester. Typical lower melt (which may be used in a sheath) melting points of bicomponent fibers may be between approximately 121 and 260 degrees Centigrade (between 250 and 500 degrees Fahrenheit). 
     The backing yarn and the pile fiber/yarn used by the present invention may thus be made of such low melt bicomponent fibers; such yarn shall be referred to herein as “bicomponent fiber yarn.” Alternately, the backing yarn and/or pile fiber may instead be a bicomponent yarn which is made of two different types of fibers or yarns (yarns can be manufactured using different types of fibers or ring spun with two different types of yarn), one of which fiber or yarn types has a lower melting point than the other fiber or yarn type; this yarn shall be referred to herein as “bicomponent yarn.” The bicomponent fiber yarn and the bicomponent yarn shall collectively be referred to herein as “low melt yarns.” 
     Consistent with the broader aspects of the present invention, the term “low melt yarn” can encompass yarns including at least one low melt filament or strand, as described above, and also including a plurality of additional high melt or non-low melt filaments or strands that are combined together by methods well known to those skilled in the art. The additional high melt/non-low melt filaments or strands may be comprised of any suitable natural or synthetic fiber suitable for combination with the low melt fiber or strand. Suitable materials include but are not limited to nylon, rayon, polypropylene, polyester, polyester-cotton blends, cotton, wool and acrylic. Other materials may be used so long as they are compatible with the selected low melt yarn and the final application of the tubular knitted pile fabric segment. In this way, the present invention is not limited to low melt yarns having only two components and includes low melt yarns having multiple strand components. 
     It will be appreciated that the ratio of low melt component to high melt component used in a particular low melt yarn encompassed by the present invention, will vary depending on the particular end use application of the tubular knitted pile fabric segment. Where a more rigid integral core is to be formed, a low melt yarn having a low melt fiber or strand composition that is substantially equal to or greater than the high melt component composition can be used. For applications where the integral core of the tubular knitted pile fabric segment may be further reinforced, a low melt fiber or strand composition that is less than the high melt component composition can be used. 
     The linear mass density of the backing yarn, the pile fibers and/or cut yarn segments used by the present invention may vary between approximately 150 denier and approximately 1500 denier, with a preferred linear mass density being between approximately 560 denier and approximately 1200 denier. It will be understood, however, that the linear mass density of each fiber or strand of the bicomponent or multi-component low melt yarn will be determined by the specific fiber/strand selected, and is a matter of design choice, depending at least in part on the knitting equipment utilized and the end use application of the tubular knitted pile fabric segment. 
     The use of low melt yarns for the base of a sliver knit fabric is discussed in U.S. Pat. No. 6,766,668, to Sinykin, which patent is assigned to the assignee of the present invention, and which patent is hereby incorporated herein by reference in its entirety. This patent used heat to activate the low melt material in the base, heating the sliver knit fabric to a temperature for a sufficient period of time to permit the low melt material to melt about the central and/or intermediate portions of the sliver fibers. The sliver knit fabric was then cooled so that the low melt material returned to a hardened state and captured a portion of the sliver fibers to lock them to the base of the fabric. This represents a substantially different use of bicomponent fibers than that made by the present invention, as will become evident below. 
     The low melt yarn backing together with the low melt sliver fibers, low melt cut pile yarn segments formed from a pile yarn, or a combination of both are knitted into the tubular knitted pile fabric segment. The manufacture of a tubular knitted pile fabric with sliver fibers is disclosed in the above-incorporated by reference U.S. patent application Ser. No. 11/740,119, which produces a tubular knitted sliver pile fabric with the pile side facing outwardly and with a diameter suitable for conversion into a paint roller cover (paint roller covers typically have an inner diameter of approximately one and one-half inches (38 millimeters)). The manufacture of a tubular knitted pile fabric with cut pile yarn segments formed from a pile yarn is disclosed in the above-incorporated by reference U.S. patent application Ser. No. 12/116,022, which produces a tubular knitted cut pile fabric with the pile side facing outwardly and with a diameter suitable for conversion into a paint roller cover (paint roller covers typically have an inner diameter of approximately one and one-half inches (38 millimeters). The manufacture of a tubular knitted pile fabric with a combination of sliver fibers and cut pile yarn segments formed from a pile yarn is disclosed in the U.S. patent application Ser. No. 12/249,455, which is incorporated herein by reference, and which produces a tubular knitted cut pile fabric with the pile side facing outwardly and with a diameter suitable for conversion into a paint roller cover (paint roller covers typically have an inner diameter of approximately one and one-half inches (38 millimeters)). It is understood that the tubular knitted pile fabric segments could be knitted slightly larger or slightly smaller than the inner diameter of a typical paint roller cover. 
     Consistent with the broader aspects of the present invention, the low melt yarn backing together with the low melt sliver fibers, low melt cut pile yarn segments formed from a pile yarn, or a combination of both can be knitted into a pile side-in configuration to form a tubular knitted pile fabric segment, and then inverted for further processing to form the paint roller integral core within the tubular knitted pile fabric segment of the present invention. 
     The tubular knitted pile fabric is then placed onto a cylindrical mandrel which is the approximate size of the inner diameter of a paint roller cover (typically approximately one and one-half inches (38 millimeters)). The cylindrical mandrel may be made, for example, of steel (which may optionally have a non-stick coating such as PTFE or silicone) and has a heating mechanism contained inside which is capable of rapidly heating the outside of the mandrel to a desired temperature. The cylindrical mandrel is heated to the desired temperature, which is less than 343 degrees Centigrade (less than 650 degrees Fahrenheit) or any temperature suitable for activating the low melt yarn. One temperature range that may be acceptable is between approximately 121 and 218 degrees Centigrade (between 250 and 425 degrees Fahrenheit). This temperature is sufficient to melt the lower melting point component of the low melt yarn used in the backing or base and is sufficient to melt the looped ends of any pile fibers also including a low melt component. The temperature is maintained for a period of between approximately five seconds and approximately ninety seconds, preferably approximately five to approximately sixty seconds. 
     The melted lower melting point component of the low melt yarn used in the backing or base of the tubular knitted pile fabric and the melted looped ends of the pile fibers flows into the cylindrical form of the outside of the cylindrical mandrel. The melted lower melting point component also flows between the high melt backing loops and the central and/or intermediate portions of the sliver fibers or the loops of the cut pile yarn segments, and locks the sliver fibers or cut pile yarn segments into the tubular knitted pile fabric. This greatly reduces the degree of shedding of pile fibers from the tubular knitted pile fabric. It also converts the backing from a fabric into a unitary cylindrical assembly which, when cooled, will become substantially rigid. The mandrel is then cooled or allowed to cool, after which the rigid, cylindrical pile fabric assembly is removed from the mandrel. 
     In a first alternate embodiment, one or more layers of a dry adhesive film may be first wound on a non-stick mandrel, following which the tubular knitted pile fabric segment is placed over the dry adhesive film. The mandrel is then heated to cause the dry adhesive film and the lower melting point component of the low melt yarn used in the backing or base of the tubular knitted pile fabric to melt together with the adhesive bonding material to create an even more rigid cylindrical assembly having a pile surface. 
     With or without utilizing the layer of dry adhesive, the methods of the present invention include applying at least one layer of spray adhesive on to the cooled, integral core formed by the re-hardened low melt yarn to create an enhanced rigid cylindrical assembly having a pile surface. 
     The adhesive used for the adhesive layer in the methods of the present invention may be two-part or one-part adhesives, and are preferably provided in a “liquid” form. As defined herein, a liquid adhesive can include compositions that are provided in a liquid or substantially liquid, gel, foam and/or liquid emulsion or dispersion form. It will be appreciated that the viscosity of the liquid adhesive will depend on the particular composition of the adhesive selected, the particular solvents utilized therewith and the desired cured and/or dried properties of the adhesive. Such adhesive compositions can include but are not limited to polyurethane and urethane adhesives, acrylics, epoxies, latex, synthetic latex, glycerin based compounds, silicone based compounds, other natural or synthetic polymeric adhesives as known to those skilled in the art, or a combination thereof. Preferably, the spray adhesive, when cured and/or dried, is a substantially waterproof and/or water resistant. 
     Preferably, the adhesive is a polyurethane composition utilizing an isocynate crosslinking agent, as well known in the art (although other crosslinking agents can be used with good effect). The polyurethane adhesive can include one or more additives including catalysts, chain-extenders, stabilizing agents, and plasticizers as are known to those skilled in the art. In particular, the polyurethane adhesive used in the present invention can include one or more catalysts including, but not limited to tertiary amines such as triethylenediamine, N-methylmorpholine, N-ethylmorpholine, diethylethanolamine, N-cocomorpholine, 1-methyl-4-dimethylaminoethylpiperazine, 3-methoxypropyldimethylamine, N,N,N-trimethylisopropyl propylenediamine, 3-diethylamino-propyldiethylamine, dimethylbenzylamine, and the like. Other suitable catalysts are, for example, stannous chloride, dibutyltin-di-2-ethyl hexonate, potassium hexanoate, stannous oxide, as well as other organometallic compounds known to those skilled in the art. 
     The adhesive is applied to the cylindrical pile fabric assembly while the assembly is positioned in a substantially vertical orientation using a spray device including a nozzle assembly designed to coat the entire tubular inside surface of the cylindrical pile fabric assembly. As such, the spray device is selected to include a nozzle capable of providing a 360 degree circular adhesive spray. 
     In certain preferred embodiments of the present invention, the spray device is automatically lowered into the vertically disposed cylindrical pile fabric assembly and centered inside the integral core thereof. The spray nozzle is positioned so that it is substantially aligned with or below the bottom end or edge of the cylindrical pile fabric assembly. Once in this position, the spray device is activated and adhesive is continuously sprayed onto the inside surface thereof as the spray device is vertically moved from the bottom end to the top end of the cylindrical pile fabric assembly. In certain other embodiments of the present invention, the spray device can be manually operated, and manually moved from the bottom end to the top end of the cylindrical pile fabric assembly. 
     After application of one or more layers of adhesive onto the inside surface of the cylindrical pile fabric assembly, the adhesive is allowed to cure and/or dry. Drying can occur via air or ambient means, or alternatively, radiant heat (oven dry), ultraviolet radiation and/or radio frequency methods can be used to cure/dry the adhesive layer. 
     The adhesive-enhanced rigid, cylindrical pile fabric assembly is finished by combing and shearing the pile fabric to the desired length. The edges of the unfinished paint roller covers are beveled, and any loose sliver fibers are then vacuumed off. The finishing of the rigid, cylindrical pile fabric assembly may be performed using the MBK Maschinenbau GmbH paint roller cover finishing machine, an Edward Jackson (Engineer) Limited finishing machine, or other equipment custom built by individual paint roller cover manufacturers. 
     It may therefore be seen that the present invention teaches a method by which a paint roller cover may be manufactured from tubular knitted pile fabric using a base or backing and/or pile fibers comprising, at least in part, a low melt yarn and forming a substantially rigid integral core member, and further enhancing the integral core member using an adhesive composition. 
     The paint roller cover manufacturing method of the present invention results in an acceptable pile which extends from an acceptably rigid core which can be installed on and used with any conventional paint roller frame, or on a frame uniquely designed for the paint roller utilizing the new core design. The paint roller cover manufacturing method of the present invention facilitates either the manufacture of a paint roller cover of a desired finished length, or the manufacture of an extended length segment from which segments of any desired size can be cut for finishing as paint roller covers, thereby facilitating the mass manufacture of paint roller covers. The paint roller cover manufacturing methods of the present invention can use tubular sliver knitted pile fabric, tubular knitted yarn cut pile fabric, tubular knitted fabric including both sliver knitted pile and yarn cut pile, as well as a number of different backing materials. 
     The paint roller cover manufacturing method of the present invention results in a construction which is both durable and long lasting, and yields a paint roller cover of superior quality. The paint roller cover manufacturing method of the present invention also reduces the cost of manufacturing paint roller covers when compared to conventional methods of manufacturing paint roller covers by manufacturing paint rollers without using a core member, thereby affording it the broadest possible market. Finally, all of the aforesaid advantages and aspirations of the paint roller cover manufacturing method of the present invention are achieved without incurring any substantial relative disadvantage. 
    
    
     
       DESCRIPTION OF THE DRAWINGS 
       These and other advantages of the present invention are best understood with reference to the drawings, in which: 
         FIG. 1  is an isometric view of a segment of tubular paint roller fabric made according to the teachings of the present invention, showing a tubular knit base having sliver fibers extending therefrom, each of which can be constructed, at least in part, of a low melt yarn; 
         FIG. 2  is a schematic view of a portion of the tubular paint roller fabric illustrated in  FIG. 1 , showing the knitting pattern of the base yarn and the placement of pile fibers from the sliver into the knit base; 
         FIG. 3  is an isometric view of a segment of tubular cut pile knit paint roller fabric made according to the teachings of the present invention, showing a tubular knit base having cut pile yarn segments extending therefrom, each of which can be constructed, at least in part, of a low melt yarn; 
         FIG. 4  is a schematic view of a portion of the tubular paint roller fabric illustrated in  FIG. 1 , showing the knitting pattern of the base yarn and the placement of cut pile yarn segments into the knit base; 
         FIG. 5  is an isometric view of a segment of tubular knit paint roller fabric made according to the teachings of the present invention, showing a tubular knit base with alternating rows of sliver fiber and cut pile extending therefrom, each of which can be constructed, at least in part, of a low melt yarn; 
         FIG. 6  is a schematic view of a portion of the tubular paint roller fabric illustrated in  FIG. 5 , showing the knitting pattern of the base yarn and the placement of tufts of sliver fibers and cut pile yarn segments into the knit base; 
         FIG. 7  is a cross sectional view of a sheath-core bicomponent fiber having a core made of a material that has a higher melting point than the material that its sheath is made of; 
         FIG. 8  is a cross sectional view of a side-by-side bicomponent fiber showing opposite sides that are respectively made of materials having different melting points; 
         FIG. 9  is a cross sectional view of an eccentric sheath-core bicomponent fiber having a core made of a material that has a higher melting point than the material that its sheath; 
         FIG. 10  is a cross sectional view of a matrix-fibril bicomponent fiber having a plurality of segments made of a material that has a higher melting point located within a sheath that is made of a lower melting point material; 
         FIG. 11  is a cross sectional view of a segmented pie bicomponent fiber having alternating wedges made of materials having different melting points; 
         FIG. 12  is a cross sectional view of a bicomponent yarn showing two different types of fibers, one of which fiber types has a lower melting point than the other fiber type; 
         FIG. 13  is a longitudinal cross sectional view of a mandrel heating assembly having a cartridge heater and a thermocouple located inside a cylindrical mandrel; 
         FIG. 14  is a lateral cross sectional view of the mandrel heating assembly shown in  FIG. 13 ; 
         FIG. 15  is a schematic depiction of a controller that uses the signal from the thermocouple illustrated in  FIG. 13  to control the cartridge heater also illustrated in  FIG. 13 ; 
         FIG. 16  is a schematic isometric depiction showing an end of a tubular knitted pile fabric about to be slid onto an outer non-stick surface of a hollow cylindrical aluminum heating tube; 
         FIG. 17  is a schematic isometric depiction of the tubular knitted pile fabric illustrated in  FIG. 16 , with the tubular knitted pile fabric being partially slid onto the outer non-stick surface of the aluminum heating tube; 
         FIG. 18  is a schematic isometric depiction of the tubular knitted pile fabric illustrated in  FIGS. 16 and 17 , with the tubular knitted pile fabric now located upon the outer non-stick surface of the aluminum heating tube; 
         FIG. 19  is a schematic isometric depiction of the tubular knitted pile fabric and the outer non-stick surface of the aluminum heating tube illustrated in  FIGS. 16 through 18  about to be slid onto the mandrel heating assembly; 
         FIG. 20  is a schematic isometric depiction of the tubular knitted pile fabric and the outer non-stick surface of the aluminum heating tube illustrated in  FIGS. 16 through 19  located upon the mandrel heating assembly illustrated in  FIG. 19  and being heated; 
         FIG. 21  is a schematic isometric depiction of the tubular knitted pile fabric that was heated on the aluminum heating tube and the mandrel heating assembly illustrated in  FIGS. 19 and 20  with the backing fused into a rigid cylindrical configuration; 
         FIG. 22A  is an isometric view of an exemplary spray device that can be used to apply one or more adhesive layers to the inside surface of the cylindrical pile fabric assembly of the present invention; 
         FIG. 22B  is an isometric view of a second exemplary spray device that can be used to apply one or more adhesive layers to the inside surface of the cylindrical pile fabric assembly of the present invention; 
         FIG. 23  is a schematic view of the spray device centered above a vertically positioned cylindrical pile fabric assembly, the spray device shown in an off or deactivated position as it will be before and after spraying of the cylindrical pile fabric assembly; 
         FIG. 24  is a schematic view of the spray device positioned inside the vertically positioned cylindrical pile fabric assembly before spraying begins; 
         FIG. 25  is a cross sectional view of the spray device positioned inside the vertically positioned cylindrical pile fabric, taken along the line  25 - 25  in  FIG. 24 ; 
         FIG. 26  is a schematic view of the spray device positioned inside the vertically positioned cylindrical pile fabric assembly as the spray device moves vertically upwardly, while adhesive spraying occurs; 
         FIG. 27  is a partial schematic view of the spray device positioned inside the vertically positioned cylindrical pile fabric assembly as the spray device moves vertically upwardly, while adhesive spraying occurs; 
         FIG. 28  is a cross sectional view of the cylindrical pile fabric assembly including the adhesive layer applied to the inside surface thereof, taken along the line  28 - 28  in  FIG. 27 ; 
         FIG. 29  is a schematic isometric depiction showing a wide segment of dry adhesive film beginning to be wound around the outer non-stick surface of the aluminum heating tube, incorporating an alternate embodiment of the methods of the present invention; 
         FIG. 30  is a schematic isometric depiction showing one or more windings of dry adhesive film on the aluminum heating tube shown in  FIG. 29 ; 
         FIG. 31  is a schematic isometric depiction showing an end of a tubular knitted pile fabric about to be slid onto the one or more windings of dry adhesive film on the aluminum heating tube shown in  FIG. 30 ; 
         FIG. 32  is a schematic isometric depiction of the tubular knitted pile fabric, the one or more windings of dry adhesive film, and the aluminum heating tube illustrated in  FIG. 31  about to be slid onto the mandrel heating assembly; 
         FIG. 33  is a schematic isometric depiction of the tubular knitted pile fabric, the one or more windings of dry adhesive film, and the aluminum heating tube illustrated in  FIGS. 31 and 32  located upon the mandrel heating assembly illustrated in  FIG. 13  and being heated; and 
         FIG. 34  is a flow diagram showing the manufacturing of a paint roller cover that is made according to the methods of the present invention, as illustrated in  FIGS. 1 through 33 . 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     The paint roller cover manufacturing methods of the present invention utilizes a tubular paint roller fabric that includes at least one of a tubular knit base and an outwardly extending pile that is made, at least in part, of a low melt yarn. The tubular paint roller fabrics for use in the present invention include those comprising a tubular knit base having sliver pile fibers extending therefrom, a tubular knit base having cut pile yarn segments extending therefrom or a tubular knit base having a combination of sliver pile fibers and cut pile yarn segments extending therefrom. The tubular paint roller fabrics and methods of manufacture thereof are discussed in detail in the above-incorporated by reference U.S. patent application Ser. No. 11/740,119, as shown in  FIGS. 1 and 2  herein, U.S. patent application Ser. No. 12/116,022, as shown in  FIGS. 3 and 4  herein, and U.S. patent application Ser. No. 12/249,455, incorporated herein by reference, and as shown in  FIGS. 4 and 5  herein. It will be appreciated that although the above-recited patent applications are directed to tubular knit fabrics formed in a pile side-out manner, the present invention can be used with good effect with tubular knit fabrics that are knitted in a pile side-in manner and inverted, as will be well known to those skilled in the art. 
     Referring first to  FIG. 1 , a tubular sliver knit segment  30  that may be continuously knitted in an extended length is shown. The tubular sliver knit segment  30  consists of a knit backing or base material  32  having pile fibers  34  extending from the knit base material  32  on the outer surface of the tubular sliver knit segment  30 . At least one of the knit base material  32  and the pile fiber  34  are constructed at least in part from a low melt yarn, that will be discussed below. It may be seen from a top edge  36  of the knit base material  32  that the tubular sliver knit segment  30  has an essentially circular cross section. The tubular sliver knit segment  30  may be knitted in as long a length as desired, notwithstanding that  FIG. 1  only shows a relatively short segment of the tubular sliver knit segment  30 . 
     Referring next to  FIG. 2 , a segment of the tubular sliver knit segment  30  is shown in schematic form from the outside thereof to illustrate the knit of the knit base material  32 , and the manner in which tufts of the pile fibers  34  are woven into the knit base material  32 . Those skilled in the art will at once realize that while the tufts of the pile fibers  34  shown in  FIG. 2  include only a few fibers each for added clarity and understanding of the construction of the pile fabric  30 , tufts of the pile fibers  34  in the tubular sliver knit segment  30  will actually include sufficient pile fibers  34  to make a pile that is sufficiently dense for the intended use of the tubular sliver knit segment  30  in the manufacture of a paint roller cover. 
     The foundation of the tubular sliver knit segment  30  is the knit base material  32 , which is formed from a plurality of threads or yarn segments, indicated generally at  31  in  FIG. 2 . The knit base material  32  may be knit from a low melt yarn in a highly modified single jersey circular knitting process on a radically redesigned circular knitting machine. The knit base material  32  has a plurality of courses (which are rows of loops of stitches which run across the knit fabric), five of which are shown and designated by the reference numerals  40 ,  42 ,  44 ,  46 , and  48 , and a plurality of wales (which are vertical chains of loops in the longitudinal direction of the knit fabric), three of which are shown and designated by the reference numerals  50 ,  52 , and  54 . The respective courses  40 ,  42 ,  44 ,  46 , and  48  are knitted sequentially from the lowest course number to the highest course number. 
     It will be appreciated that if the knit base material includes low melt yarn, the threads or yarn segments  31  of the knit base material  32  may each be made of a low melt yarn, or alternatively, only a portion of the threads  31  of the knit base material  32 , such as alternating threads  31 , can be made of a low melt yarn, depending on the desired end use application of the tubular knit fabric  30 . 
     By way of example, the construction of the portion of the tubular sliver knit segment  30  in the area of the course  46  and the wale  52  will be discussed herein. A loop  56  formed in a yarn segment, indicated at  58 , is located in this area, with a loop  60  formed in a yarn segment indicated at  62  being located in the course  44  below the loop  56 , and a loop  64  formed in a yarn segment indicated at  66  being located in the course  48  above the loop  56 . The loop  56  extends through the loop  60  from the outside to the inside of the tubular sliver knit segment  30  (shown in  FIG. 2 ), and the loop  64  also extends through the loop  56  from the outside to the inside. 
     A tuft of pile fibers  34  having a loop portion  68  and opposite end portions  70  and  72  is knitted into the knit base material  32  together with the loop  56 . The loop portion  68  of that particular tuft of pile fibers  34  is located adjacent the top of the loop  56 , and the opposite end portions  70  and  72  of that particular tuft of pile fibers  34  extend outwardly from the interior of the loop  56 , above the loop  60  and below the loop  64 . In a similar manner, each of the other tufts of the pile fibers  34  is knitted into the knit base material  32  with a different loop. 
     The tufts of the pile fibers  34  of the tubular sliver knit segment  30  can also be made from a low melt yarn so that the loop portions thereof may be melted together, if desired, as described in more detail below. In order to provide the tubular knit segment  30  with a consistent and uniform pile surface (for use as a paint roller cover), the tufts of pile fibers  34  including the low melt yarn component can be knitted into the knit base material  32  in any number of patterns or configurations. For example, tufts of pile fibers indicated at  61 ,  63 ,  65 ,  67 ,  69 ,  71  and  73  may be constructed of a low melt yarn, so that a repeating pattern of low melt fibers and high melt fibers/yarns are incorporated into the pile  34 . The number of tufts of low melt pile fibers can be determined by a number of factors, including but not limited to, the paint roller fabric application, the type of low melt and high melt fibers used in both the knit base material  32  and the pile  34 , and as a matter of design choice. 
     Referring now to  FIG. 3 , a tubular cut pile knit segment  80  that may be continuously knitted in an extended length is shown. The tubular cut pile knit segment  80  consists of a knit backing or base material  82  having cut pile yarn segments  84  extending from the knit base material  82  on the outer surface of the tubular cut pile knit segment  80 . At least one of the knit base material  82  and the cut pile yarn segments  84  are made, at least in part, from a low melt yarn that will be discussed below. It may be seen from a top edge  86  of the knit base material  82  that the tubular cut pile knit segment  80  has an essentially circular cross section. The tubular cut pile knit segment  80  may be knitted in as long a length as desired, notwithstanding that  FIG. 3  only shows a relatively short segment of the tubular cut pile knit segment  80 . 
     Referring next to  FIG. 4 , a segment of the tubular cut pile knit segment  80  is shown in schematic form to illustrate the knit of the knit base material  82 , and the manner in which the cut pile yarn segments  84  are knitted into the knit base material  82 . 
     The foundation of the tubular cut pile knit segment  80  is the knit base material  82 , which is formed from a plurality of threads or yarn segments, indicated generally at  81  in  FIG. 4 . The knit base material  82  may be knit from a low melt yarn in a highly modified single jersey circular knitting process on a radically redesigned circular knitting machine. The knit base material  82  has a plurality of courses (which are rows of loops of stitches which run across the knit fabric), five of which are shown and designated by the reference numerals  90 ,  92 ,  94 ,  96 , and  98 , and a plurality of wales (which are vertical chains of loops in the longitudinal direction of the knit fabric), three of which are shown and designated by the reference numerals  100 ,  102 , and  104 . The respective courses  90 ,  92 ,  94 ,  96 , and  98  are knitted sequentially from the lowest course number to the highest course number. 
     It will be appreciated that when the knit base material  81  is designed to include low melt yarn, the threads or yarn segments  81  of the knit base material  82  may each be made of a low melt yarn, or alternatively, a portion, such as alternating threads  81 , can be made of a low melt yarn, depending on the desired end use application of the tubular knit fabric  80 . 
     By way of example, the construction of the portion of the tubular cut pile knit segment  80  in the area of the course  96  and the wale  102  will be discussed herein. A backing loop  106  formed in a backing yarn segment indicated at  108  is located in this area, with a backing loop  110  formed in a backing yarn segment indicated at  112  being located in the course  94  below the backing loop  106 , and a backing loop  114  formed in a backing yarn segment indicated at  116  being located in the course  98  above the backing loop  106 . The backing loop  106  extends through the backing loop  110  from the outside to the inside of the tubular cut pile knit segment  80  (shown in  FIG. 4 ), and the backing loop  114  also extends through the backing loop  106  from the outside to the inside. It will at once be appreciated by those skilled in the art that this arrangement of backing loops in sequentially knitted courses is completely opposite to the way in which knit fabrics have been knitted on known circular knitting machines. 
     A cut pile yarn segment  84  having a pile loop portion  118  and opposite pile ends  120  and  122  is knitted into the knit base material  82  together with the backing loop  106 . The pile loop portion  118  of that particular cut pile yarn segment  84  is located adjacent the top of the backing loop  106 , and the opposite pile ends  120  and  122  of that particular cut pile yarn segment  84  extend outwardly from the interior of the backing loop  106 , above the backing loop  110  and below the backing loop  114 . In a similar manner, each of the other cut pile yarn segments  84  is knitted into the knit base material  82  with a different backing loop. 
     The cut pile yarn segments  84  of the tubular cut pile knit segment  80  can also be made from a low melt yarn so that the pile loop portions thereof may be melted together with the backing material, as described in more detail below. In order to provide the tubular cut pile knit segment  80  with a consistent and uniform pile surface (for use as a paint roller cover), the cut pile yarn segments  84  including the low melt yarn component can be knitted into the knit base material  82  in any number of patterns or configurations. For example, the cut pile yarn segments indicated at  91 ,  93  and  95  may be constructed of a low melt yarn, so that a substantially repeating pattern of low melt cut yarns and high melt yarns are incorporated into the pile  84 . The number of low melt cut pile yarn segments  84  incorporated into the knit base material  84  can be determined by a number of factors, including but not limited to, the paint roller fabric application, the type of low melt and high melt fibers used in both the knit base material  82  and the pile  84 , and as a matter of design choice. 
     Turning now to  FIGS. 5 and 6 , a tubular knit segment  300  comprising a combination of tufts of pile fibers  304 A and cut pile yarn segments  304 B (indicated generally as  304  in  FIG. 5 ) that may be continuously knitted in an extended length is shown. The tubular knit segment  300  consists of a knit backing or base material  302  having pile fibers,  304  in  FIG. 5 , extending from the knit base material  302  on the outer surface of the tubular knit segment  300 . At least one of the knit base material  302  and the pile fibers  304 A and  304 B are constructed at least in part from a low melt yarn that will be discussed below. It may be seen from a top edge  306  of the knit base material  302  that the tubular knit segment  300  has an essentially circular cross section. The tubular knit segment  300  may be knitted in as long a length as desired, notwithstanding that  FIG. 5  only shows a relatively short segment of the tubular knit segment  300 . 
       FIG. 6  illustrates a segment of the tubular knit segment  300  in schematic form to illustrate the knit of the knit base material  302 , and the manner in which tufts of the pile fibers  304 A and cut pile yarn segments  304 B are woven into the knit base material  302 . Those skilled in the art will at once realize that while the pile fibers  304 A and  304 B shown in  FIG. 6  include only a few fibers each for added clarity and understanding of the construction of the pile fabric  300 , the pile fibers  304 A and  304 B in the tubular knit segment  300  will actually include sufficient pile fibers  304 A and  304 B to make a pile that is sufficiently dense for the intended use of the tubular knit segment  300  in the manufacture of a paint roller cover. 
     The foundation of the tubular knit segment  300  is the knit base material  302 , which is formed from a plurality of threads or yarn segments, as indicated generally at  310 . The knit base material  302  may be knit from a low melt yarn in a highly modified single jersey circular knitting process on a radically redesigned circular knitting machine. The knit base material  302  has a plurality of courses (which are rows of loops of stitches which run across the knit fabric), five of which are shown and designated by the reference numerals  340 ,  342 ,  344 ,  346 , and  348 , and a plurality of wales (which are vertical chains of loops in the longitudinal direction of the knit fabric), three of which are shown and designated by the reference numerals  350 ,  352 , and  354 . The respective courses  340 ,  342 ,  344 ,  346 , and  348  are knitted sequentially from the lowest course number to the highest course number. 
     It will be appreciated that when the knit base material  302  includes a low melt material, all of the threads  310  of the knit base material  302  may be made of a low melt yarn, or alternatively, a portion of knit base material  302 , such as alternating threads  310 , can be made of a low melt yarn, depending on the desired end use application of the tubular knit fabric  300 . 
     As will be appreciated by those skilled in the art, the construction of the portion of the tubular knit segment  300  is similar to that described with respect to the tubular sliver knit fabric  30  and the tubular cut pile knit segment  80 . However, the tubular knit segment  300  includes alternating rows of tufts of pile fibers  304 A and cut pile yarn segments  304 B knitted into the knit base material  302 . As illustrated in  FIG. 6 , each of the tufts of pile fibers  304 A have a loop portion  312  and opposite end portions  314  and  316 , and each of the cut pile yarn segments  304 B have a pile loop portion  318  and opposite pile ends  320  and  322 . 
     In certain embodiments of the present invention, the tufts of the pile fibers  304 A and/or the cut pile yarn segments  304 B of the tubular sliver knit segment  300  can be made from a low melt yarn so that the loop portions thereof may be melted together with the backing material, as described in more detail below. In order to provide the tubular knit segment  300  with a consistent and uniform pile surface (for use as a paint roller cover), the pile fibers  304 A and  304 B including the low melt yarn component can be knitted into the knit base material  302  in any number of patterns or configurations. For example, each of the rows of cut pile yarn segments  304 B may be constructed of a low melt yarn, while the rows of tufts of pile fibers  304 A are constructed of a high melt, or higher melt material, so that a repeating pattern of low melt fibers and high melt fibers/yarns are incorporated into the pile  304 A and  304 B. Alternatively, tufts of pile fibers, such as tufts  354  and  356  can be constructed of low melt yarn and/or cut yarn segments  358  and  360  can be constructed of low melt yarn. The number of low melt pile fibers can be determined by a number of factors, including but not limited to, the paint roller fabric application, the type of low melt and high melt fibers used in both the knit base material  302  and/or the pile  304 A and  304 B, and as a matter of design choice. 
     Referring now to  FIGS. 7 through 12 , a number of different bicomponent fibers are shown by way of example (although numerous alternatives may be manufactured by yarn producers), any of which could be used for the threads of the knit base material and/or pile fibers of the tubular knit fabrics  30 ,  80  and  300  of the present invention. Referring first to  FIG. 7 , a sheath-core bicomponent fiber  130  is illustrated which has a high melt component  132  located in the center of the sheath-core bicomponent fiber  130  and a low melt component  134  located on the outer portion of the sheath-core bicomponent fiber  130  which low melt component  134  surrounds the high melt component  132 . The segments of the low melt component  134  and the high melt component  132  are concentric. 
     Consistent with the broader aspects of the present invention, a low melt yarn can be provided wherein the low melt component is provided in the center of a sheath-core bicomponent fiber with a non-melt or high melt component surrounding the low melt component (a construction opposite to that shown in  FIG. 7 ). Indeed, any of the described yarn constructions recited with respect to  FIGS. 7 through 12  can be constructed in a manner in which the low melt component  134  is exchanged in position within the bicomponent fiber. As will be appreciated, the application of heat, as described in more detail below, will permit the low melt component  132  to melt or otherwise soften or flow together. As such, such oppositely formed bicomponent fibers can be used with good effect in the methods of the present invention. 
     The particular low melt components  134  and high melt components  132  used in the tubular knitted fabric of the present invention can be any material known to those skilled in the art, provided that the low melt component melts at temperature sufficiently below the melting point of the high melt component so as not to damage the high melt component  132  during the manufacturing process. Such low melt components/yarns can include, but are not limited to, low-melting thermoplastic polymer or copolymer, such as polypropylene, polyethylene, low melt polyester, low melt co-polyamide (nylon) and the like having a known and/or predetermined melting point. The high melt component  134  is selected so as to remain unaffected at the low melting point of the low melt component and be any natural fiber, thermoplastic polymer/copolymer or a composite thereof. 
     Consistent with the broader aspects of the present invention, the term “low melt yarn” can encompass yarns comprising at least one low melt filament or strand, as described above, and also including a plurality of additional high melt or non-low melt filaments or strands that are combined together by methods well known to those skilled in the art. The additional high melt/non-low melt filaments or strands may be comprised of any suitable natural or synthetic fiber suitable for combination with the low melt fiber or strand. Suitable materials include but are not limited to nylon, rayon, polypropylene, polyester, polyester-cotton blends, cotton, wool and acrylic. Other materials may be used so long as they are compatible with the selected low melt yarn and the final application of the tubular knitted pile fabric segment. In this way, the present invention is not limited to low melt yarns having only two components and includes low melt yarns having multiple strand components. 
     It will be appreciated that the ratio of low melt component to high melt component used in a particular low melt yarn encompassed by the present invention, will vary depending on the particular end use application of the tubular knitted pile fabric segment. Where a more rigid integral core is to be formed, a low melt yarn having a low melt fiber or strand composition that is substantially equal to or greater than the high melt component composition can be used. For applications where the integral core of the tubular knitted pile fabric segment may be further reinforced, a low melt fiber or strand composition that is less than the high melt component composition can be used. 
     The linear mass density of the backing yarn, the pile fibers and/or cut yarn segments used by the present invention may vary between approximately 150 denier and approximately 1500 denier, with a preferred linear mass density being between approximately 560 denier and approximately 1200 denier. It will be understood, however, that the linear mass density of each fiber or strand of the bicomponent or multi-component low melt yarn will be determined by the specific fiber/strand selected, and is a matter of design choice, depending at least in part on the knitting equipment utilized and the end use application of the tubular knitted pile fabric segment. 
     Referring next to  FIG. 8 , a side-by-side bicomponent fiber  140  is illustrated which has one side (a semicircular cross section) made of a high melt component  142  and the other side (a complementary semicircular cross section) made of a low melt component  144 . Referring now to  FIG. 9 , an eccentric sheath-core bicomponent fiber  150  is illustrated which has a high melt component  152  located in the center of the eccentric sheath-core bicomponent fiber  150  and a low melt component  154  located on the outer portion of the eccentric sheath-core bicomponent fiber  150  which low melt component  154  surrounds the high melt material  152 . By definition in an eccentric sheath-core relationship, the segments of the low melt component  154  and the high melt component  152  are not concentric. 
     Referring next to  FIG. 10 , a matrix-fibril bicomponent fiber  160  is illustrated which has four segments of high melt component  162  distributed in a matrix of low melt component  164  that entirely surrounds the segments of high melt component  162 . Although four segments of high melt component  162  are shown in  FIG. 10 , more or fewer could be used. Also, although the four segments of high melt component  162  are shown as being evenly distributed in the surrounding low melt component  164 , the segments of high melt component  162  could be distributed more randomly in the surrounding low melt component  164  as well. 
     Referring now to  FIG. 11 , a segmented pie bicomponent fiber  170  is illustrated which has eight pie-shaped segments that are evenly distributed around the circumference of the segmented pie bicomponent fiber  170 . The segments alternate between high components  172  and low melt components  174 . Although four segments of high melt component  172  and four segments of low melt component  174  are shown in  FIG. 11 , more or fewer could be used. 
     Referring next to  FIG. 12 , a bicomponent yarn  180  is illustrated which is made up of four fibers, two of which are high melt fibers  182  and two of which are low melt fibers  184 . As is the case with any yarn, the high melt fibers  182  and the low melt fibers  184  are twisted together to form the segment of bicomponent yarn  180 . Although two high melt fibers  182  and two low melt fibers  184  are shown in  FIG. 12 , more or fewer of each could be used. 
     Referring now to  FIGS. 13 and 14 , a mandrel heating assembly  190  is illustrated in two cross sectional views. The mandrel heating assembly  190  of the exemplary embodiment has a mandrel  192  that is cylindrical and has an outer diameter of approximately one and three-eighths inches (35 millimeters) or slightly less and has a coaxial cylindrical aperture  194  located therein that is approximately three-quarters of an inch (19 millimeters) in diameter or slightly larger extending therethrough, which mandrel  192  may be made out of steel. A smaller aperture  196  that is approximately one-eighth of an inch (3.2 millimeters) in diameter or slightly larger extends longitudinally through the mandrel  192  and is located in the mandrel  192  between the aperture  194  and the outer surface of the mandrel  192 . 
     A cartridge heater  198  is located in the aperture  194  in the mandrel  192 . The cartridge heater  198  may be a Watlow FIREROD Part No. N24A23-E12H cartridge heater from Watlow Electric Manufacturing Company of St. Louis, Mo. The cartridge heater  198  has a three-quarter inch (19 millimeter) diameter and is twenty-four inches (610 millimeters) long, has a 2750 Watt rating, and has two heater leads  200  extending from one end thereof. 
     A thermocouple  202  is located in the aperture  196  in the mandrel  192 . The thermocouple  202  may be an Omega Model No. JMQSS-125G-6 thermocouple from Omega Engineering, Inc. of Stamford, Conn. The thermocouple  202  has a has an one-eighth inch (3.2 millimeter) diameter, is twenty-four inches (610 millimeters) long, and has two thermocouple leads  204  extending from one end thereof. 
     Referring next to  FIG. 15 , a control circuit for operating the cartridge heater  198  based on temperature information received from the thermocouple  202  is illustrated. A Eurotherm Model No. 2216e general purpose PID (Proportional-Integral-Derivative) temperature controller from Eurotherm Inc. of Leesburg, Va. has as an input the thermocouple leads  204  from the thermocouple  202 , and is connected through the heater leads  200  to operate the cartridge heater  198  at the desired temperature. 
     Referring next to  FIG. 16 , a tubular knitted pile fabric  220  (which may be any one of the tubular knit segments  30 ,  80  and  300  described herein) having a first end  222  and a second end  224  is shown as it is about to be pulled onto the exterior surface of a hollow cylindrical aluminum heating tube  226  having a first end  228  and a second end  230  and a nonstick substance  232  on the outer surface thereof. The aluminum heating tube  226  has an outer diameter that is approximately the same as the inner diameter of a finished paint roller cover core (paint roller cover cores typically have an inner diameter of approximately one and one-half inches (38 millimeters), although alternative sizes such as inner diameters of one and three-quarters inches (44 millimeters) and two inches (51 millimeters) can be manufactured as well). 
     The aluminum heating tube  226  has an inner diameter of approximately one and three-eighths inches (35 millimeters) or slightly greater and is sized to fit removably over the mandrel  192  of the mandrel heating assembly  190  (shown in  FIGS. 13 and 14 ). (It should be noted that the inner diameter of the aluminum heating tube  226  is not critical, and indeed will vary according to the outer diameter of the mandrel  192  of the mandrel heating assembly  190 .) The outer surface of the aluminum heating tube  226  is coated with a low coefficient of friction material such as silicone or polytetrafluoroethylene (PTFE, such as the material marketed by DuPont under the trademark TEFLON) to provide a non-stick substance  232  thereupon. 
     The tubular knitted pile fabric  220  has an inner diameter that is approximately the same size as or slightly smaller than the outer diameter of the aluminum heating tube  226 . The tubular knitted pile fabric  220  may be sized to require that it be stretched slightly when it is placed onto the aluminum heating tube  226  in order to achieve the correct density and/or positioning. Alternately, the tubular knitted pile fabric segment  220  could also be slightly larger than the outer diameter of the aluminum heating tube  226  and shrunk slightly (through the subsequent application of heat which will be discussed below) to closely conform to the aluminum heating tube  226 . 
     The tubular knitted pile fabric  220  is of a length that corresponds to the desired length of a paint roller cover. For a nine inch (229 millimeters) long paint roller cover, the tubular knitted pile fabric  220  will have to be sufficiently long such that following the application of heat the resulting paint roller cover will be of the desired length. Experience has indicated that there may be shrinkage in length during the application of heat (in one instance, the shrinkage in length was approximately eight percent. Accordingly, if an eight percent shrinkage in length is anticipated, the tubular knitted pile fabric  220  will need to be approximately 9.8 inches (249 millimeters) long. 
     It will be appreciated by those skilled in the art that the tubular knitted pile fabric  220  could alternately be sized for use in manufacturing a plurality of paint roller covers of any of several different lengths. For example, the tubular knitted pile fabric  220  could be approximately one hundred inches (2.54 meters) long, which is a sufficient length to allow it to be used for the manufacture of seven nine inch (229 millimeter) long paint roller covers. In this case, of course, the aluminum heating tube  226  and the mandrel heating assembly  190  (shown in  FIGS. 13 and 14 ) would have to be proportionately longer as well. 
     In  FIG. 16 , the tubular knitted pile fabric  220  is shown with its second end  224  about to be pulled over the first end  228  of the aluminum heating tube  226 .  FIG. 17  shows the tubular knitted pile fabric  220  partly pulled onto the aluminum heating tube  226 , and  FIG. 18  shows the tubular knitted pile fabric  220  fully pulled onto the aluminum heating tube  226 , with the second end  224  of the tubular knitted pile fabric  220  located close adjacent to the second end  230  of the aluminum heating tube  226 . The tubular knitted pile fabric  220  fits easily on the outer diameter of the aluminum heating tube  226 , and is not stretched on the aluminum heating tube  226 . 
     Referring next to  FIG. 19 , the aluminum heating tube  226  with the tubular knitted pile fabric  220  located thereupon is about to be placed onto the mandrel heating assembly  190 . As mentioned above, the inside diameter of the aluminum heating tube  226  is sized to fit removably over the outer diameter of the mandrel  192  of the mandrel heating assembly  190 , but with a relatively close fit to allow heat from the mandrel heating assembly  190  to be transferred to and through the aluminum heating tube  226 . Prior to placing  226  with the tubular knitted pile fabric  220  located thereupon over the mandrel heating assembly  190 , the mandrel heating assembly  190  is brought up to the desired temperature. Typically, this will take less than one minute. 
     The temperature of the mandrel heating assembly  190  is a function of which particular bicomponent material is used in the low melt yarn used for the backing and/or pile of the tubular knitted pile fabric  220 . More specifically, the temperature used must be at or above the melting point of the low melt component used in the backing and/or pile materials, but below the melting point of the high melt component used in the backing and/or pile material of the tubular knitted pile fabric  220 . The temperature of the mandrel heating assembly  190  accordingly varies according to the properties of the bicomponent material, and will typically be set between approximately 375 degrees Fahrenheit (190 degrees Celsius) and approximately 435 degrees Fahrenheit (224 degrees Celsius), although with some bicomponent materials the temperature may vary from as low as approximately 250 degrees Fahrenheit (121 degrees Celsius) to as high as 600 degrees Fahrenheit (316 degrees Celsius). 
     In  FIG. 19 , the aluminum heating tube  226  with the tubular knitted pile fabric  220  located thereupon is shown with the second end  230  of the aluminum heating tube  226  about to be pulled over the mandrel heating assembly  190 .  FIG. 20  shows the aluminum heating tube  226  with the tubular knitted pile fabric  220  located thereupon fully pulled onto the mandrel heating assembly  190 , where it is heated and maintained for a period of time sufficient to activate the backing yarn and/or the looped portions/knit ends of the pile fibers. (Activating the backing yarn and/or looped portions/knit ends of the pile fibers constitutes melting the low melt component of the bicomponent material of the backing and/or pile yarn of the tubular knitted pile fabric  220  so that it will flow together to lock the backing yarn and knit loop portions of the pile fibers into an integral cylindrical core around the aluminum heating tube  226 .) 
     This period of time can vary between approximately five seconds to approximately ninety seconds, with typical times for most bicomponent materials varying from approximately five seconds to approximately sixty seconds. During this activation process, the length of the tubular knitted pile fabric  220  may shrink somewhat, as mentioned above. Clamps securing the fabric in place (not shown herein) can be utilized to minimizing or eliminate the fabric&#39;s shrinking characteristics. Following the activation process, the aluminum heating tube  226  with the now-activated tubular knitted pile fabric  240  (as indicated in  FIG. 21 ) located thereupon is removed from the mandrel heating assembly  190  and allowed to cool, which typically takes only a few seconds. The activated tubular knitted pile fabric  240  may then be removed from the aluminum heating tube  226 . 
     Referring next to  FIG. 21 , the activated tubular knitted pile fabric  240  is shown as having a first end  242  and a second end  244 , with a pile  248  extending outwardly from the activated tubular knitted pile fabric  240 . The inside of the activated tubular knitted pile fabric  240  is a cylindrical fused backing, comprising a substantially rigid integral core member  246  on the inside surface thereof. Finishing the activated tubular knitted pile fabric  240  will include the steps of combing the pile  248  of the activated tubular knitted pile fabric  240  and shearing it to the desired length. Finally, the ends  242  and  244  of the activated tubular knitted pile fabric  240  may be finished and the edges of the activated tubular knitted pile fabric  240  may be beveled, and any loose fibers may be vacuumed off. 
     While the exemplary embodiment discussed above produces a nine inch (229 millimeter) paint roller cover, the tubular knitted pile fabric  220 , the aluminum heating tube  226 , and the mandrel heating assembly  190  (as shown in  FIGS. 19 and 20 ) could alternately be sized for use in manufacturing a plurality of paint roller covers of any of several different lengths. For example, a substantially longer activated tubular knitted pile fabric  240  could be produced and subsequently be cut into unfinished paint roller cover segments of any desired size. These unfinished paint roller cover segments would then be finished as described above. 
     Turning now to  FIG. 22A , one embodiment of a an exemplary adhesive spray device  400  is schematically illustrated. The spray device  400  includes an elongated fluid delivery tube or shaft  401  having a first or proximal end  402  including an adhesive input  406  and, preferably, an air input  408 . The adhesive input  406  is in fluid communication with an adhesive source  410 , which can be provided any means known to those skilled in the art. The air input  408  is in communication with an air source  412 , which is preferably a pressurized air source. The pressure of the pressurized air is determined by a number of factors, including, the type and viscosity of adhesive used, the type of spray device and spray nozzle selected, as will be understood by those skilled in the art. The first end  402  will also include a connection or mixing chamber, indicated generally at  414 , wherein the adhesive and pressurized air are mixed prior to dispensation of the adhesive. 
     The adhesive spray device  400  includes a second or distal end  404  comprising a spray nozzle  418 . The nozzle is preferably capable of providing a 360 degree circular adhesive spray. A spacer  420  can be included to ensure that the spray nozzle  418  of the spray device is correctly centered inside the tubular knitted pile fabric  240 . Indeed,  FIG. 22B  illustrates the spray device  400  provided without the spacer  420 . Spray devices that can be used with good effect include those manufactured by Binks, ITW Industrial Finishing (Glendale Heights, Ill.). 
     The present invention includes applying at least one layer of spray adhesive on to the cooled, integral core formed by the re-hardened low melt yarn backing material of the tubular knitted pile fabric  240  to create an enhanced rigid cylindrical assembly having a pile surface. 
     The adhesive used for the adhesive layer in the methods of the present invention may be one or more of a two-part or one-part adhesive, and is preferably provided in a “liquid” form. As defined herein, a liquid adhesive can include compositions that are provided as liquid or substantially liquid, gel, foam and/or in a liquid emulsion or dispersion form. It will be appreciated that the viscosity of the liquid adhesive will depend on the particular composition of the adhesive selected, the particular solvents utilized therewith and the desired cured and/or dried properties (e.g. strength, water resistance, permeability) of the adhesive. Such adhesive compositions can include but are not limited to polyurethane and urethane adhesives, acrylics, epoxies, latex, synthetic latex, glycerin based compounds, silicone based compounds, other natural or synthetic polymeric adhesives as known to those skilled in the art, or a combination thereof. The viscosity of the adhesive selected for use in the present invention is preferably selected so as to avoid dripping or running of the adhesive layer once it is applied to the tubular knitted pile fabric  240 . Preferably, the spray adhesive, when cured and/or dried, is a substantially waterproof and/or water resistant. 
     Preferably, the adhesive is a polyurethane composition utilizing an isocynate crosslinking agent, and having a viscosity of approximately about 2000 centipoise. As will be understood by those skilled in the art, other crosslinking agents can be used with good effect. The polyurethane adhesive can include one or more additives including catalysts, chain-extenders, stabilizing agents, and plasticizers as are known to those skilled in the art. In particular, the polyurethane adhesive used in the present invention can include one or more catalysts including, but not limited to tertiary amines such as triethylenediamine, N-methylmorpholine, N-ethylmorpholine, diethylethanolamine, N-cocomorpholine, 1-methyl-4-dimethylaminoethylpiperazine, 3-methoxypropyldimethylamine, N,N,N-trimethylisopropyl propylenediamine, 3-diethylamino-propyldiethylamine, dimethylbenzylamine, and the like. Other suitable catalysts are, for example, stannous chloride, dibutyltin-di-2-ethyl hexonate, potassium hexanoate, stannous oxide, as well as other organometallic compounds known to those skilled in the art. 
     Turning next to  FIG. 23 , the liquid adhesive is applied to the tubular knitted pile fabric  240  while the assembly is positioned in a substantially vertical orientation. The tubular knitted pile fabric  240  can be held in place by clamps (not shown) or by any means known to those skilled in the art. 
     As illustrated in  FIG. 23 , the spray device  400  is mounted to a substantially horizontal plane  422 , so that that the spray device  400  is disposed in a substantially vertical position. Although other configurations can be used, it is preferable that the spray device  400  is mounted in this vertical fashion with the nozzle  418  in a generally spaced apart position from the top edge  242  of the tubular knitted pile fabric  240 . 
     The spray device  400  can be vertically and positionably mounted by any positioning means  430  known to those skilled in the art. For example, the positioning means  430  can be a hydraulic or air actuated mechanism including an extendable shaft  432  for moving the spray device  400  from a first position  434  (as illustrated in  FIG. 23 ) to a second position  436  (as illustrated in  FIG. 24 ) and to a plurality of vertically positions therebetween. 
     Once the tubular knitted pile fabric  240  is properly positioned beneath the spray device  400  so that the nozzle  418  is substantially centered in the middle of the integral core  246  of the tubular knitted pile fabric  240 , the spray device is lowered to the lower position  436 . In this way, at least a portion of the spacer  420  is positioned inside the tubular knitted pile fabric  240  and the nozzle  418  is vertically positioned at approximately the bottom end  244 , or below the bottom end  244 , of the tubular knitted pile fabric  240 , as illustrated in  FIG. 24 . As shown in  FIG. 25 , the nozzle  418  of the spray device is substantially centered inside the tubular knitted pile fabric  240 . 
     As illustrated in  FIGS. 26 and 27 , the liquid adhesive  438  is continuously sprayed on to the integral core member  246  of the tubular knitted pile fabric  240  as the nozzle  418  of the spray device  400  is moved from the lower position  436  (as shown in  FIG. 24 ) back to the higher position  434  (as shown in  FIG. 23 ), leaving a substantially uniform layer  440  of adhesive on the inside surface of the tubular knitted pile fabric  240 . The spray device  400  is turned off after the integral core member  246  of the tubular knitted pile fabric  240  has a complete layer  440  of adhesive provided thereon. It will be understood that although only a single layer of adhesive  440  is shown in  FIGS. 27 and 28 , multiple layers of adhesive  440  can be provided, depending on the end use application of the paint roller cover. 
     It will be appreciated that the thickness of the layer of adhesive  440  depends on the type of adhesive selected and the desired end use of the paint roller cover. When polyurethane is used as the adhesive, the thickness of the layer of adhesive  440  is preferably approximately about 7 mils or less, and most preferably about 1 to about 2 mils. The adhesive layer  440  is preferably thick enough to provide the integral core member  246  of the tubular knitted pile fabric  240  with sufficient rigidity for its intended use, and to provide any desired water resistance and/or impermeability properties desired in the end use product. 
     The speed of the adhesive spray device  400  as it moves from a low position to a high position during spraying and the flow rate of adhesive spray  438  that comes out of the nozzle  418  of the sprayer  400  is determined by a number of factors, including but not limited to, the type of spray device  400  selected, the pressure of the pressurized air source provided to the spray device  400 , the viscosity, type and cure rate of the adhesive selected, the desired thickness of the adhesive layer  440 , the type of knit backing material used in the tubular knitted pile fabric  240 , and is therefore a matter of design choice and can be determined as understood by those skilled in the art. In certain preferred embodiments of the present invention, the adhesive layer  440  is applied to the tubular knitted pile fabric  240  in about 20 seconds or less, and most preferably in about 1 to about 3 seconds, depending on the length and diameter of the tubular knitted pile fabric  240 . 
     Preferably, adhesive  438  is sprayed only as the spray device  400  moves from a lower vertical position to a higher vertical position along the length of the tubular knitted pile fabric  240 ; however, consistent with the broader aspects of the present invention, adhesive can be sprayed as the spray device moves in a vertically downward direction, from a high position to a low position. 
     Further, as will be understood by those skilled in the art, the spray device  400  may be vertically mounted in a stationary position, with the tubular knitted pile fabric  240  being moved vertically up and down with respect to the stationary spray nozzle. In this way, the bottom end  244  of the tubular knitted pile fabric  240  will move to a position above or substantially equal to the nozzle  418  of the spray device  400  and is centered with respect to the nozzle  418 . The spray device  400  is then turned on to provide a layer of adhesive to the tubular knitted pile fabric  240  as the tubular knitted pile fabric  240  is moved from a high vertical position to a low vertical position. The spray device  400  would be shut off as the top end  242  of the tubular knitted pile fabric  240  passes the nozzle  418 . spraying. 
     In certain other embodiments of the present invention, the spray device can be manually operated, and used to provide the layer of adhesive  440 , as will be appreciated by those skilled in the art. Also, it will be understood that the interior surface of the tubular knitted pile fabric  240  can be coated with a liquid adhesive while the tubular knitted pile fabric  240  is oriented horizontally. 
     After application of one or more layers of adhesive onto the inside surface of the cylindrical pile fabric assembly, the adhesive is allowed to cure and/or dry. Drying can occur via air or ambient means, or alternatively, radiant heat (oven dry), ultraviolet radiation and/or radio frequency methods can be used to cure/dry the adhesive layer  440 . The drying temperature will depend on the type of adhesive selected, the thickness of the layer of adhesive  440 , and the particular solvent used therein. Such drying times can range from a few minutes to about 30 minutes. 
     An alternate embodiment of the paint roller cover manufacturing method of the present invention is shown in  FIGS. 29 through 33 . Referring first to  FIG. 29 , prior to application of the spray adhesive, one or more layers of dry adhesive film  250  is wound around the aluminum heating tube  226 . The dry adhesive film  250  generally consists of a thin plastic film that is coated on one side (the side that will be wound facing outwardly) with a non-tacky adhesive, and may optionally have a pressure-sensitive adhesive on the opposite side to facilitate the installation of the dry adhesive film  250  onto the aluminum heating tube  226 . One dry adhesive film that may be used, for example, is Stock No. 233 from Lenderink Technologies in Belmont, Mich. The thickness of the dry adhesive film  250  may vary from approximately 0.0005 inches (0.0127 millimeters) thick to approximately 0.01 inches (0.254 millimeters) thick. For example, from one to seven layers of 0.0012 inch (0.0305 millimeter) thick dry adhesive film  250 , or from one to three layers of thicker dry adhesive film  250  (0.0024 inch (0.61 millimeter) thick to 0.0072 inch (0.183 millimeter) thick) being used. The dry adhesive film  250  is cut when a sufficient length of the dry adhesive film  250  has been wound around the aluminum heating tube  226  to form a wrapped dry adhesive film  252 , as shown in  FIG. 30 . 
     Referring next to  FIG. 31 , the tubular knitted pile fabric  220  is shown with its second end  224  about to be pulled over the first end  228  of the aluminum heating tube  226 , and then onto the wrapped dry adhesive film  252  on the aluminum heating tube  226 .  FIG. 32  shows the tubular knitted pile fabric  220  fully pulled onto the wrapped dry adhesive film  252  on the aluminum heating tube  226 , with the aluminum heating tube  226  with the tubular knitted pile fabric  220  and the wrapped dry adhesive film  252  located thereupon about to be placed over the mandrel heating assembly  190 . 
       FIG. 33  shows the aluminum heating tube  226  with the tubular knitted pile fabric  220  and the wrapped dry adhesive film  252  located thereupon fully pulled onto the mandrel heating assembly  190 , where it is heated and maintained for a period of time sufficient to activate the wrapped dry adhesive film  252  and the backing yarn/looped ends of the low melt pile fiber, with the wrapped dry adhesive film  252  and the low melt component of the bicomponent material of the backing yarn and looped ends of pile fiber of the tubular knitted pile fabric  220  flowing together to form an integral cylindrical core around the mandrel  192  of the mandrel heating assembly  190 . Following the activation process, the aluminum heating tube  226  with the now-fused together material is removed from the mandrel heating assembly  190  and allowed to cool. The resulting assembly may then be removed from the aluminum heating tube  226  and finished as described above. 
     Referring finally to  FIG. 34 , the paint roller cover manufacturing method of the present invention is shown in a flow chart that includes a number of the variations discussed herein. The paint roller cover manufacturing operation starts in a manufacture tubular knitted pile fabric sleeve step  260  in which the tubular knitted pile fabric used in the tubular knitted pile fabric  220  (shown in  FIGS. 1 through 6 ) is manufactured. 
     The tubular knitted pile fabric used in the tubular knitted pile fabric  220  (shown in  FIGS. 1 through 6 ) is represented in a manufacture tubular sliver knit fabric sleeve  260 A, which corresponds to manufacture of the tubular sliver knit segment  30  shown in  FIGS. 1 and 2 . The tubular knitted pile fabric used in the tubular knitted pile fabric  220  can also be a tubular cut pile yarn fabric sleeve  260 B, which corresponds to manufacture of the tubular cut pile yarn segment  80  shown in  FIGS. 3 and 4 . The tubular knitted pile fabric used in the tubular knitted pile fabric  220  can also be a tubular knit fabric sleeve  260 C including tufts of pile fibers and cut pile yarn segments, which correspond to manufacture of the tubular knit segment  300  shown in  FIGS. 5 and 6 . 
     The process next moves to a cut tubular knitted pile fabric sleeve to length step  262  in which the tubular knitted pile fabric is cut to the desired length of the tubular knitted pile fabric  220  (shown in  FIGS. 16 through 20 ). As mentioned above, the tubular knitted pile fabric  220  will have to be sufficiently long such that following the application of heat the resulting paint roller cover will be of the desired length, taking account of shrinkage that may occur during the heating process. Alternately, the tubular knitted pile fabric  220  could be sized for use in manufacturing a plurality of paint roller covers of any of several different lengths. For example, a substantially longer activated tubular knitted pile fabric  240  (similar is appearance to that shown in  FIG. 21 , except longer in length) could be produced and subsequently be cut into unfinished paint roller cover segments of any desired size. 
     Optionally, an invert fabric sleeve step  263  is included if the tubular knitted pile fabric  220  is provided in a pile side-in manner. 
     Optionally, an apply dry adhesive film to aluminum heating tube step  264  can then be used if it is desired to apply the wrapped dry adhesive film  252  (shown in  FIG. 22 ) under the tubular knitted pile fabric  220  on the aluminum heating tube  226 . 
     With or without the apply dry adhesive film to aluminum heating tube step  264 , the tubular knitted pile fabric  220  is placed onto the aluminum heating tube  226  in a place tubular knitted pile fabric sleeve on aluminum tube step  266 , as shown in  FIGS. 16 through 18  (without the wrapped dry adhesive film  252 ) or in  FIG. 31  (with the wrapped dry adhesive film  252 ). The process next moves to a preheat mandrel to desired temperature step  268 , wherein the mandrel heating assembly  190  is heated to the desired temperature to activate the low melt component in the backing of the tubular knitted pile fabric  220 . 
     The process then moves to a place aluminum heating tube with fabric sleeve onto mandrel step  270 , in which the aluminum heating tube  226  with the tubular knitted pile fabric  220  (and, optionally, the wrapped dry adhesive film  252 ) located thereupon is placed onto the mandrel heating assembly  190  to initiate the heating process, as shown in  FIG. 19 . The aluminum heating tube  226  with the tubular knitted pile fabric  220  (and, optionally, the wrapped dry adhesive film  252 ) located thereupon is heated on the mandrel heating assembly  190  for a predetermined time as shown in  FIG. 20  in a heat fabric sleeve on mandrel for a predetermined time step  272 . 
     The process then moves to a remove aluminum tube with activated fabric sleeve from mandrel step  274  in which the aluminum heating tube  226  with the activated tubular knitted pile fabric  240  (shown in  FIG. 21 ) is removed from the mandrel heating assembly  190  and allowed to cool. At this point, the activated tubular knitted pile fabric  240  has cooled and has an integral cylindrical fused backing  246  located on the inside thereof, as indicated in a fabric sleeve has formed integral core member step  276 . 
     An apply liquid adhesive layer to integrally formed core member of tubular fabric sleeve step  277  is used to further enhance the rigidity of the integrally formed core member  246  of tubular fabric sleeve  240 , as illustrated in  FIGS. 22A through 29 . A cure/dry adhesive layer step  279  follows the application step  277 . 
     Next, in an optional cut fabric-covered core member to desired lengths step  278 , the activated tubular knitted pile fabric  240  may be cut into a plurality of unfinished paint roller covers of any desired size. This step is, of course, not performed if the tubular knitted pile fabric  220  was cut to meet its finished size in the cut tubular knitted pile fabric sleeve to length step  262 . The unfinished paint roller covers may then have the fabric pile thereupon combed and sheared to a desired length in a comb and shear fabric pile step  280 . It should be noted that the comb and shear fabric pile step  280  may instead be performed before the cut fabric-covered core member to desired lengths step  278 . 
     Next, in a bevel edges of paint roller covers step  282 , the edges of the unfinished paint roller covers are beveled to finish them. Finally, in a vacuum paint roller covers step  284 , loose fibers are vacuumed off the unfinished paint roller covers, finishing them into paint roller covers which may then be packaged and sold (typically, vacuuming is accomplished throughout the brushing, shearing, and beveling steps rather than as a separate step). 
     It may therefore be appreciated from the above detailed description of the preferred embodiment of the present invention that it teaches a method by which a paint roller cover having an integrally formed core member may be manufactured from tubular knitted pile fabric. The paint roller cover manufacturing methods of the present invention results in an acceptable pile which extends from an acceptably rigid core which can be installed on and used with any conventional paint roller frame, or on a frame uniquely designed for the paint roller utilizing the new core design. 
     The paint roller cover manufacturing method of the present invention facilitates either the manufacture of a paint roller cover of a desired finished length, or the manufacture of an extended length segment from which segments of any desired size can be cut for finishing as paint roller covers, thereby facilitating the mass manufacture of paint roller covers. The paint roller cover manufacturing method of the present invention can use tubular knitted pile fabric including sliver fibers, cut yarn pile or a combination of each, as well as utilize a number of different backing materials. 
     The paint roller cover manufacturing method of the present invention results in a construction which is both durable and long lasting, and yields a paint roller cover of superior quality. The paint roller cover manufacturing method of the present invention also reduces the cost of manufacturing paint roller covers when compared to conventional methods of manufacturing paint roller covers by manufacturing paint rollers without using a separately provided core member, thereby affording it the broadest possible market. Finally, all of the aforesaid advantages and aspirations of the paint roller cover manufacturing method of the present invention are achieved without incurring any substantial relative disadvantage. 
     Although the foregoing description of the paint roller cover manufacturing method of the present invention has been shown and described with reference to particular embodiments and applications thereof, it has been presented for purposes of illustration and description and is not intended to be exhaustive or to limit the invention to the particular embodiments and applications disclosed. It will be apparent to those having ordinary skill in the art that a number of changes, modifications, variations, or alterations to the invention as described herein may be made, none of which depart from the spirit or scope of the present invention. The particular embodiments and applications were chosen and described to provide the best illustration of the principles of the invention and its practical application to thereby enable one of ordinary skill in the art to utilize the invention in various embodiments and with various modifications as are suited to the particular use contemplated. All such changes, modifications, variations, and alterations should therefore be seen as being within the scope of the present invention as determined by the appended claims when interpreted in accordance with the breadth to which they are fairly, legally, and equitably entitled.