WO1987007660A1 - Method and apparatus for modifying fabrics to produce varied effects - Google Patents

Method and apparatus for modifying fabrics to produce varied effects Download PDF

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Publication number
WO1987007660A1
WO1987007660A1 PCT/US1987/001394 US8701394W WO8707660A1 WO 1987007660 A1 WO1987007660 A1 WO 1987007660A1 US 8701394 W US8701394 W US 8701394W WO 8707660 A1 WO8707660 A1 WO 8707660A1
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WIPO (PCT)
Prior art keywords
fabric
particles
stream
effects
force
Prior art date
Application number
PCT/US1987/001394
Other languages
English (en)
French (fr)
Inventor
George R. Geller
Original Assignee
Geller George R
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority to IN25/DEL/87A priority Critical patent/IN168612B/en
Application filed by Geller George R filed Critical Geller George R
Publication of WO1987007660A1 publication Critical patent/WO1987007660A1/en

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Classifications

    • DTEXTILES; PAPER
    • D06TREATMENT OF TEXTILES OR THE LIKE; LAUNDERING; FLEXIBLE MATERIALS NOT OTHERWISE PROVIDED FOR
    • D06BTREATING TEXTILE MATERIALS USING LIQUIDS, GASES OR VAPOURS
    • D06B11/00Treatment of selected parts of textile materials, e.g. partial dyeing
    • D06B11/0093Treatments carried out during or after a regular application of treating materials, in order to get differentiated effects on the textile material
    • D06B11/0096Treatments carried out during or after a regular application of treating materials, in order to get differentiated effects on the textile material to get a faded look
    • DTEXTILES; PAPER
    • D06TREATMENT OF TEXTILES OR THE LIKE; LAUNDERING; FLEXIBLE MATERIALS NOT OTHERWISE PROVIDED FOR
    • D06CFINISHING, DRESSING, TENTERING OR STRETCHING TEXTILE FABRICS
    • D06C23/00Making patterns or designs on fabrics

Definitions

  • This invention relates to methods and apparatus for modifying fabrics to obtain varied effects. More particularly, the invention is concerned with treating fabrics to change the feel (hand) , appear ⁇ ance or material constitution of the fabrics.
  • denim garments often includes washing the garments, in various ways including regular mechnical laundering, a chlorine bleach washing, enzyme washing or stonewashing. In the latter techni- q ⁇ the fabric in the form of garments is washed in the presence of pumice stones in a mechanical laundering system including chlorine bleaching. By removing sizing and dye, garments are obtained which are softer and have a faded or worn look. It is also known to treat the fabric prior to the manufacturing of the garment, though commercially impractical. Fabrics have been subjected to mill washing with agitation, to remove starch. Brushing or sanding methods have been proposed to remove surface starch and surface dye but such methods have been considered to unduly weaken the fabric and are limited because they affect only the surface of the fabric.
  • jets of hot fluid such as hot air are directed at fabric having a thermoplastic surface to soften and sculpture the threads.
  • the known methods for treating fabrics have a number of disadvantages. Such methods are generally capable .of producing only a single speci ⁇ fic type of effect or modification of the fabric, or a very limited range of such effects.
  • the known techni ⁇ ques are usually useful only with respect to a limited class of fabrics. Installation of expensive equipment is required to carry out many such methods, and the equipment cannot be readily modified to produce any wide range of different types of effects on varying types of fabrics.
  • some of the methods as noted above tend to weaken or otherwise degrade the fabric to an unacceptable extent.
  • the present invention provides a method for modifying a wide variety of fabrics, for the purpose of achieving varied changes or effects in such fabrics.
  • Relatively simple equipment may be employed to achieve these effects, and the same equipment can be used to treat many different kinds of fabrics and to produce a great variety of effects by changing the operating con ⁇ ditions of the equipment rather than by any substan ⁇ tial modification or replacement of equipment as would be required in employing techniques of the prior art.
  • the present invention produces desired effects by projecting a stream of particles at a surface of the fabric to be treated, under controlled conditions of r ⁇ treatment.
  • the particles contact the surface at desired locations with a controlled force such that the physical appearance or feel of the fabric, or the physical characteristics of the fabric are modified.
  • the method is useful to provide an effect of softening or a soft-hand feel, a worn, or laundered appearance, the creation of designs, patterns,
  • the present invention provides a method for modifying fabrics to produce varied effects
  • a method for the treatment of fabrics to produce a softening (soft-hand) , worn or laundered effect which comprises projecting
  • a method for the treatment of fabrics to form designs, patterns, pictures or printing effects which comprises projecting under controlled conditions a stream of particles towards a surface of a fabric, the particles contacting said sur ⁇ face with a force effective to remove or partially re- move from said fabric one or more of dyes, pigments or portions of the fabric material.
  • a method for the treatment of fabrics to produce textured or sculptured effects which comprises projecting under controlled conditions a stream of particles towards a surface of a fabric, said particles contacting said surface with a force effective to remove or partially remove fabric material.
  • an apparatus for modifying fabrics to produce varied effects which com ⁇ prises means for supplying a length of fabric, said fabric having a first fabric surface and a second fabric surface, means for moving the fabric along a horizontal path in lengthwise direction, a first support backing positioned adjacent to said path, means for slidably pressing the second fabric surface against the first support backing, a first treating station located oppo ⁇ site from the first support backing, facing the first fabric surface and comprising means for propelling a stream of particles towards said first fabric surface, and means for removing treated fabric from said path.
  • FIG. 1 is a perspective view of apparatus usable in the process of the present invention and illustrates use of a rotary blaster for projecting a stream of particles at a supported fabric.
  • FIG. 2 is a plan view taken along the lines 2-2 of FIG. 1.
  • FIG. 3 is a schematic elevational view of apparatus useable in the process of the present invention and illustrates employment of a compressed air blasting system.
  • FIG. 4 is a schematic plan view of a fabric treatment line of the present invention and illustrating a continuous treatment ⁇ of fabric in accordance with the present method.
  • a stream of particles is directed towards a surface of a fabric.
  • the stream is in the form of a jet or blast of - particles which may be projected by any controllable means of propelling the particles. They may be pro ⁇ jected by entrainment in a fluid stream such as air or other gases or liquids such as water.
  • Air released from a compressed air source with the released stream of moving air carrying with it said particles mixed therein has been found to be an effective means of projecting the particles.
  • Commercially available sand blasting or air blaster equipment is useful.
  • the compressed air may be mixed in a tank with the desired particles and re ⁇ leased from a hose having a nozzle, or the compressed air may be released and the particles introduced into the resulting stream.
  • the hose may be hand-held par ⁇ ticularly for obtaining random design effects and may be contained in a cabinet, with manual or automated move ⁇ ment of the nozzle, the fabric or both, to bring the fabric into contact with the stream of particles. .
  • a suitable arrangement is shown in FIG. 3.
  • centrifugal or rotary blaster for projecting the stream of particles.
  • the technique and equipment for centri- fugal wheel blasting is well-known and readily available commercially.
  • particles are supplied to a rapidly rotating wheel and are thrown with force away from the rim of the wheel.
  • the particles may be applied to the rim surface of .a wheel.having a rim in- dentation or other structure which retains the particles until they have been accelerated and then thrown off the wheel.
  • the rotating wheel may be equipped with internal paddles or blades directed radially from the hub, and
  • FIGS. 1 and 2 illustrate use of a rotary blaster in the method of the present invention.
  • the particles After the particles contact the surface of the fabric, they are desirably collected and recycled to the supply source of particles, for reuse. Collection may be done simply by allowing the particles to fall by gravity into a collecting bin and conveying the col ⁇ lected particles to said source, or a stream of air may be used to convey the particles away from the fabric and into the collection system.
  • an effective force is one which is not so weak as to cause little or no effect on the fabric, and yet is not so strong as to cause an undesired significant weakening or degrading of the fabric.
  • Certain desired effects may involve the creation of designs or sculpturing in which considerable portions of the fabric material 'are removed, causing a weakening of the fabric in those areas, but this would be a desired result for such an effect.
  • the extent or nature of the force imparted to the particles will widely vary, depending upon the type of effect desired and the nature of the fabric under- going the treatment. The needed force can readily be determined by ordinary experimentation.
  • the extent or degree of-the effect desired would influence the choice of particles or the duration of the treatment of any particular area of the fabric.
  • Speci ⁇ fic conditions are not determinable in general, but must be adapted to the specific instances involving a par ⁇ ticular fabric and desired effect.
  • the type of particles and equipment will be chosen first. Then the conditions for establishing a stream of particles are readily determinable by simple experimentation. The essential aspect is to control the conditions of pro- jecting the stream of particles such that an effective particle force for the particles contacting the fabric is obtained.
  • the controlled conditions will be established by selecting the properties of size, shape, momentum and rate of flow of the particles.
  • the momen ⁇ tum of the particles will determine the extent of the -en ⁇ force of impact on the fabric surface. This force of course is determined by the mass and velocity of the particles. However, different types of particles of the same mass will have different sizes and shapes.
  • the momentum given to the particles also is influenced by the size, shape and rate of flow since the particles in motion will interact with the ambient atmosphere and will interact with each other such as by colliding. Therefore, the conditions of size, shape and rate of flow of particles will affect both the ultimate force of impact of the particles on the fabric and also will affect the intensity of the effect caused on the fabric. An abrasive particle will cause a more intense effect than a smooth particle.
  • the conditions which should be controlled also include the shape and size of the contact area of the particles on the fabric surface. At the same rate of flow of particles, dispersion over a large size area will cause a less intense effect than when concentrated on a small size area of the fabric surface.
  • the shape of the area is a condition which is closely related to the type of effect desired.
  • a contact area of any shape provided that it spans the fabric from one edge to an opposite edge of the fabric is preferred for an overall softening treatment of the entire surface of the fabric. Removal of dye or material of the fabric in a selected area to create a design re ⁇ quires an appropriate shape of contact area corres ⁇ ponding to the limited area to be treated.
  • a further condition of importance is control over the movement of the fabric relative to the stream of particles.
  • a piece of fabric or part of a garment may be introduced into a chamber and while stationary, subjected to a blast of a stream of par ⁇ ticles for a short time, such as 0.5 to 10 seconds. Upon cessation of the blast, the piece of fabric can be re oved and another piece brought into position for treatment.
  • there would be relative movement between the stream of particles and the fabric to provide detailed effects or effects over a long extent of the fabric particularly under conditions where a continuous length of fabric or a continuous series of pieces of fabric is being treated.
  • Either the stream of particles can be moved in relation to a stationary fabric length, or the length of fabric can be moved past a stream of particles eman ⁇ ating from a stationary source such that successive ' areas on the fabric are contacted by the stream of particles. Movement of the stream of particles relative to a stationary length of fabric would commonly be done in case of a hand-held source of particles for random or free-hand designs or other effects, or in the case where intricate designs are to be imparted to the fabric by an automated movement of the nozzle or other source of par ⁇ ticles. For most treatments, however, it has been found to be most effective to move the fabric past a stationary source of particles.
  • the controlled obtaining of such a variety of effects on a wide range of fabrics with a single type of equipment is an unparalleled achievement over known art and practices.
  • a combination of such effects can be obtained during the treatment of the fabric.
  • one treatment may achieve both softening and removal of dye for a worn appearance.
  • the fabric can be simultaneously or sequentially treated by two or more streams of particles or sequentially by the same stream in different locations or with different conditions.
  • th modification of fabrics can result in controlled fading, forming details or random designs, or patterns, or creating decorations, pictures, lace-like or embroidery ⁇ like effects, simulated leather effects such as graininess, sueding effects, napping, sculptured designs such as relief patterns, or printing effects such as decorations or names.
  • the latter can be done either by removal of dye or removal of material of the fabric.
  • the stencil can be a sheet " of impervious material having openings through which the particles can pass, or can be an impervious sheet without openings, such sheet being of a size or being positioned in the stream of particles such that the particles pass only around the outer perimeter of the sheet into contact with the -surface of the fabric.
  • a combination effect can be obtained with a stencil having openings wherein the particles pass through the openings and outside the perimeter of the stencil. Where particles pass through the openings in the stencil, the surface of the fabric is contacted by the particles in areas substantially corresponding to the areas of the openings in the stencil. The corres ⁇ pondence of areas will be affected by the distance of the stencil from the fabric surface.
  • a stencil allows the particles to contact the fabric surface in selected areas creating a pattern or design in contrast with adjacent areas which are not contacted. This enables a variety of effects such as the creation of pictures, designs, patterns, sculptured effects on pile fabrics or lace-like and embroidery-like effects. Further, the stencil enables printing-like effects such as the appearance of words or symbols.
  • the piece or length of fabric When contacted with the stream of particles, it is advantageous for the piece or length of fabric to be held under tension or positioned against a support surface.
  • the lengths or pieces of the fabric desirably are mounted on a support frame or support backing for bringing the fabric into and out of contact with the - stream of particles.
  • a support frame may allow part of the surface of the fabric which contacts the frame to be exposed, such that a simultaneous contacting of the re ⁇ verse side of the fabric with a stream of particles can be conducted while treating the front side of the fa ⁇ bric.
  • the continuous length is moved along a path, at a location in the path one surface of the sheet may be supported by pressing against a backing roll or plate and the surface of the sheet opposite to the supported surface may be brought into and out of contact with the stream of particles.
  • dust and adhered particles may be removed from the fabric after it has been contacted with the stream of particles.
  • the size and nature of the par ⁇ ticles and the type of treatment will determine whether any dust is created from the particles or the fabric, and whether any particles will adhere to the surface of the fabric or be embedded in the structure of it. De ⁇ pending upon these factors, it may be decided to employ a cleaning step after treatment with the particles.
  • This cleaning or removing of dust and adhered particles may be done mechanically by shaking or agitating the fabric or by blowing air or another gas or fluid onto the surface of the fabric or through the fabric. Ad ⁇ vantageously, the air is blown at the side of the fabric opposite to the side which was treated by the stream of particles.
  • a preferred cleaning technique is done by placing one side of the fabric under a vacuum and di ⁇ recting either continuous or pulsating streams of pres ⁇ surized air against the other side of the fabric. It is preferred to place the particle-treated side of the fa ⁇ bric under vacuum and direct jets or streams of air against the other side.
  • the fabric surface may be placed under vacuum in this embodiment by contacting the fabric surface with a semi-enclosed housing the areas of contact of the housing with the fabric being partially sealed by means of brushes or the like, and air being exhausted from the housing to create the vacuum.
  • a alternate technique is to remove adhered particles electrostatically.
  • the particles fre ⁇ quently will have an electrostatic charge resulting from the technique of projecting, or such charge can be im ⁇ parted to the particles.
  • an opposite electro ⁇ static charge is imparted to the fabric or to air which is blown onto or through the fabric.
  • the particles then will contact the fabric due to the momentum of said par ⁇ ticles, but will tend to be repelled after contact, be ⁇ cause of the differing electrostatic charge.
  • the charge can be applied to the fabric at a location after contact with the particles when the fabric has moved away from the stream of particles.
  • the cleaning step can take the form of removing any adhered particles from the fa- brie by magnetic attraction, such as by bringing a mag ⁇ netized surface adjacent to or in contact with the fa ⁇ bric surface after treatment.
  • said particles ' are grits, shot, balls, spheroidal, cylindri- cal, cut wire or crushed materials.
  • glass or plastics could be used in the form of uncrushed beads having a smooth shape, or could be crushed or shaped into cylinders, etc., to create a more abrasive par ⁇ ticle.
  • the preferred particle for use is aluminum oxide because of its availability, ⁇ ompatability with the equipment normally used, ability to be recycled and cap ⁇ ability for use in obtaining a wide variety of effects on the fabric.
  • the particle size may be selected based .on a combination of factors discussed above in order to ob ⁇ tain the desired conditions. It has been found effec ⁇ tive to utilize a blend of sand grit having mesh sizes 20, 30 and 50.
  • Aluminum oxide is effectively used in mesh size 80-100 but many other-sizes are useful. Shells are typically are crushed so that the particle size range is 0.01-0.13 inch.
  • the size of plastic particles typically is 0.03-0.06 inch.
  • Aluminum spher- roids may also be used (aluminum metal or alloy) the size of such particles typically being 0.0017-0.0937 inch.
  • Iron shot which is used may have a screen size of 7-120 (screen opening 2.80mm-0.125mm) . A typical size for grit such as iron grit is in a screen size of 7-200
  • any kind of fabric may be treated in accordance with the present invention.
  • the in ⁇ vention enables modification of any thin or thick, light or heavy, flexible material from any combination of cloth, fiber, polymeric film, sheet, foam or the like.
  • the fabric to be treated may be a textile or non- textile, it may be woven or non-woven, natural, man- made or synthetic, or it may be a blend of more than one such material.
  • the fabric to be treated can be useful in respect of many end-uses, particularly as a garment, upholstery, apparel, toweling, carpeting, curtain, bed- clothing or wall covering fabric.
  • Such fabrics in particular are in ⁇ cluded denim, cotton, silk, leather, suede, corduroy, velour, velvet, fur, wool, rayon, canvas, linen, and o synthetics such as polyester, nylon, and the like.
  • the treatment being effective to remove or partially re ⁇ move coatings, sizes, dyes or pigments, it is particu ⁇ larly preferred to direct such treatment towards denim' fabrics.
  • Denim is also a preferred fabric where the treatment is directed to form designs, patterns, pic- Q tures or printing effects such that the particles remove from the fabric or partially remove from it one or more of dyes, pigments or portions of the fabric material.
  • the preferred fabrics for treatment are pile, 07660 ' '
  • -18- napped, hooked, natural or man-made leather, natural or man-made fur, corduroy, velour or velvet fabrics are particularly preferred.
  • fabrics which are natural or man-made leather These may be treated to produce a suede effect and in connection with man-made leather the appearance may be enhanced by creating a grain or leather-like surface.
  • the texturing or sculpturing treatment is to produce an embroidery-like or lace-like effect, this can be done on a number of fa ⁇ brics, particularly denim, cotton, silk and synthetics.
  • the method of the present invention is effec ⁇ tive and can be applied at different stages of manufac- ture of the fabric or of articles made from the fabric.
  • the treatment can be applied to unfinished or greige goods, or to finished goods which for example have been subjected to dyeing and dry or wet finishing, or to finished coated or uncoated fabrics.
  • the effects of the invention can be obtained by application of the method to a garment or other article made from the fabric.
  • manufac ⁇ tured parts of such garments or articles can be sub ⁇ jected to the method.
  • pockets to be used as a part of a garment can be manufactured and the method can be employed to produce designs or names such as "decorator" names on such pockets.
  • fabric may be treated in accordance with the invention by being moved past a rotary blaster.
  • Fabric 1 is oun- ted by mounting means such as edge clamps (not shown) on vertical support 2. It is preferred to mount the fabric vertically.
  • rotary blaster 6 which includes a protective housing 7 and centrifugal wheel 8. Particles are supplied by hopper 10 to the wheel 8 where they are thrown off to form par ⁇ ticle stream 9 which contacts fabric 1.
  • Fabric 1 may be individual mounted pieces as shown or a length or con- tinuous length.
  • the particles are collected in a col ⁇ lector bin 11 and passed through a return duct 12 by means of conveyors such as screw conveyors and elevator systems as is known in the art, and such particles are returned to hopper 10.
  • the wheel 8 may be spun by a motor with appropriate controls, and the blaster 6 may be enclosed by a protective or dust housing and will have support and positioning elements, all of which are - not shown but are conventional in the art.
  • additional pieces or lengths of fabric 1 may be attached and treated by a second blaster 6' as may be seen in FIG. 2.
  • FIG. 3 An air blaster may be utilized, as illustrated in FIG. 3.
  • Fabric l is mounted on support 2 by mounting means (not shown) , with support 2 being in the form of a trolley having wheels 14.
  • Support 2 is moved on support rails 15 which extend into and out of protective cabinet 13.
  • a plurality of such trolleys each bearing a piece or length of fabric may be successively introduced to said cabinet through suitable sealing doors or flaps (not shown) .
  • Particles from hopper 10 are introduced through a pressure actuated valve 18 into pressure tank 17, pressurized by air from air supply duct 23 having valve 24.
  • the particles and compressed air enter mixing chamber 19 and are conveyed by pressure of said air through duct 20 and valve 21 into nozzle 22 where the compressed air and particles are released forming a stream of particles 9 which contacts fabric 1.
  • the par ⁇ ticles which have contacted fabric 1 are directed down- wardly by the flow of air into particle collector 11.
  • the collected particles in collector 11 are returned to hopper 10 through return duct 12 by means of screw conveyors and elevators (not shown) .
  • a fabric supply 29 may be from a roll or other supply of fabric.
  • Fabric 1 is moved along a horizontal path following a treatment line in the di- rection shown by arrows, and by means of roll 31 and rollers 34 is pressed against a support backing in the form of support plate 33.
  • the plate is preferably flat but can be arcuate or can be replaced by a backing roll of large radius.
  • a first treating station 30 is located.
  • the treating station employs blaster 32 which includes housing 7, rotary • wheel 8 and particle collector 11, all being as illus ⁇ trated in FIG.
  • the fabric is cleaned by cleaner 35 which in ⁇ cludes vacuum chamber 36, and air jets 37 supplied by air duct 38.
  • the fabric then is moved to a second treating station 40 where it is pressed against another support plate 33 by means of rollers 34 and "is treated by blaster 32' having the same components as described in respect of first station 30.
  • blaster 32' is positioned to treat the side of the fabric opposite to the side treated at first treating station 30.
  • the second treating station may be omitted along with its subsequent cleaner 35 of the same construction as described previously.
  • second treating station 40 may be positioned to treat the same surface of the fabric as was treated at first treating station 30, with the purpose of employing different treatment conditions for a different effect on the fabric.
  • first treating station 30 may pro ⁇ vide an effect of laundering appearance, while second treating station 40 may be used to impart a design to the fabric.
  • the treated fabric 1 is moved away from the treatment station by suitable means such as roll 39 and is collected at take-up roll 41 or is directed further to other processing units. As is readily apparent. Further treating stations may be introduced into the line.
  • sample A to F Six denim fabric samples identified as A to F were treated in accordance with the method of the pre ⁇ sent invention. The samples were all approximately six feet long and made of 100% cotton woven denim. These samples were of different fabric weights, samples E and F being light weight fabrics and A to D of a heavier weight. The fabrics also were of a differing stage of manufacture. Samples A, B, C and F were of a finished fabric, that is, dyed goods ready for manufacturing into garments. Samples D and E were greige goods, that is, goods as obtained from the loom prior to being subjected to the finishing procedure.
  • the tensile strength, tear strength and fabric weight of each sample was measured before treatment and after treatment. Measurement of the tensile strength was in accordance with ASTM Standard Test Method D1682- 64 (Reapproved 1975) . In this test a fabric specimen is gripped by opposed jaws of 1 inch width. A continually increasing load is applied longitudinally to the specimen, and the test is carried to rupture in a . specific time. Values for the breaking load of the test specimen are obtained from machine scales reading in pounds, so that the test result is expressed is lbs/in width of specimen. The tear resistance of the samples was determined by a test in accordance with ASTM Standard Test Method D 1424-83.
  • the average force required to continue a tongue- type tear in a fabric is determined by measuring the work done in tearing it through a fixed distance.
  • the tester consists of a sector-shaped pendulum carrying a clamp which is in alignment with a fixed clamp when the pendulum is in the raised, starting position with maximum potential energy.
  • the specimen is fastened in the clamps and the tear is started by a slit cut in the specimen between the clamps.
  • the pendulum is then . released and the specimen is torn as the moving jaw moves away from the fixed one.
  • the scale attached to the pendulum is graduated so as to read directly the tearing force in pounds.
  • Each sample was prepared for treatment by mounting the sample of fabric on a metal support plate having a rubber layer, the fabric contacting the rubber layer and being clamped under tension at the edges of the support plate.
  • the support structure was mounted vertically on a cart and the face of the fabric was passed in front of a stationary blaster apparatus having two rotary wheels each throwing a stream of particles at the surface of the fabric being moved across the path of said streams, such that a blast pattern of equal density of particles was applied in an elongated area extending from the bottom edge to the top edge of the mounted fa- brie surface.
  • the blaster was a "WHEELABRATOR” (Registered Trade Mark) blaster made by Wheelabrator-Frye Inc., 400 South Byrkit Ave., Mishawaka, Indiana.
  • The- particles were assorted steel shot of mixed size about 80 mesh-16 mesh. Dis ⁇ tance from outlet of the wheels to the fabric surface was about 5 feet and the fabric was moved past the front of the blaster at a rate of about 4 yards of fabric length per minute of passage time.
  • Sample A was treated by one pass on both sides, meaning that the treatment was done on one entire side and then the fabric sample was reversed on the support and the same treatment was applied to the thus-exposed reversed side of the fabric.
  • Sample B was treated by a first passage treating the exposed surface and by repeating this treatment on the same exposed side, so that as a result one side of the fabric sample was subjected to two passes.
  • Each of samples C, D, E and F were subjected to a single treatment passage, only one side being treated.
  • the treatment conditions and test results are shown in the following Table. It can be seen from the test results that as a result of the treatment, the fabric weight generally decreased somewhat, with multiple passes causing a proportionally larger decrease than in the case of single. passes.
  • the tensile strength of the treated specimens decreased as compared with the specimens prior to treatment, but the decrease was within acceptable levels such that the treated fabrics were all of a satisfactory strength for manufacturing into garments. It is surprising that the tear resistance of the treated samples was improved over the un ⁇ treated fabric (the force required to tear the fabric was greater after treatment) , for most of the samples and frequently in both of the test directions. Each test was done both in the warped (W) direction and in the filling (F) direction. That is, the warp- yarns or the filling yarns were respectively subjected to tension for the tensile test and subjected to tearing for the tear test.
  • the fabric sample was observed to become softer to the touch and feel, and changed from the loom state (dark blue color) to a faded or lighter color.
  • Another piece of denim fabric corresponding to sample A of Example 1 is treated with the same procedure as in Example 1 except that the blaster apparatus in- eludes only a single wheel and is adjusted to form a stream of particles impinging on a more limited area near the surface of the fabric.
  • the fabric is sup ⁇ ported with its length in the horizontal direction of movement of the fabric and its width positioned verti- cally.
  • the particle stream forms an area of about 0.5 foot wide by about 1 foot high near the fabric surface.
  • a stencil comprising a 1/4 inch steel plate 4 feet wide by 5 feet high is interposed between the fabric and the blaster, at a distance of 0.5 inch from the fabric.
  • the stencil is solid except for a central area corresponding to the area of impingement of the stream of particles, in which is located three 1 inch high by 0.5 inch wide rectangular openings, one above the other, spaced 2 inches from each other.
  • the fabric is moved past the blaster during the treatment and a design consisting of a series of three horizontal faded stripes running the length of the fabric is obtained.
  • Example 1 is treated in an apparatus in accordance with FIG. 4 of the drawings except that the apparatus comprises a single treating station including a blaster apparatus as defined in Example 1 followed by a vacuum and air jet cleaner.
  • the treatment conditions are the same as in Example 1.
  • a softened, faded treated fabric is continuously obtained.
  • EXAMPLE 4 A piece of denim fabric corresponding to sample A of Example 1 is treated as in Example 1 except that a single wheel is used with aluminum oxide grit particles of 80-100 mesh size. By positioning the wheel closer to the fabric and adjusting conditions, the blast pattern is confined on the surface of the fabric to an area of about 12 inches high by 2 inches wide. Upon treating the fabric, there is obtained a design con- sisting of a faded stripe running horizontally along the length of the piece of fabric.
  • Example 5 The treatment of Example 1 is repeated, how ⁇ ever using plastic particles consisting of extruded plastic cut to cylindrical shape of a size being 0.03 inch length and 0.03 inch diameter. Upon treatment, a softened, faded denim fabric, is obtained.
  • a natural leather fabric suitable for making leather jackets is treated in accordance with the conditions of Example 1 except that the particles used are aluminum oxide, the distance between the blaster wheel and fabric surface is decreased, and the rota ⁇ tional speed of the wheels is increased. A suede tex ⁇ ture effect is obtained on the treated leather.
  • EXAMPLE 8 A heavy weight cotton pile toweling fabric is substituted for the denim fabric of Example 2 and treated as in Example 2 but with closer positioning of the blaster wheel to the stencil surface. A sculp ⁇ tured pattern of depressed areas corresponding to the position of the openings in the stencil is obtained, the depressed areas being in the form of stripes running horizontally the length of the fabric. EXAMPLE 9
  • a commercially available sand blaster was em ⁇ ployed to create a stream of released compressed air containing accelerated particles of aluminum oxide grit of 80-100 mesh, this stream being projected from a hand ⁇ held nozzle.
  • Denim fabric pieces of a type corres ⁇ ponding to sample A of Example 1 were mounted against a wooden support plate by edge clamping, the fabric being flattened by the clamping tension. .
  • the nozzle was held at varying distances from the fabric from 6 to 18 inches, and both the fabric and nozzle were contained in a blast cabinet. By traversing the nozzle across the stationary fabric, a random design pattern of faded areas was obtained on the surface of the fabric.
  • the resulting fabric sample having a random design was found to be of a physical quality suitable for manufacture into garments.
  • EXAMPLE 10 The procedure of Example 9 was repeated, but there was interposed between the fabric surface and the stream of particles a stencil having openings corres ⁇ ponding to the outline of city buildings. A design was obtained on the fabric consisting of a picture of city buildings. EXAMPLE 11
  • Example 9 The procedure of Example 9 was repeated but a stencil was interposed between the fabric surface and the stream of particles.
  • the stencil had openings cor ⁇ responding to a lace-like pattern.
  • the stencil was smaller in size than the area of impingement of said stream of particles with the surface of the fabric.
  • There was obtained a design pattern on the surface of the fabric consisting of a shape in the form of the shape of the stencil. Within the design pattern there was formed faded areas corresponding to openings in the stencil, giving a lace-like effect. Areas corresponding to solid portions of the stencil remained dark blue in 07660 ' '
  • EXAMPLE 12 The procedure of Example 10 is repeated, but with use of a stencil positioned very closely to the surface of the fabric and having openings in the form of letters, arranged as words. • There is obtained a design consisting of faded portions on the fabric surface in the shape of letters corresponding to the openings in the stencil.

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  • Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Materials Engineering (AREA)
  • Textile Engineering (AREA)
  • Treatment Of Fiber Materials (AREA)
  • Chemical Or Physical Treatment Of Fibers (AREA)
  • Treatments For Attaching Organic Compounds To Fibrous Goods (AREA)
  • Synthetic Leather, Interior Materials Or Flexible Sheet Materials (AREA)
PCT/US1987/001394 1986-06-09 1987-06-08 Method and apparatus for modifying fabrics to produce varied effects WO1987007660A1 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
IN25/DEL/87A IN168612B (enrdf_load_stackoverflow) 1986-06-09 1987-01-14

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
US87218586A 1986-06-09 1986-06-09
US872,185 1986-06-09

Publications (1)

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WO1987007660A1 true WO1987007660A1 (en) 1987-12-17

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Country Status (5)

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EP (1) EP0252317A3 (enrdf_load_stackoverflow)
JP (1) JPS6375170A (enrdf_load_stackoverflow)
AU (1) AU7583587A (enrdf_load_stackoverflow)
IN (1) IN168612B (enrdf_load_stackoverflow)
WO (1) WO1987007660A1 (enrdf_load_stackoverflow)

Cited By (1)

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EP0303120A1 (en) * 1987-07-31 1989-02-15 Golden Trade S.R.L. Method and apparatus for producing a faded effect on fabric garments

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DD264112A3 (de) * 1987-05-13 1989-01-25 Greika Web U Veredlg Veb Vorrichtung zur herstellung matter und rauher flaechen- oder bandfoermiger polymerer erzeugnisse
US4832864A (en) * 1987-09-15 1989-05-23 Ecolab Inc. Compositions and methods that introduce variations in color density into cellulosic fabrics, particularly indigo dyed denim
JP2540052B2 (ja) * 1987-09-30 1996-10-02 博文 ▲高▼田 布の表面漂白方法
JPH01291922A (ja) * 1988-05-10 1989-11-24 Veb Greika Greiz Weberei & Veredlung 無光択でかつ粗いシート状の、帯状の或いは糸状のポリマー製品を造るための方法
IT1225774B (it) * 1988-07-13 1990-11-27 Giorgio Viada Trattamento di martellinatura della superficie dei tessuti e macchina martellinatrice a lancio di graniglia per mezzo di turbina centifruga
JP2931825B2 (ja) * 1988-08-02 1999-08-09 博文 ▲高▼田 布への抜染プリント方法
US4997450A (en) * 1989-03-10 1991-03-05 Ecolab Inc. Decolorizing dyed fabric or garments
US5268002A (en) * 1989-03-10 1993-12-07 Ecolab Inc. Decolorizing dyed fabric or garments
JPH04146256A (ja) * 1990-10-05 1992-05-20 Sintokogio Ltd 染色布地の軟化処理方法
DE19906263A1 (de) * 1999-02-15 2000-08-17 Brueckner Apparatebau Gmbh Verfahren und Vorrichtung zur Oberflächenbehandlung einer Textilbahn
DE19955660C1 (de) * 1999-11-19 2001-03-22 Messer Griesheim Gmbh Verfahren und Vorrichtung zur Behandlung der Oberfläche von Textilien
ITBO20110565A1 (it) * 2011-10-05 2013-04-06 Sabatino Rosselli Metodo di sabbiatura su pelle lucida e prodotto ottenuto
CN110756363B (zh) * 2019-11-08 2020-08-28 南京溧水高新创业投资管理有限公司 一种雕刻用上色装置

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US2277937A (en) * 1941-05-09 1942-03-31 George C Shryer Method of producing bas-relief on pile fabrics
GB649979A (en) * 1947-12-17 1951-02-07 Edmund Fritchaf Struckman Improvements in and relating to a method and apparatus for the treatment of textile fabrics
GB817184A (en) * 1955-12-08 1959-07-29 Tru Scale Inc Apparatus for abrasively surfacing continuous webs
US2993309A (en) * 1956-04-26 1961-07-25 Bell Intercontinental Corp Machine for the surface treatment of thin plastic films
US3523346A (en) * 1967-12-07 1970-08-11 Canton Textile Mills Method for modifying the surface texturing of fabrics
US3553801A (en) * 1968-02-19 1971-01-12 Hadley Co Inc Fabric treating apparatus
US3872557A (en) * 1972-06-12 1975-03-25 Benzaquen Sa Ind Process for conditioning superficially dyed fabrics

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US3911281A (en) * 1974-02-12 1975-10-07 Cottbus Textilkombinat Arrangement for selectively irradiating webs
IT1051529B (it) * 1975-12-19 1981-05-20 Cartabbia Giovanni Procedimento atto a conferire ai pantaloni in tessuto jean caratteristiche di indossabilita ed un particolare aspetto di scoloritura e di usura ed impianto atto a concretizzare tale procedimento

Patent Citations (8)

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Publication number Priority date Publication date Assignee Title
US930522A (en) * 1908-02-24 1909-08-10 Max L Weiss Process of renovating apparel.
US2277937A (en) * 1941-05-09 1942-03-31 George C Shryer Method of producing bas-relief on pile fabrics
GB649979A (en) * 1947-12-17 1951-02-07 Edmund Fritchaf Struckman Improvements in and relating to a method and apparatus for the treatment of textile fabrics
GB817184A (en) * 1955-12-08 1959-07-29 Tru Scale Inc Apparatus for abrasively surfacing continuous webs
US2993309A (en) * 1956-04-26 1961-07-25 Bell Intercontinental Corp Machine for the surface treatment of thin plastic films
US3523346A (en) * 1967-12-07 1970-08-11 Canton Textile Mills Method for modifying the surface texturing of fabrics
US3553801A (en) * 1968-02-19 1971-01-12 Hadley Co Inc Fabric treating apparatus
US3872557A (en) * 1972-06-12 1975-03-25 Benzaquen Sa Ind Process for conditioning superficially dyed fabrics

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP0303120A1 (en) * 1987-07-31 1989-02-15 Golden Trade S.R.L. Method and apparatus for producing a faded effect on fabric garments

Also Published As

Publication number Publication date
EP0252317A3 (en) 1989-02-08
AU7583587A (en) 1988-01-11
IN168612B (enrdf_load_stackoverflow) 1991-05-04
JPS6375170A (ja) 1988-04-05
EP0252317A2 (en) 1988-01-13

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