• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    A bonded web of nonwoven fibers is stretched beyond its elastic limit in one direction sufficiently to permanently elongate those filaments or filament portions of the web extending generally in the direction of the applied tension. This results in a narrowing or necking down of the web in the cross direction and consequent shortening or lateral buckling of those filaments or filament portions extending generally transverse to the direction of applied tension. This imparts increased softness, flexibility and resilient stretchability to the fabric, in that transverse direction. The elongated filaments are then compacted longitudinally while the web is retained in its narrowed condition to impart increased softness, flexibility and resilient stretchability in the longitudinal direction.
    公开号:SU731907A3
    申请号:SU772505355
    申请日:1977-07-22
    公开日:1980-04-30
    发明作者:Джон Грум Эрнест
    申请人:Клупак Инк (Фирма);
    IPC主号:
    专利说明:

    roller 8 and from roller 9 is again directed to pressure roller 6.
    The canvas 1 is compacted by pressing the belt 5 against the cylinder 4.
    During compaction, essentially all longitudinally directed fibers are micro-compressed, as a result of which they are bent inside the web.
    The pressure roller 6 and the cylinder 4 rotate at such a rate that the canvas 1 is guided at a faster speed than the feed speed of the canvas 1 by the feed rollers 2. This ensures a constant elongation of those canvas fibers that are directed in the longitudinal direction.
    At the same time, the width of the canvas is reduced (as shown in Fig. 1), with the result that the side bending of the fibers takes place. In other words, the fibers directed in the necrodal direction are elongated in the feed direction, orient themselves in the nodal direction and are compressed in the transverse direction, with parts of the fibers moving in the direction of the center of the canvas, causing the side fibers to bend or twist and thus reduce the width of the canvas. The compaction of the canvas 1 also takes place during the displacement of the canvas between the tape 5 and the cylinder 4.
    According to FIG. 3 and 4, the canvas 1 is passed between the feed rollers 2 and then between the pressure rollers 10, which rotate at a higher speed than the rollers 2. In this case, the canvas 1 is permanently elongated, causing the width of the canvas to decrease and the lateral fibers to bend.
    After passing between the pressure rollers 10, canvas 1 relieves all stresses in the longitudinal direction and the canvas 1 again expands slightly. But the width of the canvas 1 is still less than before lengthening. Then the canvas 1 is fed to the collecting device 11 and from there it moves along the roller 12 and is guided into the gap between the belt 5 and the cylinder 4 of the sealing device 7.
    After the web 1 is compacted in the longitudinal direction, a non-woven material of the same quality as the non-woven material obtained by processing in FIG. 1 and 2.
    The elongation of the material that is performed prior to compaction is carried out until the desired reduction in the width of the canvas is achieved.
    An elongation of the order of 10-30% leads to a decrease in the compressive modulus of the material by about 35%, resulting in a compaction. As already indicated, the web 1 is first elongated in the longitudinal direction and then compacted to a length that is approximately equal to the web length to the elongation.
    During compaction in the longitudinal direction, the web 1 is prevented from expanding to its original transverse size due to the fact that the web 1 is arranged between the belt 5 and the cylindrical 4. The fibers, which are directed in the longitudinal direction, wilt, and the fibers that are directed in the transverse direction, constantly bending.
    The nonwoven fabric thus obtained has a significantly improved softness and can be extended in both directions, and its elongation ability in transverse direction is sufficient to again obtain the original width of the canvas.
    When using certain nonwoven materials, it is advisable to add a small amount of moisture before processing, which favorably affects the complete bending of the fibers. In addition, the fiber flexing process is accelerated. Materials that can be treated with the addition of moisture contain hydrophilic fibers and / or binders. The addition of moisture to these materials contributes to the formation of a more elastic and more capable of deforming bond, due to which it is possible to achieve greater elongation in
    the longitudinal direction and, therefore, a greater reduction in width without tearing the canvas.
    The optimum amount of moisture added to the material depends on the type of fibers.
    and the binder used. It can be determined simply by experiment.
    The moisture content is typically 15-25% by weight of the canvas.
    When processing a material consisting of viscose fibers bound by an acrylic binder, it is possible to lengthen the air-dried material by about 8%. After the addition of 12% moisture (total
    moisture content 19%) width reduction is 2%.
    With this reduction in width, it is 12% and the treated canvas has significantly improved properties.
    In addition, carrying out elongation at higher temperatures favorably affects the results of processing such materials that contain thermoplastic fibers and / or binders.
    When using such materials, it is believed that the heat causes the same effect as adding moisture to the canvas containing hydrophilic fibers and / or binders.
    Example 1. The following spinning polyester materials are used.
    A. Standard material of branched fibers weighing 5.9 kg / 278 m.
    B. Material A, but weighing 19.5 kg / 278 m.
    B. The material of the crimped fibers.
    D. A material in which the denier of the fibers is irimerically 2.9 or 5.5 in the specified materials. Weight: 9.5 kg / 278 m.
    Each material is treated under various conditions, i.e., consolidation using tapes with a Shore hardness of 50 n 60 and elongation with the next compaction using a tape with a Shore hardness of 50 and in some cases also using a tape with a Shore 60 hardness.
    Elongation and compaction are carried out under the following conditions.
    U d l i n n
    The elongation is carried out in such a way that the canvas is subjected to a 12-15% reduction in width in terms of feed to compaction. This requires a difference in speed of approximately 20-25%.
    Compaction.
    Regardless of whether the elongation is carried out by compaction, the following conditions are followed;
    Degree of compaction 15%
    Chi 60 temperature (higher lindra, ° C temperature adversely affects softness) Of Teflon
    Cylinder surface
    27.21-2.54
    Pathe ribbon, kg / cm Air drying
    Canvas moisture content
    The results of the experiments are summarized in table 1.
    Note.
    From tab. 1, it can be seen that the proposed method can significantly reduce the rigidity, not only in the longitudinal, but also in the non-axial direction. In addition, the tensile strength increases significantly in the longitudinal direction.
    .
    Example 2. Analogously to example 1, a material consisting of nylon fibers 2.54 cm long and viscose fibers 1.27 cm long connected
    thermoplastic binder; Seal 50-tape with a hardness of 50 shore; 60-penta sealer hardness of 60; elongation + compaction-elongation followed by compaction m; PRN- in the longitudinal direction; Mon-in the transverse direction.
    78
    The results of the experiments are given in table 2. Note.
    Example 3. Analogously to Example 1, a material consisting of viscose fibers 1.27-2.54 cm in length, bound by a thermoplastic binder, is treated. With
    权利要求:
    Claims (5)
    [1]
    1. A method of treating a nonwoven material in which the material is stretched in the longitudinal direction, characterized in that, in order to improve the quality, the stress applied when the material is stretched exceeds the elastic limit of the fibers of the material.
    [2]
    2. A method according to claim 1, characterized in that after stretching the material is compacted in the longitudinal direction.
    [3]
    3. Method according to paragraphs. I and 2, distinguishing 731907
    This elongation and compaction is carried out at a temperature of 82 ° C.
    The results of the experiments are shown in table 3.
    due to the fact that the material is stretched to its elongation by 15-25%.
    [4]
    4. The way he is. 1-3, characterized in that after stretching the material, the stress is relieved.
    [5]
    5. The method according to paragraphs. 1-4, characterized in that the tensile stress corresponds to the value of the subsequent compaction.
    Information sources,
    taken into account in the examination
    1. US Patent No. 3554854, cl. 161-150, 1970.
    2. Patent of the GDR № 39589, cl. 8h, 8, 1965. In order to lengthen the moisture content of the material should be increased to 18%. In this case, the material can be lengthened without breaking. Before compaction, the material is dried to a moisture content of about 10%.
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    同族专利:
    公开号 | 公开日
    NL7707045A|1978-01-31|
    BR7704164A|1978-03-21|
    IT1079373B|1985-05-08|
    FR2359923A1|1978-02-24|
    FR2359923B1|1981-12-24|
    NL182419C|1988-03-01|
    GB1540176A|1979-02-07|
    JPS5314875A|1978-02-09|
    JPS6211106B2|1987-03-10|
    NL182419B|1987-10-01|
    CA1055238A|1979-05-29|
    DE2729949C2|1988-09-22|
    US4088731A|1978-05-09|
    DE2729949A1|1978-02-02|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    BE516549A|1952-06-11|
    US3515633A|1953-04-03|1970-06-02|Clupak Inc|Compacting of paper and similar fiber webs|
    US3047444A|1955-07-15|1962-07-31|Kimberly Clark Co|Non-woven fabric and method of making the same|
    NL286039A|1961-12-19|
    GB1100908A|1964-07-28|1968-01-24|Clupak Inc|Process and apparatus for producing an extensible web material|
    US3525787A|1966-09-26|1970-08-25|Du Pont|Process for producing low permanent shrinkage cellophane|
    US3427376A|1966-09-27|1969-02-11|Du Pont|Softening nonwoven fabrics|
    US3772417A|1970-10-28|1973-11-13|C Vogt|Method for improving physical properties of spray spun fibrous sheet materials|JPS641581B2|1983-12-14|1989-01-12|Kao Corp|
    CA1283764C|1986-09-29|1991-05-07|Mitsui Chemicals Inc.|Very soft polyolefin spunbonded nonwoven fabric and its production method|
    JP2587461B2|1988-06-24|1997-03-05|三井石油化学工業株式会社|Nonwoven fabric manufacturing method|
    EP0695383B1|1993-03-26|2001-10-31|The University Of Tennessee Research Corporation|Post-treatment of nonwoven webs|
    US5441550A|1992-03-26|1995-08-15|The University Of Tennessee Research Corporation|Post-treatment of laminated nonwoven cellulosic fiber webs|
    USRE35206E|1992-03-26|1996-04-16|The University Of Tennessee Research Corporation|Post-treatment of nonwoven webs|
    US5443606A|1992-03-26|1995-08-22|The University Of Tennessee Reserch Corporation|Post-treatment of laminated nonwoven cellulosic fiber webs|
    US5486411A|1992-03-26|1996-01-23|The University Of Tennessee Research Corporation|Electrically charged, consolidated non-woven webs|
    US5531235A|1992-09-28|1996-07-02|Hassenboehler, Jr.; Charles B.|Cigarette filter micropleated web and method of manufacture|
    US5686050A|1992-10-09|1997-11-11|The University Of Tennessee Research Corporation|Method and apparatus for the electrostatic charging of a web or film|
    US5955174A|1995-03-28|1999-09-21|The University Of Tennessee Research Corporation|Composite of pleated and nonwoven webs|
    US5592357A|1992-10-09|1997-01-07|The University Of Tennessee Research Corp.|Electrostatic charging apparatus and method|
    US5413811A|1994-03-18|1995-05-09|Kimberly-Clark Corporation|Chemical and mechanical softening process for nonwoven web|
    WO1997013266A2|1995-06-19|1997-04-10|The University Of Tennessee Research Corporation|Discharge methods and electrodes for generating plasmas at one atmosphere of pressure, and materials treated therewith|
    US5704102A|1995-06-26|1998-01-06|Catallo; Frank|Apparatus for finishing a fabric web|
    US5814390A|1995-06-30|1998-09-29|Kimberly-Clark Worldwide, Inc.|Creased nonwoven web with stretch and recovery|
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    US5770531A|1996-04-29|1998-06-23|Kimberly--Clark Worldwide, Inc.|Mechanical and internal softening for nonwoven web|
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    US20040102125A1|2002-11-27|2004-05-27|Morman Michael Tod|Extensible laminate of nonwoven and elastomeric materials and process for making the same|
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    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    US05/709,543|US4088731A|1976-07-28|1976-07-28|Method of softening nonwoven fabrics|
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