The present invention relates to knitted gloves. More specifically; the invention relates to knitted gloves, knitted glove liners and novel methods of making them.
Knitted gloves are commonly used in handling and light assembly conditions. Knitted gloves used for these purposes are currently made using flat knitting machines that use a number of needles in the form of a needle array and a single yarn to knit the gloves using eight basic components to comprise the glove. These eight components include one component for each of the five fingers, two components for the palm including a upper section and a lower section; and one component for the wrist area. All these sections are cylinders or conical sections that join to each other fashioning the general anatomical shape of a hand. Conventional knitting processes use a knitting machine to knit each of these areas in a particular sequence, generally one finger at a time, beginning with the pinky finger and continuing on through the ring finger and middle finger to the forefinger. After each finger is knitted using only selected needles in the needle array, the knitting process for this finger is stopped and yarn is cut and bound. The knitted finger is held by holders, weighted down by sinkers. The next finger is knit sequentially one at a time using a different set of needles in the needle array. When all the four fingers are knitted in this fashion, the knitting machine then knits the upper section of the palm picking stitches from each of the previously knit four fingers. The method of knitting individual fingers and picking stitches to knit the upper palm selection with better fitting crotches that are well fitted is discussed in U.S. Pat. No. 6,945,080 by Maeda, et al. After knitting an appropriate length of upper palm, the thumb portion is initiated using a separate set of needles in the needle array and the lower section of the palm is knit using all the needles in the needle array. Finally, the knitting machine knits the wrist component to the desired length.
The knitting stitches used at the fingertips are generally tighter than the stitches used elsewhere in the glove to improve the strength of the glove in this area where more pressure is likely to be applied. Depending on the size of the needles used and the denier of the yarn to knit the gloves, a certain number of courses are used to create each of the eight components of the glove. The finer the gauge of needle used; the higher the number of courses for each component to create the same size of a finished glove. Changing needles or the denier of a yarn is extremely difficult in a continuous process and generally a continuous yarn of pre-selected denier and a corresponding needle size is commercially used. While this standardization in needle size and number of courses permits the manufacturing of a glove or liner with a standard shape, that shape does not accommodate variations in size and shape of individual fingers and hands.
U.S. Pat. No. 5,284,032 to Shima discloses stitch control mechanism for a flat knitting machine. A stitch control mechanism is applicable for a flat knitting machine and controls loop size in a knit fabric. A spiral cam plate is attached to one surface of a stitch control cam. The spiral cam plate is held between a pair of cam rollers, and the pair of cam rollers is supported on a guide plate. The stitch cam has a portion slidably fitted in a guide slot formed in a base plate. The stitch dimension or loop size is controlled by the stitch control cam and can be changed by a computer program. This patent discloses the hardware necessary for stitch dimension control and does not disclose a knitted glove or liner with anatomic features providing improved fit.
U.S. Pat. No. 5,547,733 to Rock et al discloses plaited double knit fabric. The composite fabric of terry construction includes an inner fabric layer made of a yarn comprising a plurality of hydrophilic treated polyester fibers and an outer fabric layer made of he same hydrophilic treated polyester fibers. The inner fabric layer and outer fabric layer are formed concurrently by a plaited knit construction so that the layers are distinct, yet integrated with one another. The textile fabric rapidly removes moisture from the skin of the user. This plaited double knit fabric is tightly woven with the outer fabric layer that integrates with the inner fabric layer creating a double knit article with limited stretcability.
U.S. Pat. No. 5,965,223 to Andrews et al discloses layered composite high performance fabric. The composite layered protective fabric has an outer primary layer composed of an abrasive material and an inner primary layer composed of an inherently cut-resistant material positioned below the outer primary layer. The inner layer, when assembled into a garment, is positioned proximate to the wearer's skin. A secondary layer may be added to the inner and outer layer framework and is composed of a material that provides additional protection against potential threats other than cuts, that increases comfort or that improves aesthetics. The composite fabric is continuously manufactured in a one-step process, which plates the primary abrasive and cut resistant yarn layers. The presence of multiple yarns tightly knitted together creates a knitted article that is stiff and does not accommodate complex shapes such as a glove. Every portion of the fabric thus formed is composed of the outer primary layer and the inner primary layer and no stretchable portions are provided within the fabric.
U.S. Pat. No. 6,155,084 to Andrews et al. discloses protective glove articles made of a continuously knit composite fabric. These protective articles provide an unprecedented level of safety and comfort and are made of two or more dissimilar yarns including thermoplastics, elastomers, or metals forming primary, secondary and tertiary regions. The secondary region covers the thumb and palm and has superior cut resistance compared to the primary region which covers the finger stalls. The tertiary region covers the wrist portion and its cut resistance is between that of the primary and secondary regions. All the regions of the glove contain the cut resistant fibers and contain one or more fibers. The regions are not knitted with any stretchability and use of two yarns provides a tightly knitted fabric presenting a glove which has a tight uncomfortable feel. The protective article uses dissimilar fibers at selected protective fabric locations and does not aim to conform to the anatomical shape of a hand using a single yarn or multiple yarns.
U.S. Pat. No. 6,550,285 to Nishitani discloses yarn feeding apparatus. This apparatus minimizes fluctuation in tension of a knitting yarn and an accurate length of the knitting yarn is fed even if the amount of demand for the knitting yarn is suddenly changed. A knitting yarn is interposed between a main roller and a driven roller with yarn storage having a buffer rod, the angular inclination of which controls the storage. An angle sensor detects this angular inclination and uses a PID algorithm to predict the amount of knitting yarn demanded. The PID algorithm controls a servo-motor that drives the driven roller such that the tip portion of the buffer rod is brought to its original position at start of knitting. This device minimizes the fluctuations in knitting yarn tension due to sudden demand and is not programmed to alter the knitting yarn tension in order to adjust stitch dimensions.
U.S. Pat. Nos. 6,782,721 and 6,823,699 to Vero et al. discloses unilayer fabric garment with reinforcing parts. A previously knit unilayer textile fabric is inserted with a heavier denier fiber at preselected areas of the fabric by a computer program. The inserted fiber is selected from the group consisting of S-glass fibers, E-glass fibers, steel filaments, carbon fibers, boron fibers, aluminum fibers, zirconium-silica fibers, aluminum-silica fibers, and mixtures thereof. The fabric article may be a garment or a glove providing the user with protection from abrasion cuts and punctures. The inserted fibers are high elastic modulus stiff fibers and presence of two fibers in a given region of a garment or glove compromises the flexibility at that location. Gloves with this reinforcement method are stiff and do not readily conform to the anatomy of user's hands.
U.S. Pat. No. 6,962,864 to Hardee, et al. discloses a knitted glove. This knitted glove is made by creating eight glove components having at least fifteen separate knitted sections altogether on a knitting machine. The glove includes five finger components made from at least two separately knitted sections for each finger component, two palm components, each of which is made from at least two separately knitted sections, and a wrist component made from at least one knitted section. Each component comprises a different stitch setup producing variable stitch dimensions and number of courses whereupon the glove has an overall shape that accommodates variations in size and shape of individual fingers and hands. The entire glove is knit with a single yarn and therefore does not have cut resistant properties or other property enhancements possible by using multiple yarns in different glove components.
Standard shape gloves or liners created by the current processes bring with them several disadvantages. First, the fit across finger knuckles and the center of the palm is tight, reducing glove or liner flexibility and ultimately reducing hand dexterity. Second, the standard gloves or liners tend to bag or gap in areas where the hand normally tapers; like the lower palm and wrist area; the excess fabric in the baggy areas can bunch and catch on protruding objects. Additionally, excess fabric at the lower palm created by the standard glove or liner shape causes an irregular foam line on those liners that are dipped in latex. Finally, the excess fabric at the lower palm of the standard glove or liner causes a high scrap rate in printing information on the gloves or liners. The problem is more severe when more than one fiber is used at any glove location resulting in a tighter, less flexible knit that does not provide a comfortable fit on the hand of the user.
In an attempt to solve these problems, knit gloves or liners can be made larger than standard size and shrunk by tumbling them in heat or using a laundry process to achieve a better fit. These processes as used on the larger gloves, however, may produce gloves that have improved fit across the knuckles, but do not address the excess fabric in areas where the hand normally tapers, like the lower palm and wrist, since the shrinkage is uniform across the glove.
Additionally, tumbling or a laundry process would require an additional manufacturing step as well as additional labor, both of which would increase the cost of the finished product. A standard tumbling process, using constant heat and time, would also fail to create the desired gloves and liners because of differences in thermal patterns in the tumbler and the heat sensitivity of fibers selected to knit the gloves and liners in a manufacturing operation. Further, these types of post-knitting processes would require additional development and manufacturing time to determine appropriate time and heat combinations to optimize the production of a particular glove or liner.
A glove with a selective second fiber, which may be cut resistant or of a different color that could be made to fit the contours of a human hand and that would not require post-knitting processing would therefore be an important improvement in the art.
The present invention is directed toward a continuously knitted gloves and liners with selected glove area reinforcement with a fiber of different denier, different fiber properties. The method of making these knitted gloves and liners consists of using continuous one or more yarns and an array of knitting needles matching the yarn denier. When a second yarn is introduced, the same single needle, which does the knitting of the glove, carries the first and second yarns together. When the selected area of the glove is completed, the second yarn is cut off, while the first yarn continues the knitting process. At a later time, when knitting a different selected area of the glove is being knitted, the second yarn is added to the first yarn to create a knitted region with the two yarn fibers. The second yarn may have a heavier or lighter denier than the first yarn. The second yarn may have a different color compared to the first yarn. The second yarn may be cut resistant or abrasion resistant while the first yarn may be a soft fiber preferably with moisture absorbing properties. We have surprisingly found that when the second yarn has a heavier denier compared to the first yarn and the knit at a given glove area has increased stretch ability, the heavier second yarn occupies on one side of the glove while the lighter denier yarn occupies the other side of the glove. If the knit is tightly formed such separation of yarn fibers does not consistently occur and the heavier and lighter denier yarns are mixed. If the heavier denier second yarn is cut resistant or abrasion resistant, and the lighter denier first yarn is moisture absorbing, a glove produced using knits with enhanced stretch ability has moisture absorbing yarn fibers in contact with the skin of the user while the cut resistant fibers or abrasion resistant fibers are on the outer surface of the glove protecting the user's hand. If the heavier second yarn is of a bright color, the glove displays bright color at the selected area of the glove providing better visibility for these selected regions. For example, the finger tips of a glove may be of bright color indicating the location of these vulnerable finger tips in a hazardous manufacturing operations.
The invention relates to the fit of knitted gloves or liners on a human hand. Specifically, the stitch dimension and the number of courses used to knit each of the standard eight major glove components and their sections of the glove is altered to provide a glove geometry which is anatomically matched to a human hand providing increased stretch capability in areas which flex during hand movement. This increased stretch capability provides the wearer with a tight fitting glove even when two fibers are present at a given glove region, which still provides comfortable glove feel and easy movement capability. These geometric alterations help conform the glove or liner to provide better fit on human hands. These alterations permit continuous knitting and manufacturing of gloves or liners with nearly perfect fit to the hand because of their tapered fingertips, expanded knuckles, tapered palm areas and expanded cuff width.
The stitch dimension in each course that is knitted determines the level of stretch available at that knitted course location. The number of courses determines the overall stretch of the fabric at a particular location in the glove. The stitch dimension has three discrete components, which may be changed individually or changed in combination under computer control of the flat knitting machine. The first embodiment of the stitch dimension comprises stitch setup specification, which increases or decreases the depth of penetration of the knitting needle carrying one or two yarns during knitting of fabric. Increasing the depth of penetration of the knitting needle brings in a larger length of one or two knitting yarns in the knitted loop and the stitch thus formed can expand more than stitches knitted with smaller depth of penetration. If a full course is knitted with a deeper depth of penetration, that course can stretch more readily. If subsequent courses are knitted with the same depth of penetration the fabric knitted has a uniform stretch feel. However, if the depth of penetration of the knitting needle is progressively decreased, the fabric knitted has a stretch feel that decreases progressively. Therefore the depth of penetration of the knitting needle provides a knitted fabric section of a glove that has ‘designed in’ stretch capability.
In a second embodiment of the stitch dimension, the tension in one or two yarns that are being knitted is increased or decreased under computer control. The one or two yarns are fed from spools and are clamped between a pair of pinch rollers, one of which may optionally be a computer controlled feeding roller. Due to the pinching action, the tension in the one or two yarns at the knitting head is not transmitted to the yarn spools. The computer controls the tension in the yarns in the segment between the pinch roller and the knitting head by means of a computer controlled tension adjustment mechanism. This adjustment mechanism may comprise a spiral spring carrying an arm through which each of the yarns pass. A spiral spring is attached to the arm and the other end of the spiral spring attached to a stepper motor. The computer rotates the stepper motor shaft, thereby increasing or decreasing the tension in the yarn in the segment between the pinch roller and the knitting head. The tension in the knit stitch limits its stretch capability. A full course stitched with increased tension has reduced stretch capability of that course. Accordingly, a fabric knitted with a number of courses with increased tension exhibits reduced stretch capability.
In a third embodiment of stitch dimension, a stitch may be missed in knitting a course. This decreases the overall stretch capability of the course. On the other hand an additional stitch may be picked from the stitch to increase the overall length of a course to provide increased stretch capability. The stitch may have one yarn or two yarns being fed to the knitting needle.
The glove has eight components, four of which define the four fingers, two of which define the palm, one defining the thumb and one defining the wrist. Each of these components is divided into one or more sections. In one embodiment, one or more of the finger components of the glove is divided into two or more sections. The upper and lower palm components are divided into two or more sections and the wrist component is made up of one or more sections, where each section is knitted using one or two yarns, a different stitch setup and each of the stitch setup is continued for a number of courses according to the desired geometrical shape of the glove. In another embodiment, each finger component of the glove is divided into three sections, and the upper and lower palm of the glove is divided into three sections, where each section is knitted using a different stitch setup and each of the stitch setup is continued for a number of courses according to the desired geometrical shape of the glove. In another embodiment, the upper and lower palm of the glove is divided into four sections, where each section is knitted using a different stitch setup and each of the stitch dimension is continued for a number of courses.
The course knitted with different stitch dimension essentially provides more yarn or less yarn at a given glove location providing enhanced or reduced stretch capability with a single yarn or two yarns included in the knitted stitch. The sections, which are required to have less stretch and therefore have a tight feel are made with stitches that incorporate a smaller length of yarn and/or at high tension or have one or more stitches less than the adjacent courses. Conversely, when a section requires increased stretch capability, the stitches are made with increased yarn length and/or with reduced tension or may have one or more stitches picked up in the courses compared to adjacent courses.
The invention also includes a method for manufacturing gloves and liners using variable stitch dimension and numbers of courses in each of the sections using one or two yarns within each of the eight major glove components to create a better fitting glove. These and other advantages of the invention will be apparent from the description of the invention provided herein.
a and 4b illustrate the first embodiment of varying stitch dimension using a stitch setup wherein the needle penetration determines the length of yarn included in the stitch.
Existing flat knitting machines can be programmed to accommodate a large number of changes in stitch dimensions using stitch setup and alter the physical dimensions used in a standard eight component glove 100 of
In
The glove 300 can be knit on a knitting machine and requires programming of the machine for each of the nineteen sections to control the stitch length. While controlled stitch stretch capability works well for single-layered fabrics with a single yarn passing through the knitting needle, the addition of a second layer formed by a second yarn passing concurrently through the knitting needle via plating or some other process will inherently decrease the stretch of the fabric. Using a variable plating process, double-layered functional zones are formed that increase the stretch in key flex areas of the gloves by altering the number of plated courses in each section. In Table 1, stretchable multi-layer functional zones are formed by plating a second functional yarn every fourth course in areas of low flex and then blending into a single-layer non-plated structure in areas of high flex. In Table 2, the same concept applies, but the functionality of the flexed areas of the zones is increased by adding a functional plating yarn every eighth course in sections where no second yarn was present. The use of every 4th and 8th course in the plating structure is for illustrative purposes only. The plating structure can range from every other course to every 9th course using the machines from Shima Seiki Mfg., Ltd. based in Wakayama, Japan. The ultimate choice of plating course structure will be dependent on the properties of the functional yarn and the desired stretch of the functional zones.
For example, the glove 300 can be made according to the specifications provided in Table 1, which shows knit courses for each yarn used. Each of the components is indicated and their sections that matches
For example, the glove 300 can be made according to the specifications provided in Table 2, which shows knit courses for each yarn used. Each of the components is indicated and their sections that matches
This specification in Table 1 and Table 2 can be used on a New Shima Full Garment Machine (NSFG) with 15 gauge and 18 gauge needle sizes, which available from Shima Seiki Mfg., Ltd. based in Wakayama, Japan to create a size 9 glove. The information for the stitch setup and the number of courses is entered into the knitting machine's operation system using a keypad and LED display. Adjustments may be made to the specifications in Table 1 to create gloves of different sizes. The gloves may be knit from different compositions of yarn, including cotton, Polyamide, polyester, polyolefin, acrylic, aramid, UHMW polyethylene, liquid-crystal polymers, PBO, water-soluble fibers including polyvinyl alcohol, or metallic filaments. The yarns used to knit the gloves may be spun yarns, textured filament yarns, or multi-component composite yarns.
a illustrates at 40 a stitch knitted with a smaller stitch setup number. The knitting needle 45 penetrates to a smaller extent including a smaller loop of yarn 46 in the stitch providing only limited stretch capability. This figure indicates for clarity one yarn, however, two yarns may be used with exactly the same geometry. Dimension ‘x’ represents the smaller loop length of the stitch dimension.
b illustrates at 40 a stitch knitted with a larger stitch setup number. The knitting needle 45 penetrates to a larger extent including a larger loop of yarn 46 in the stitch providing only enhanced stretch capability. This figure indicates for clarity one yarn, however, two yarns may be used with exactly the same geometry. Dimension ‘x’ represents the larger loop length of the stitch dimension.
The knitted variable stitch dimensions in the glove 300 allow the alteration of stitch dimension within a larger number of finger and palm sections than would be found in a standard glove 100. This increased number of sections benefits the glove by improving the degree to which it conforms to the shape of the hand, creating a better fit providing one or two yarns selected from cut resistant or abrasion resistant or colored yarns of different denier. In turn, this better fit provides increased dexterity and grip as well as increased long-term comfort in wearing the glove. In the present invention, stitch dimensions can be increasing in areas such as knuckles, which would require greater glove flexibility as fingers move.
Knitted stitch dimensions can be used to eliminate additional manufacturing steps that would be required in, for example, the use of heat or water to shrink gloves or liners to fit a particular hand size; This saves both money and time in the manufacturing process and does not require unique times, temperatures, or pressures. It also produces a more consistent product than one relying on difficult to control steps such as heat or tumbling.
A small study has been conducted to compare glove flexibility and resulting hand dexterity of standard shape gloves as compared to gloves of this invention. Subjects in the study assembled eight sets of five different nut and screw sizes while wearing the standard glove and while wearing the knitted variable stitch glove of this invention. Each subject in the study showed a decrease in the time it took to assemble the set of nuts and screws when wearing the gloves of this invention. In the study, decreases in time ranged from 13.9% to 20.3% less time for participants to assemble the sets of screws and nuts wearing the gloves of the present invention than while wearing standard knitted gloves. This study shows that the glove of this invention improved the fit of the knitted gloves such that it increased dexterity and grip over the standard glove.
The knitted gloves of this invention, once finished, may also be coated either on the outside or inside with a coating such as natural rubber latex or synthetic rubber latex, as well as other elastomeric polymer coatings. The coating may be applied by dipping the knitted glove of this invention into the coating material or by spraying the coating onto the glove. Coating the knitted gloves of this invention can improve the grip of the glove in handling dry and oily items when the coating is on the outside of the glove. The addition of a coating to the knitted layer can also improve the quality of the glove as an insulator.
Although only a few exemplary embodiments of the present invention have been described in detail above, those skilled in the art will readily appreciate that many modifications are possible in the exemplary embodiments without materially departing from the novel teachings and advantages of this invention. For example, the number of sections of the glove may be increased or decreased to adjust the fit of the glove without departing from the spirit of the present invention. Accordingly, all such modifications are intended to be included within the scope of this invention as defined in the following claims.
The use of the terms “a” and “an” and “the” and similar referents in the context of describing the invention (especially in the context of the following claims) are to be construed to cover both the singular and the plural unless otherwise indicated herein or clearly contradicted by context. Recitation of ranges of values herein are merely intended to serve as a shorthand method of referring individually to each separate value falling within the range; unless otherwise indicated herein, and each separate value is incorporated into the specification as if it were individually recited herein. All methods described herein can be performed in any suitable order unless otherwise indicated herein or otherwise clearly contradicted by context. The use of any and all examples, or exemplary language (e.g. “such as”) provided herein, is intended merely to better illuminate the invention and does not pose a limitation on the scope of the invention unless otherwise claimed. No language in the specification should be construed as indicating any non-claimed element as essential to the practice of the invention.
Preferred embodiments of this invention are described herein, including the best mode known to the inventors for carrying out the invention. It should be understood that the illustrated embodiments are exemplary only, and should not be taken as limiting the scope of the invention.
This is a continuation-in-part of application Ser. No. 11/181,064, filed Jul. 13, 2005, which is a continuation-in-part of application Ser. No. 10/892,763, filed Jul. 16, 2004, now U.S. Pat. No. 6,962,064, the disclosures of which are hereby incorporated in their entirety by reference thereto.
Number | Name | Date | Kind |
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5284032 | Shima | Feb 1994 | A |
5547733 | Moshe et al. | Aug 1996 | A |
5965223 | Andrews et al. | Oct 1999 | A |
6155084 | Andrews et al. | Dec 2000 | A |
6550285 | Nishitani | Apr 2003 | B2 |
6782721 | Vero et al. | Aug 2004 | B1 |
6823699 | Vero et al. | Nov 2004 | B1 |
6945080 | Maeda et al. | Sep 2005 | B2 |
6962064 | Hardee et al. | Nov 2005 | B1 |
6962864 | Jeng et al. | Nov 2005 | B1 |
7213419 | Hardee et al. | May 2007 | B2 |
Number | Date | Country |
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57-106753 | Jul 1982 | JP |
11-200123 | Jul 1999 | JP |
2002-201515 | Jul 2002 | JP |
2005-038116 | Feb 2005 | JP |
Number | Date | Country | |
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20070022511 A1 | Feb 2007 | US |
Number | Date | Country | |
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Parent | 11181064 | Jul 2005 | US |
Child | 11444806 | US | |
Parent | 10892763 | Jul 2004 | US |
Child | 11181064 | US |