Patent Application
20250137177
The present application relates to the technical field of knitting machinery, specifically to a yarn holder with movable yarn nozzle, texture structure, fabric, Flyknit fabric, and weaving process.
Flat knitting machines are used for knitting items such as gloves and socks. During operation, they often require the use of yarn nozzles for yarn guiding. Currently, during the knitting process, the yarn holder slides on the guide rail, often resulting in instability and vibration. These phenomena can easily cause wear and tear on the corresponding components. The layout of the yarn nozzle on the yarn holder also affects knitting efficiency and quality, which in turn determines the economic benefits of the knitting factory.
At present, adding warp yarn weaving to Flyknit fabric not only reduces the warp direction extension performance of the Flyknit fabric but also serves to decorate the Flyknit fabric. Therefore, this type of Flyknit fabric product is favored by consumers. However, in commonly used Flyknit equipment, most are ‘16 yarn nozzles’. Due to the limitations of Flyknit equipment performance, the number of ‘warp yarns’ involved in Flyknit fabric weaving is relatively small, and frequent avoidance of yarn nozzles is required, resulting in particularly long production times and relatively monotonous warp direction texture structures.
Based on this, the inventors conducted research and proposed this case.
Other features and advantages of the present application will be set forth in the following description, and in part will become apparent from the description, or may be learned by practice of the application. The objectives and other advantages of the present application can be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings.
The objective of the present application is to overcome the above-mentioned deficiencies and provide a yarn holder with movable yarn nozzle, texture structure, fabric, Flyknit fabric, and their weaving process.
In a first aspect, the present application provides a yarn holder with movable yarn nozzle, comprising a yarn holder and several yarn nozzles, wherein the yarn nozzle comprises a movable yarn nozzle. The yarn holder is provided with a first adjustment mechanism for controlling and adjusting the position and direction of the yarn holder. The position and direction of the movable yarn nozzle on the yarn holder are adjusted by a second adjustment mechanism. At least one movable yarn nozzle is provided on the yarn holder. The first adjustment mechanism is configured to cooperate with the second adjustment mechanism cooperate to control the movable yarn nozzle on the yarn holder to move from an initial position to a weaving position. The first adjustment mechanism and the second adjustment mechanism each control displacement in at least one direction. The first adjustment mechanism controls the entire yarn holder (comprising structures on the yarn holder, such as the movable yarn nozzle and the second adjustment mechanism that adjusts the movable yarn nozzle). The second adjustment mechanism and the first adjustment mechanism are independent of each other in control and do not interfere with each other. The second adjustment mechanism can control the adjustment of the movable yarn nozzle while the first adjustment mechanism controls the overall displacement of the yarn holder, thereby finally adjusting the movable yarn nozzle from an initial position to a weaving position.
The present application plans the layout structure of the yarn nozzle on the yarn holder, enabling the weaving equipment to perform more weaving actions when controlling the yarn holder to move for weaving, thereby indirectly improving weaving efficiency.
In some embodiments, the yarn holder is adjusted integrally by the first adjustment mechanism, and the movable yarn nozzle is adjusted to move up and down on the yarn holder by the second adjustment mechanism.
In some embodiments, is adjusted to move left and right, back and forth integrally by the first adjustment mechanism, and the movable yarn nozzle is adjusted to move up and down on the yarn holder by the second adjustment mechanism.
In some embodiments, is adjusted to move left and right, up and down integrally by the first adjustment mechanism, and the movable yarn nozzle is adjusted to move back and forth on the yarn holder by the second adjustment mechanism.
In some embodiments, the movable yarn nozzle is adjusted by the second adjustment mechanism to move left and right on the yarn holder, and the yarn holder is adjusted by the first adjustment mechanism to move up and down or/and back and forth integrally.
In some embodiments, the movable yarn nozzle is adjusted by the second adjustment mechanism to move left and right, back and forth on the yarn holder, and the yarn holder is adjusted by the first adjustment mechanism to move up and down integrally.
In some embodiments, the movable yarn nozzle is adjusted by the second adjustment mechanism to move left and right, up and down on the yarn holder, and the yarn holder is adjusted by the first adjustment mechanism to move back and forth integrally.
In some embodiments, the yarn holder is adjusted by the first adjustment mechanism to move up and down integrally, and the movable yarn nozzle is adjusted to move back and forth on the yarn holder by the second adjustment mechanism.
In some embodiments, the movable yarn nozzle is adjusted by the second adjustment mechanism to move up and down on the yarn holder, and the yarn holder is adjusted to move back and forth on the yarn holder by the first adjustment mechanism.
In a second aspect, the present application provides another yarn holder with movable yarn nozzle, comprising a yarn holder and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle. The yarn holder is provided with a first adjustment mechanism for controlling and adjusting the position direction of the yarn holder. At least one movable yarn nozzle is arranged on the yarn holder. The integral position of the yarn holder is adjusted by the first adjustment mechanism so that it is adjusted from an initial position to a weaving position, and the yarn holder is adjusted in at least one direction integrally. The yarn nozzle can be a fixed yarn nozzle or a movable yarn nozzle. As long as it is a yarn nozzle on the yarn holder, it can be moved from an initial position to a weaving position by controlling the overall displacement of the yarn holder.
In some embodiments, the yarn holder is adjusted to move left and right, or up and down, or back and forth by the first adjustment mechanism.
In some embodiments, the yarn holder is adjusted to move left and right integrally by the first adjustment mechanism, and the yarn holder is adjusted to move up and down or/and back and forth integrally by the first adjustment mechanism.
In some embodiments, the yarn holder is adjusted to move up and down, and back and forth integrally by the first adjustment mechanism.
In a third aspect, the present application also provides another type of yarn holder with movable yarn nozzle, comprising a yarn holder and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle, and the position and direction of the movable yarn nozzle on the yarn holder is adjusted by a second adjustment mechanism. The movable yarn nozzle is controlled by the second adjustment mechanism to move from an initial position to a weaving position in at least one direction. At least one movable yarn nozzle is arranged on the yarn holder.
In some embodiments, the movable yarn nozzle is adjusted by the second adjustment mechanism to move left and right, up and down, or back and forth on the yarn holder.
In some embodiments, the movable yarn nozzle is adjusted by the second adjustment mechanism to move left and right on the yarn holder, and the movable yarn nozzle is adjusted by the second adjustment mechanism to move up and down and/or back and forth on the yarn holder.
In some embodiments, the movable yarn nozzle is adjusted by the second adjustment mechanism to move up and down, back and forth on the yarn holder.
In some embodiments, several yarn nozzles are arranged and distributed in different layers.
In some embodiments, the movable yarn nozzle is rotatable.
In some embodiments, the movable yarn nozzle does not move and constitutes a fixed yarn nozzle.
In some embodiments, the movable yarn nozzle is adjusted to swing back and forth on the yarn holder by a third adjustment mechanism.
In some embodiments, the movable yarn nozzle swings back and forth by the third adjustment mechanism in conjunction with an swinging pivot, which is located on the yarn holder or the movable yarn nozzle.
In some embodiments, the yarn nozzle is provided with several independent yarn outlets, the spacing between adjacent yarn outlets is adjustable, the height of the independent yarn outlets is adjustable, and the size of the independent yarn outlets is adjustable. These can be arranged on either the fixed yarn nozzle or the movable yarn nozzle.
In a fourth aspect, the present application provides a texture structure, which is woven by the movable yarn nozzle in the yarn holder with movable yarn nozzle described above. The texture structure comprises multiple threads, and any angle can be formed between two adjacent threads.
In some embodiments, the angle comprises a first angle, and the first angle is 90° or 180°. The present application utilizes a movable yarn nozzle to weave on the base fabric, and the movable yarn holder does not swing in directions such as front, back, left, right, up, or down. This makes the first angle 90° or 180°, meaning the woven texture structure is in a straight thread type or a stepped straight thread type. This greatly enhances the aesthetic effect of the base fabric and significantly reduces the elongation performance of the base fabric in the warp direction or/and weft direction, making the structure of the base fabric more stable.
In some embodiments, the angle comprises a second angle, the second angle is 0°<the second angle<90° or 90°<the second angle<180°. The present application utilizes a movable yarn nozzle to weave on the base fabric, and the movable yarn nozzle can swing in any direction such as front, back, left, right, up, and down, so that the second angle woven is 0°<the angle<90° or 90°<the angle<180°. This results in a curved texture structure, greatly enhancing the aesthetic effect of the base fabric and significantly reducing the elongation performance of the base fabric in the warp and/or weft direction, making the structure of the base fabric more stable.
In some embodiments, each adjacent second angle is consistent or inconsistent. The present application utilizes a movable yarn nozzle to weave on the base fabric. The movable yarn nozzle can swing in any direction such as forward, backward, left, right, up, and down, and always maintains each adjacent second angle consistent, making the texture structure smoother. In addition, the present application utilizes a movable yarn nozzle to weave on the base fabric. The movable yarn nozzle can swing in any direction such as forward, backward, left, right, up, and down, and always maintains each adjacent second angle inconsistent, making the texture structure more diverse.
In some embodiments, the threads are thread segments formed by the movable yarn nozzle through non-loop knitting. The present application utilizes a movable yarn nozzle to weave texture structures through non-loop knitting, embedding the texture structures into the base fabric.
In some embodiments, the threads are long axes formed by the movable yarn nozzle through loop knitting. The present application utilizes a movable yarn nozzle to weave texture structures through loop knitting, interweaving the texture structures with the base fabric, thereby significantly enhancing the structural stability of the base fabric.
In some embodiments, the colors of every two adjacent threads are different. The present application can make the colors of every two adjacent threads different by replacing different movable yarn nozzles, making the texture structure more colorful.
In some embodiments, the threads are woven from multiple yarns. The present application can weave threads by moving the yarn nozzle carrying multiple yarns, thereby adjusting the thickness of the threads, allowing the texture structure to achieve different raised structures.
In some embodiments, the texture structure is hidden and/or exposed woven on the base fabric. The texture structure of the present application can be hidden within the base fabric, exposed outside the base fabric, or partially hidden and partially exposed, thereby achieving different visual effects and structural stability.
In a fifth aspect, the present application provides a fabric, comprising a base fabric and a texture structure integrally woven with the base fabric.
In a sixth aspect, the present application provides a Flyknit fabric, comprising a Flyknit fabric body and a warp structure integrally woven with the Flyknit fabric body. The warp structure is woven by the movable yarn nozzle in the yarn holder with movable yarn nozzle described above, in a warp direction of the Flyknit fabric body, and the movable yarn nozzle does not need to perform a yarn kicking avoidance action during yarn weaving. The present application uses a movable yarn nozzle for yarn output and weaving on the Flyknit fabric body. During the weaving process, there is no need to avoid yarn kicking actions, allowing for the rapid weaving of warp structures with multiple warp stripes. This greatly enriches the texture structure of the Flyknit fabric in the warp direction, while also enhancing the strength and stability of the Flyknit fabric in the warp direction and reducing its extensibility and deformation capability.
In some embodiments, the warp structure is one or more of the straight warp structure, bent warp structure, or scattered warp structure.
In some embodiments, the warp structure is woven into the surface layer and/or inner layer of the Flyknit fabric body.
In some embodiments, the warp structure is integrally woven with the Flyknit fabric body through inlay, float thread, loop formation, tuck stitch, or needle-turn weaving methods.
Furthermore, the warp structure is integrally woven with the Flyknit fabric body through the inlay method. The present application uses a movable yarn nozzle to feed yarn in the warp direction of the Flyknit fabric body and weaves the warp yarn into the surface layer and/or inner layer of the Flyknit fabric body in an inlay manner to form a warp structure with an inlay effect.
Further, the warp structure is integrally woven with the Flyknit fabric body by means of float threads. The present application utilizes a movable yarn nozzle to feed yarn in the warp direction of the Flyknit fabric body and weaves the warp yarn into the surface layer and/or inner layer of the Flyknit fabric body by means of float threads to form a warp structure with a floating effect.
Further, the warp structure is integrally woven with the Flyknit fabric body by means of loop formation. The present application utilizes a movable yarn nozzle to feed yarn in the warp direction of the Flyknit fabric body and weaves the warp yarn into the surface layer and/or inner layer of the Flyknit fabric body by means of loop formation, thereby making the connection between the warp structure and the Flyknit fabric body more stable and firmer.
Furthermore, the warp structure is integrally woven with the Flyknit fabric body through the needle-turn weaving method. The present application employs a movable yarn nozzle to release yarn in the warp direction of the Flyknit fabric body and weave the warp yarn into the Flyknit fabric body using the needle-turn weaving method, allowing the warp structure to be arranged on the front and back surface layers of the Flyknit fabric body.
In some embodiments, the warp structure comprises several warp stripes, which are parallel and/or intersect with each other.
Furthermore, the warp stripes are parallel to each other, thereby forming a warp structure with a sense of regularity.
Furthermore, each of the warp stripes intersects with one another, thereby forming a warp structure with a sense of richness.
Furthermore, some of the warp stripes are parallel to each other, while others intersect, thereby forming a warp structure that combines a sense of order and richness.
In some embodiments, the color of the warp structure is different from the color of the Flyknit fabric body.
In some embodiments, the Flyknit fabric body is single-layered, double-layered, or
multi-layered.
In a seventh aspect, the present application provides a weaving process for the Flyknit fabric, comprising the following steps:
In some embodiments, it further comprises a fixed weaving between the introducing weaving and fabric weaving, and a movable weaving between fabric weaving and the lead-out weaving, wherein the fixed weaving is to perform tuck weaving on the flying woven fabric during weaving, which serves to fix the warp yarns in the parked position to prevent slippage when the subsequent warp yarns move. The moving weaving is to perform moving weaving on the warp yarn during weaving, which serves to form a warp-directional curved bend on the Flyknit fabric body.
In some embodiments, during fabric weaving, each adjacent two fabric weaving operations need to offset by one needle position.
By adopting the above technical solution, the beneficial effects of the present application are:
1. The movable yarn nozzle of the present application can swing back and forth. In the yarn holder structure, the range of movement of the movable yarn nozzle is smaller than the range of its swing. The back-and-forth swing of the movable yarn nozzle can quickly adjust the yarn nozzle to the weaving position, resulting in good coordination.
2. The yarn holder of the present application can be provided with both fixed and movable yarn nozzles. The movable yarn nozzle is controlled by a mechanical structure to move and swing within the active area on the yarn holder. The active area is divided into various zones based on the layout of the yarn nozzles. Additionally, the layout structure of the fixed and movable yarn nozzles is configured to be a layered structure, facilitating more weaving actions by the yarn nozzles.
3. The yarn holder of the present application can be configured with only movable yarn nozzles. Multiple movable yarn nozzles can cooperate for weaving, and the movable yarn nozzles can move in multiple directions, such as up and down, left and right, forward and backward, rotate, and swing. Similarly, different movable yarn nozzles can also be designed in layers. By setting multiple movable yarn nozzles on the yarn holder, the yarn holder can perform more weaving actions.
4. In the present application, the yarn nozzle structure is further optimized to improve the yarn outlet structure, allowing the yarn outlet to be adjustable, which is beneficial for enhancing the weaving effect.
5. The movable yarn nozzle of the present application can be fixed to form a fixed yarn nozzle. The yarn nozzles on the yarn holder can be adjusted by changing the position of the yarn holder, thereby adjusting the displacement of the yarn nozzles on the yarn holder to the corresponding position for weaving. The yarn holder adopts a movable yarn nozzle instead of the traditional fixed yarn nozzle. When the yarn nozzle needs to move, it can quickly link and cooperate for weaving, thereby increasing weaving efficiency.
6. The present application utilizes multiple movable yarn nozzles to integrally weave a texture structure on the base fabric. This texture structure comprises multiple thread segments, and any angle can be formed between any two adjacent threads. As a result, the texture structure can be arranged in the warp direction and/or the weft direction on the base fabric, forming various texture patterns. This not only enhances the aesthetic effect of the base fabric but also reduces the elongation performance of the base fabric in the warp direction and/or the weft direction, greatly improving the structural stability of the base fabric. The present application can swing or not swing the movable yarn nozzle as needed, thereby enabling the texture structure to achieve curved or straight thread effects, greatly enriching the pattern of the texture and significantly enhancing the structural stability of the base fabric. The present application can make the colors of every two adjacent thread segments different by replacing different movable yarn nozzles, making the texture structure more colorful. The present application can carry multiple yarns through the movable yarn nozzle for weaving threads, thereby adjusting the thickness of the threads, enabling the texture structure to achieve a concave-convex structure.
7. The present application uses a movable yarn nozzle to release yarn and weave on the Flyknit fabric body. During the weaving process, there is no need to avoid the yarn-kicking action, thus enabling the rapid weaving of warp structures with multiple warp stripes, greatly enriching the thread texture structure of the Flyknit fabric in the warp direction. This also enhances the strength and stability of the Flyknit fabric in the warp direction while reducing its extensibility and deformation capability. In the present application, when the yarn nozzle for weaving warp stripes encounters other weaving yarn nozzles during the weaving process, there is no need to perform a yarn avoidance kick action, thus significantly saving time. Moreover, the more yarn nozzles for weaving warp stripes, the more time is saved compared to the traditional Flyknit warp insertion process. The present application can be combined with movable yarn nozzle to weave warp stripes exceeding the number of yarn nozzles in traditional Flyknit equipment, significantly reducing the elongation performance in the warp direction of the Flyknit fabric. Multiple warp stripes in the present application can participate in loop formation, tuck stitch, tuck stitch, float thread, and other weaving processes, or simply serve as warp insertion, producing exquisite warp structures. The present application breaks through the traditional process concept of Flyknit products, providing a new development direction for the innovation of Flyknit products.
It should be understood that the above general description and the detailed description below are merely exemplary and explanatory and are not restrictive of this disclosure.
Undoubtedly, such objectives and other objectives of the present application will become more apparent after the detailed description of the preferred embodiments described below with various figures and drawings.
To make the above and other objectives, features, and advantages of the present application more apparent and understandable, one or more preferred embodiments are specifically cited below, and detailed descriptions are provided in conjunction with the accompanying figures.
The figures are provided to further understand the present application and constitute a part of the specification. They are used in conjunction with the embodiments of the present application to explain the application and do not constitute a limitation on the application.
In the figures, the same components are denoted by the same reference numerals, and the figures are schematic and may not necessarily be drawn to scale.
To more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the following is a brief introduction to the figures required for the description of the embodiments or the prior art. It is evident that the figures described below are merely one or several embodiments of the present application. For those skilled in the art, other figures can be obtained based on these figures without creative effort.
In the drawings:
To make the objectives, technical solutions, and advantages of the present application clearer, the following provides a more detailed description of the present application in conjunction with specific embodiments. It should be understood that the specific embodiments described herein are merely for explaining the present application and are not intended to limit the present application.
Additionally, in the description of the present application, it should be understood that the terms ‘center’, ‘upper’, ‘lower’, ‘front’, ‘rear’, ‘left’, ‘right’, ‘vertical’, ‘horizontal’, ‘top’, ‘bottom’, ‘inner’, ‘outer’, ‘axial’, ‘radial’, ‘circumferential’, etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the figures. These terms are merely for the convenience of describing the present application and simplifying the description and are not intended to indicate or imply that the referenced devices or elements must have specific orientations, be constructed, and operated in specific orientations. Therefore, they should not be construed as limitations on the present application.
In the present application, unless otherwise explicitly specified and limited, terms such as ‘install’, ‘connect’, ‘link’, ‘fix’, etc., should be understood in a broad sense. For example, it can be a fixed connection, a detachable connection, or an integral connection; It can be directly connected, indirectly connected through an intermediary medium, or an internal communication or interaction relationship between two components. However, if it is specified as a direct connection, it indicates that the connection between the two main bodies is established without any transitional structure, only through the connecting structure to form an integral whole. For those skilled in the art, the specific meanings of the above terms in the present application can be understood according to the specific circumstances.
In the present application, unless otherwise explicitly specified and limited, the first feature being ‘on’ or ‘under’ the second feature may mean that the first and second features are in direct contact, or the first and second features are in indirect contact through an intermediate medium. In the description of this specification, the terms ‘one embodiment’, ‘some embodiments’, ‘example’, ‘specific example’, or ‘some examples’, etc., mean that the specific features, structures, materials, or characteristics described in connection with the embodiment or example are included in at least one embodiment or example of the present application. In this specification, the illustrative expressions of the above terms do not necessarily refer to the same embodiment or example. Moreover, the specific features, structures, materials, or characteristics described can be combined in any suitable manner in one or more embodiments or examples.
Referring to
The present application plans the layout structure of the yarn nozzle on the yarn holder 10, enabling the weaving equipment to perform more weaving actions when controlling the yarn holder 10 to move for weaving, thereby indirectly improving weaving efficiency.
According to some embodiments of the present application, optionally, the yarn holder 10 is adjusted by the first adjustment mechanism to move the yarn holder 10 integrally left and right, and the movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move up and down and/or back and forth on the yarn holder 10.
According to some embodiments of the present application, optionally, the yarn holder 10 is adjusted by the first adjustment mechanism to move the yarn holder 10 integrally left and right, and back and forth, and the movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move up and down on the yarn holder 10.
According to some embodiments of the present application, optionally, the yarn holder 10 is adjusted by the first adjustment mechanism to move the yarn holder 10 integrally left and right, and up and down, and the movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move back and forth on the yarn holder 10.
According to some embodiments of the present application, optionally, the movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move left and right on the yarn holder 10, and the yarn holder 10 is adjusted by the first adjustment mechanism to move integrally up and down or/and back and forth.
According to some embodiments of the present application, optionally, the movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move left and right, back and forth on the yarn holder 10, and the yarn holder 10 is adjusted by the first adjustment mechanism to move up and down integrally.
According to some embodiments of the present application, optionally, the movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move left and right, up and down on the yarn holder 10, and the yarn holder 10 is adjusted by the first adjustment mechanism to move back and forth integrally.
According to some embodiments of the present application, optionally, the yarn holder 10 is adjusted by the first adjustment mechanism to move up and down integrally, and the movable yarn nozzle 40 is adjusted to move back and forth on the yarn holder 10 by the second adjustment mechanism.
According to some embodiments of the present application, optionally, the movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move up and down on the yarn holder 10, and the yarn holder 10 is adjusted by the first adjustment mechanism to move the yarn holder 10 back and forth integrally.
According to some embodiments of the present application, the present application provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The yarn holder 10 is provided with a first adjustment mechanism for controlling and adjusting the position and direction of the yarn holder 10. At least one movable yarn nozzle 40 is arranged on the yarn holder 10. The integral position of the yarn holder 10 is adjusted by the first adjustment mechanism so that it is adjusted from an initial position to a weaving position, and the yarn holder 10 is adjusted in at least one direction integrally. Among them, the yarn nozzle can be a fixed yarn nozzle 30 or a movable yarn nozzle 40. As long as it is a yarn nozzle on the yarn holder 10, it can be displaced from an initial position to a weaving position by controlling the integral displacement of the yarn holder 10.
According to some embodiments of the present application, optionally, the yarn holder 10 is adjusted to move integrally left and right or up and down or back and forth through the first adjustment mechanism.
According to some embodiments of the present application, optionally, the yarn holder 10 is adjusted to move integrally left and right through the first adjustment mechanism, and the yarn holder 10 is adjusted to move integrally up and down and/or back and forth through the first adjustment mechanism.
According to some embodiments of the present application, optionally, the yarn holder 10 is adjusted by the first adjustment mechanism to move the yarn holder 10 integrally up and down, and back and forth.
According to some embodiments of the present application, the present application provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The position and direction of the movable yarn nozzle 40 on the yarn holder 10 is adjusted by the second adjustment mechanism. The movable yarn nozzle 40 is controlled by the second adjustment mechanism to move the movable yarn nozzle 40 from an initial position to a weaving position in at least one direction. At least one movable yarn nozzle 40 is arranged on the yarn holder 10.
According to some embodiments of the present application, optionally, the movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move left and right or up and down or back and forth on the yarn holder 10.
According to some embodiments of the present application, optionally, the movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move left and right on the yarn holder 10, and the movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move up and down or/and back and forth on the yarn holder 10.
According to some embodiments of the present application, optionally, the movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move up and down, back and forth.
According to some embodiments of the present application, optionally, several yarn nozzles are arranged and distributed in different layers.
According to some embodiments of the present application, optionally, the movable yarn nozzle 40 is rotatable.
According to some embodiments of the present application, optionally, the movable yarn nozzle 40 does not move and constitutes a fixed yarn nozzle 30.
According to some embodiments of the present application, optionally, the movable yarn nozzle 40 is adjusted by the third adjustment mechanism to swing back and forth on the yarn holder 10.
According to some embodiments of the present application, optionally, the movable yarn nozzle 40 swings back and forth by the third adjustment mechanism in cooperation with an swinging pivot 50, wherein the swinging pivot 50 is located on the yarn holder 10 or the movable yarn nozzle 40.
According to some embodiments of the present application, optionally, the yarn nozzle is provided with several independent yarn outlets 60, the spacing between adjacent yarn outlets 60 is adjustable, the height of the independent yarn outlets 60 is adjustable, and the size of the independent yarn outlets 60 is adjustable. These can be arranged on both fixed yarn nozzles and movable yarn nozzles.
According to some embodiments of the present application, optionally, the present application provides a yarn holder with movable yarn nozzle. The yarn holder 10 is provided with an active area 20 for controlling the movement of the movable yarn nozzle 40. The yarn holder 10 is provided with movable yarn nozzle 40 and a fixed yarn nozzle 30, defining the fixed yarn nozzle 30 as a yarn nozzle that remains stationary. The movable yarn nozzle 40 is set inside the two fixed yarn nozzles 30 and has two modes: a fixed knitting mode and an active knitting mode that follows the displacement of the integral yarn holder 10.
According to some embodiments of the present application, optionally, three fixed yarn nozzles 30 are provided, one movable yarn nozzle 40 is provided, and the fixed yarn nozzles 30 and the movable yarn nozzle 40 are staggered on the yarn holder 10. The active area 20 controlled by the movement of the movable yarn nozzle 40 is the entire yarn holder 10.
According to some embodiments of the present application, optionally, three movable yarn nozzles 40 are provided, one fixed yarn nozzle 30 is provided, and the fixed yarn nozzle 30 and the movable yarn nozzles 40 are staggered on the yarn holder 10. The active area 20 controlled by the movement of the movable yarn nozzles 40 is the independent active area 20 where the yarn nozzle is located.
According to some embodiments of the present application, optionally, two movable yarn nozzles 40 are provided, two fixed yarn nozzles 30 are provided, the yarn holder 10 is divided into two active areas 20, and the fixed yarn nozzles 30 and the movable yarn nozzles 40 are staggered.
According to some embodiments of the present application, optionally, at least one fixed yarn nozzle 30 is provided, and it serves as the main yarn nozzle. The movable yarn nozzle 40 can move in multiple directions or/and rotate. The active area 20 controlled by the movement of the movable yarn nozzle 40 covers the entire yarn holder 10. The fixed yarn nozzles 30 and the movable yarn nozzles 40 are arranged in layers.
According to some embodiments of the present application, optionally, the present application provides a yarn holder with movable yarn nozzle, all being movable yarn nozzles 40. An active area 20 for controlling the movement of the movable yarn nozzle 40 is provided on the yarn holder 10. Three movable yarn nozzles 40 are provided, with different movable yarn nozzles 40 respectively located in corresponding active areas 20.
According to some embodiments of the present application, optionally, four movable yarn nozzles 40 are provided, with the movable yarn nozzles 40 arranged in at least two layers. Any one movable yarn nozzle 40 is independently arranged on any layer structure of the yarn holder 10, and the active area 20 for controlling its movement is the entire yarn holder 10. The active areas 20 for controlling the movement of the remaining movable yarn nozzles 40 are the independent active areas 20 where the yarn nozzles are located.
According to some embodiments of the present application, optionally, the numbers of different yarn nozzles are different.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The yarn holder 10 is provided with a first adjustment mechanism for controlling and adjusting the position and direction of the yarn holder 10. The position and direction of the movable yarn nozzle 40 on the yarn holder 10 are adjusted by a second adjustment mechanism. At least one movable yarn nozzle 40 is arranged on the yarn holder 10. The first adjustment mechanism is configured to cooperated with the second adjustment mechanism to control the displacement of the movable yarn nozzle 40 on the yarn holder 10 from an initial position to a weaving position.
The yarn holder 10 is adjusted to move integrally left and right by the first adjustment mechanism, and the movable yarn nozzle 40 is adjusted to move up and down on the yarn holder 10 by the second adjustment mechanism.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The yarn holder 10 is provided with a first adjustment mechanism for controlling and adjusting the position and direction of the yarn holder 10. The position and direction of the movable yarn nozzle 40 on the yarn holder 10 are adjusted by a second adjustment mechanism. At least one movable yarn nozzle 40 is arranged on the yarn holder 10. The first adjustment mechanism is configured to cooperated with the second adjustment mechanism to control the displacement of the movable yarn nozzle 40 on the yarn holder 10 from an initial position to a weaving position.
The yarn holder 10 is adjusted to move integrally left and right by the first adjustment mechanism, and the movable yarn nozzle 40 is adjusted to move back and forth on the yarn holder 10 by the second adjustment mechanism.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The yarn holder 10 is provided with a first adjustment mechanism for controlling and adjusting the position and direction of the yarn holder 10. The position and direction of the movable yarn nozzle 40 on the yarn holder 10 are adjusted by a second adjustment mechanism. At least one movable yarn nozzle 40 is arranged on the yarn holder 10. The first adjustment mechanism is configured to cooperated with the second adjustment mechanism to control the displacement of the movable yarn nozzle 40 on the yarn holder 10 from an initial position to a weaving position.
The yarn holder 10 is adjusted to move integrally left and right by the first adjustment mechanism, and the movable yarn nozzle 40 is adjusted to move up and down on the yarn holder 10 by the second adjustment mechanism. The movable yarn nozzle 40 is adjusted to move back and forth on the yarn holder 10 by the second adjustment mechanism.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The yarn holder 10 is provided with a first adjustment mechanism for controlling and adjusting the position and direction of the yarn holder 10. The position and direction of the movable yarn nozzle 40 on the yarn holder 10 are adjusted by a second adjustment mechanism. At least one movable yarn nozzle 40 is provided on the yarn holder 10. The first adjustment mechanism is configured to cooperated with the second adjustment mechanism to control the displacement of the movable yarn nozzle 40 on the yarn holder 10 from an initial position to a weaving position.
The yarn holder 10 is adjusted to move integrally left and right by the first adjustment mechanism, the movable yarn nozzle 40 is adjusted to move up and down on the yarn holder 10 by the second adjustment mechanism, and the yarn holder 10 is adjusted to move integrally back and forth by the first adjustment mechanism.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The yarn holder 10 is provided with a first adjustment mechanism for controlling and adjusting the position and direction of the yarn holder 10. The position and direction of the movable yarn nozzle 40 on the yarn holder 10 are adjusted by a second adjustment mechanism. At least one movable yarn nozzle 40 is provided on the yarn holder 10. The first adjustment mechanism is configured to cooperated with the second adjustment mechanism to control the displacement of the movable yarn nozzle 40 on the yarn holder 10 from an initial position to ta weaving position.
The yarn holder 10 is adjusted by the first adjustment mechanism to move the yarn holder 10 integrally left and right, and the yarn holder 10 is adjusted by the first adjustment mechanism to move the yarn holder 10 integrally up and down. The movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move back and forth on the yarn holder 10.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The yarn holder 10 is provided with a first adjustment mechanism for controlling and adjusting the position and direction of the yarn holder 10. The position and direction of the movable yarn nozzle 40 on the yarn holder 10 are adjusted by a second adjustment mechanism. At least one movable yarn nozzle 40 is provided on the yarn holder 10. The first adjustment mechanism is configured to cooperated with the second adjustment mechanism to control the displacement of the movable yarn nozzle 40 on the yarn holder 10 from an initial position to a weaving position.
The movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move left and right on the yarn holder 10. The yarn holder 10 is adjusted by the first adjustment mechanism to move the yarn holder 10 integrally up and down.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The yarn holder 10 is provided with a first adjustment mechanism for controlling and adjusting the position and direction of the yarn holder 10. The position and direction of the movable yarn nozzle 40 on the yarn holder 10 are adjusted by a second adjustment mechanism. At least one movable yarn nozzle 40 is provided on the yarn holder 10. The first adjustment mechanism is configured to cooperated with the second adjustment mechanism to control the displacement of the movable yarn nozzle 40 on the yarn holder 10 from an initial position to a weaving position.
The movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move left and right on the yarn holder 10. The yarn holder 10 is adjusted by the first adjustment mechanism to move the yarn holder 10 integrally back and forth.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The yarn holder 10 is provided with a first adjustment mechanism for controlling and adjusting the position and direction of the yarn holder 10. The position and direction of the movable yarn nozzle 40 on the yarn holder 10 are adjusted by a second adjustment mechanism. At least one movable yarn nozzle 40 is provided on the yarn holder 10. The first adjustment mechanism is configured to cooperated with the second adjustment mechanism to control the displacement of the movable yarn nozzle 40 on the yarn holder 10 from an initial position to a weaving position.
The movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move left and right on the yarn holder 10. The yarn holder 10 is adjusted by the first adjustment mechanism to move the yarn holder 10 integrally up and down. The yarn holder 10 is adjusted by the first adjustment mechanism to move the yarn holder 10 integrally back and forth.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The yarn holder 10 is provided with a first adjustment mechanism for controlling and adjusting the position and direction of the yarn holder 10. The position and direction of the movable yarn nozzle 40 on the yarn holder 10 are adjusted by a second adjustment mechanism. At least one movable yarn nozzle 40 is provided on the yarn holder 10. The first adjustment mechanism is configured to cooperated with the second adjustment mechanism to control the displacement of the movable yarn nozzle 40 on the yarn holder 10 from an initial position to a weaving position.
The movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move left and right on the yarn holder 10. The yarn holder 10 is adjusted by the first adjustment mechanism to move the yarn holder 10 integrally up and down. The movable yarn nozzle 40 is adjusted to move back and forth movement on the yarn holder 10 through the second adjustment mechanism.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The yarn holder 10 is provided with a first adjustment mechanism for controlling and adjusting the position and direction of the yarn holder 10. The position and direction of the movable yarn nozzle 40 on the yarn holder 10 are adjusted by a second adjustment mechanism. At least one movable yarn nozzle 40 is provided on the yarn holder 10. The first adjustment mechanism is configured to cooperated with the second adjustment mechanism to control the displacement of the movable yarn nozzle 40 on the yarn holder 10 from an initial position to a weaving position.
The movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move left and right on the yarn holder 10. The movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move up and down on the yarn holder 10. The yarn holder 10 is adjusted by the first adjustment mechanism to move the entire yarn holder 10 back and forth.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The yarn holder 10 is provided with a first adjustment mechanism for controlling and adjusting the position and direction of the yarn holder 10. The position and direction of the movable yarn nozzle 40 on the yarn holder 10 are adjusted by a second adjustment mechanism. At least one movable yarn nozzle 40 is provided on the yarn holder 10. The first adjustment mechanism is configured to cooperated with the second adjustment mechanism to control the displacement of the movable yarn nozzle 40 on the yarn holder 10 from an initial position to a weaving position.
The yarn holder 10 is adjusted by the first adjustment mechanism to move the yarn holder 10 integrally up and down. The movable yarn nozzle 40 is adjusted to move back and forth on the yarn holder 10 by the second adjustment mechanism.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The yarn holder 10 is provided with a first adjustment mechanism for controlling and adjusting the position and direction of the yarn holder 10. The position and direction of the movable yarn nozzle 40 on the yarn holder 10 are adjusted by a second adjustment mechanism. At least one movable yarn nozzle 40 is provided on the yarn holder 10. The first adjustment mechanism is configured to cooperated with the second adjustment mechanism to control the displacement of the movable yarn nozzle 40 on the yarn holder 10 from an initial position to a weaving position.
The movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move up and down on the yarn holder 10. The yarn holder 10 is adjusted by the first adjustment mechanism to move the entire yarn holder 10 back and forth.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The yarn holder 10 is provided with a first adjustment mechanism for controlling and adjusting the position and direction of the yarn holder 10. At least one movable yarn nozzle 40 is arranged on the yarn holder 10. The yarn nozzle adjusts the overall position of the yarn holder 10 by the first adjustment mechanism, allowing it to be adjusted from an initial position to a weaving position, and the entire yarn holder 10 is adjusted in at least one direction.
The yarn holder 10 is adjusted to move integrally left and right by the first adjustment mechanism.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The yarn holder 10 is provided with a first adjustment mechanism for controlling and adjusting the position and direction of the yarn holder 10. At least one movable yarn nozzle 40 is arranged on the yarn holder 10. The yarn nozzle adjusts the overall position of the yarn holder 10 through the first adjustment mechanism, allowing it to be adjusted from an initial position to a weaving position, and the entire yarn holder 10 is adjusted in at least one direction.
The yarn holder 10 is adjusted to move integrally left and right by the first adjustment mechanism, and the yarn holder 10 is adjusted to move integrally up and down by the first adjustment mechanism.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The yarn holder 10 is provided with a first adjustment mechanism for controlling and adjusting the position and direction of the yarn holder 10. At least one movable yarn nozzle 40 is arranged on the yarn holder 10. The yarn nozzle adjusts the overall position of the yarn holder 10 by the first adjustment mechanism, allowing it to be adjusted from an initial position to a weaving position, and the entire yarn holder 10 is adjusted in at least one direction.
The yarn holder 10 is adjusted to move integrally left and right by the first adjustment mechanism, and the yarn holder 10 is adjusted to move integrally back and forth by the first adjustment mechanism.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The yarn holder 10 is provided with a first adjustment mechanism for controlling and adjusting the position and direction of the yarn holder 10. At least one movable yarn nozzle 40 is arranged on the yarn holder 10. The yarn nozzle adjusts the overall position of the yarn holder 10 by the first adjustment mechanism, allowing it to be adjusted from an initial position to a weaving position, and the entire yarn holder 10 is adjusted in at least one direction.
The yarn holder 10 is adjusted to move integrally left and right by the first adjustment mechanism, the yarn holder 10 is adjusted to move integrally up and down by the first adjustment mechanism, and the yarn holder 10 is adjusted to move integrally back and forth by the first adjustment mechanism.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The yarn holder 10 is provided with a first adjustment mechanism for controlling and adjusting the position and direction of the yarn holder 10. At least one movable yarn nozzle 40 is arranged on the yarn holder 10. The yarn nozzle adjusts the overall position of the yarn holder 10 by the first adjustment mechanism, allowing it to be adjusted from an initial position to a weaving position, and the entire yarn holder 10 is adjusted in at least one direction.
The yarn holder 10 is adjusted by the first adjustment mechanism to move the yarn holder 10 integrally up and down.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The yarn holder 10 is provided with a first adjustment mechanism for controlling and adjusting the position and direction of the yarn holder 10. At least one movable yarn nozzle 40 is arranged on the yarn holder 10. The yarn nozzle adjusts the overall position of the yarn holder 10 by the first adjustment mechanism, allowing it to be adjusted from an initial position to a weaving position, and the entire yarn holder 10 is adjusted in at least one direction.
The yarn holder 10 is adjusted by the first adjustment mechanism to move the yarn holder 10 up and down integrally, and the yarn holder 10 is adjusted by the first adjustment mechanism to move the yarn holder 10 back and forth integrally.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The yarn holder 10 is provided with a first adjustment mechanism for controlling and adjusting the position and direction of the yarn holder 10. At least one movable yarn nozzle 40 is arranged on the yarn holder 10. The yarn nozzle adjusts the overall position of the yarn holder 10 by the first adjustment mechanism, allowing it to be adjusted from an initial position to a weaving position, and the entire yarn holder 10 is adjusted in at least one direction.
The yarn holder 10 is adjusted by the first adjustment mechanism to move the yarn holder 10 integrally back and forth.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The position direction of the movable yarn nozzle 40 is adjusted by the second adjustment mechanism on the yarn holder 10. The movable yarn nozzle 40 is controlled by the second adjustment mechanism to move from an initial position to a weaving position in at least one direction. At least one movable yarn nozzle 40 is provided on the yarn holder 10.
The movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move left and right on the yarn holder 10.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The position direction of the movable yarn nozzle 40 is adjusted by the second adjustment mechanism on the yarn holder 10. The movable yarn nozzle 40 is controlled by the second adjustment mechanism to move from an initial position to a weaving position in at least one direction. At least one movable yarn nozzle 40 is arranged on the yarn holder 10.
The movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move left and right on the yarn holder 10, and the movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move up and down on the yarn holder 10.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The position and direction of the movable yarn nozzle 40 on the yarn holder 10 is adjusted by the second adjustment mechanism. The movable yarn nozzle 40 is controlled by the second adjustment mechanism to move from an initial position to a weaving position in at least one direction. At least one movable yarn nozzle 40 is arranged on the yarn holder 10.
The movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move left and right on the yarn holder 10, and the movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move back and forth on the yarn holder 10.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The position direction of the movable yarn nozzle 40 is adjusted by the second adjustment mechanism on the yarn holder 10. The movable yarn nozzle 40 is controlled by the second adjustment mechanism to move from an initial position to a weaving position in at least one direction. At least one movable yarn nozzle 40 is arranged on the yarn holder 10.
The movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move left and right on the yarn holder 10, the movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move up and down on the yarn holder 10, and the movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move back and forth on the yarn holder 10.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The position direction of the movable yarn nozzle 40 is adjusted by the second adjustment mechanism on the yarn holder 10. The movable yarn nozzle 40 is controlled by the second adjustment mechanism to move from an initial position to a weaving position in at least one direction. At least one movable yarn nozzle 40 is arranged on the yarn holder 10.
The movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move up and down on the yarn holder 10.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The position direction of the movable yarn nozzle 40 is adjusted by the second adjustment mechanism on the yarn holder 10. The movable yarn nozzle 40 is controlled by the second adjustment mechanism to move from an initial position to a weaving position in at least one direction. At least one movable yarn nozzle 40 is arranged on the yarn holder 10.
The movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move up and down on the yarn holder 10, and the movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move back and forth on the yarn holder 10.
This embodiment provides a yarn holder with movable yarn nozzle, comprising a yarn holder 10 and several yarn nozzles. The yarn nozzle comprises a movable yarn nozzle 40. The position direction of the movable yarn nozzle 40 is adjusted by the second adjustment mechanism on the yarn holder 10. The movable yarn nozzle 40 is controlled by the second adjustment mechanism to move from an initial position to a weaving position in at least one direction. At least one movable yarn nozzle 40 is arranged on the yarn holder 10.
The movable yarn nozzle 40 is adjusted by the second adjustment mechanism to move back and forth on the yarn holder 10.
This embodiment provides a yarn holder with movable yarn nozzle. Based on the structure of any one of the yarn holders 10 with movable yarn nozzle 40 in embodiments 1-26, several yarn nozzles are further arranged in different layers, i.e., staggered arrangement of yarn nozzles. Taking the arrangement of yarn nozzles in two layers as an example, in the first case, the staggered arrangement can have all fixed yarn nozzles 30 in the first layer and all movable yarn nozzles 40 in the second layer, with at least one yarn nozzle in the first and second layer. In the second case, both the first and second layers consist entirely of movable yarn nozzles 40, with at least one yarn nozzle in each layer. Based on the staggered arrangement of movable yarn nozzles 40, the maximum range of movement for the movable yarn nozzles 40 can be the entire yarn holder 10, or the yarn holder 10 can be divided into at least two regions, with the movable yarn nozzles 40 in each region moving within their respective regions.
This embodiment provides a yarn holder with movable yarn nozzle. Based on the structure of any yarn holder 10 with movable yarn nozzle 40 in Embodiments 1-27, this embodiment further sets the movable yarn nozzle 40 as a rotatable yarn nozzle.
Preferably, the rotatable yarn nozzle is arranged based on a staggered structure, that is, to achieve the rotational switching position of the yarn nozzles of different layers.
This embodiment provides a yarn holder with movable yarn nozzle. Based on the structure of any yarn holder 10 with movable yarn nozzle 40 in Embodiments 1-28, this embodiment further comprises not only the movable yarn nozzle 40 but also a fixed yarn nozzle 30, wherein the fixed yarn nozzle 30 is formed when the movable yarn nozzle 40 is not moving, or a conventional fixed yarn nozzle 30 is directly used in conjunction with the movable yarn nozzle 40.
Referring to
This embodiment provides a yarn holder with movable yarn nozzle. This embodiment is based on the structure of any one of the yarn holders with movable yarn nozzle in Embodiments 1-29. Furthermore, the movable yarn nozzle 40 can swing. Specifically, the movable yarn nozzle 40 swings back and forth through the cooperation of the third adjustment mechanism and the swinging pivot 50. The swinging pivot 50 is located on the yarn holder 10, that is, the position of the swinging pivot 50 is at the connection between the movable yarn nozzle 40 and the yarn holder 10.
As shown in
In
Referring to
This embodiment provides a yarn holder with movable yarn nozzle. Based on the structure of any yarn holder with movable yarn nozzle in Embodiments 1-29, the movable yarn nozzle 40 can swing. Specifically, the movable yarn nozzle 40 swings back and forth through the cooperation of the third adjustment mechanism and the swinging pivot 50, where the swinging pivot 50 is located on the movable yarn nozzle 40.
The movable yarn nozzle 40 is first arranged on the yarn holder 10. In this embodiment, the swinging of the movable yarn nozzle 40 is achieved by the control structure inherent to the movable yarn nozzle 40 itself, rather than relying on the structure of the connection area between the top end of the movable yarn nozzle 40 and the yarn holder 10.
In
Referring to
One movable yarn nozzle 40 is provided, located inside the two fixed yarn nozzles 30. The movable yarn nozzle 40 has two modes: a fixed knitting mode and an active knitting mode that follows the displacement of the entire yarn holder 10.
In
When the entire yarn holder 10 is performing knitting operations, the No. 1 and No. 3 yarn nozzles will perform fixed knitting, while the No. 2 yarn nozzle will move in any direction (comprising left and right, back and forth, or up and down) following the movement of the entire yarn holder 10 or remain stationary to perform knitting.
Referring to
Three fixed yarn nozzles 30 are provided, and one movable yarn nozzle 40 is provided. The fixed yarn nozzles 30 and the movable yarn nozzle 40 are staggered on the yarn holder 10. The active area 20 for controlling the movement of the movable yarn nozzle 40 covers the entire yarn holder 10.
In
The yarn holder 10 can be divided into back and forth layers (or multiple layers), with yarn nozzles No. 1, 2, and 3 located in the rear layer as shown in
When the entire yarn holder 10 is performing knitting operations, yarn nozzles No. 1, 2, and 3 will perform fixed knitting, while yarn nozzle No. 4 will follow the movement of the entire yarn holder 10 and move in any direction within the black area (or perform fixed knitting).
Referring to
Three movable yarn nozzles 40 are provided, and one fixed yarn nozzle 30 is provided. The fixed yarn nozzle 30 and the movable yarn nozzles 40 are staggered on the yarn holder 10. The active area 20 for controlling the movement of the movable yarn nozzle 40 is an independent active area 20 where the yarn nozzle is located.
In
The yarn holder 10 can be divided into back and forth layers (or multiple layers), with yarn nozzles 1, 2, and 3 located in the front layer as shown in
When the entire yarn holder 10 is performing knitting operations, yarn nozzle No. 4 will perform fixed knitting work, while yarn nozzles No. 1, 2, and 3 will move along with the entire yarn holder 10 and perform knitting work in any direction within the black area (or remain fixed).
Referring to
Two movable yarn nozzles 40 are provided, and two fixed yarn nozzles 30 are provided. The yarn holder 10 is divided into two active areas 20, with the fixed yarn nozzles 30 and the movable yarn nozzles 40 staggered on the yarn holder 10.
In
The yarn holder 10 can be divided into back and forth layers (or multiple layers), with yarn nozzles No. 1 and 4 located in the rear layer as shown in
When the entire yarn holder 10 is performing knitting operations, the main yarn nozzles No. 2 and 3 will perform fixed knitting, while yarn nozzles No. 1 and 4 will follow the movement of the entire yarn holder 10 and perform knitting operations in any direction within their respective movable black areas (or fixed).
Referring to
At least one fixed yarn nozzle 30 is provided, which serves as the main yarn nozzle. The movable yarn nozzle 40 can move or/and rotate in multiple directions. The active area 20 for controlling the movement of the movable yarn nozzle 40 covers the entire yarn holder 10. The fixed yarn nozzle 30 and the movable yarn nozzle 40 are arranged in layers.
In
The yarn holder 10 can be divided into two layers (or multiple layers), with the yarn nozzle No. 1 fixed in one of the layers, while the yarn nozzle No. 2 can switch between different layers.
During the weaving operation of the entire yarn holder 10, the main yarn nozzle No. 2 will perform weaving in a fixed position, while the auxiliary yarn nozzle No. 1 will move along with the entire yarn holder 10 and simultaneously rotate around the main yarn nozzle No. 2 in any direction and angle for weaving.
Referring to
Three movable yarn nozzles 40 are provided, with different movable yarn nozzles 40 respectively located in corresponding active areas 20.
In
When the entire yarn holder 10 is performing knitting operations, three (or more) yarn nozzles will move along with the entire yarn holder 10 (comprising in directions such as left and right, back and forth, or up and down) or remain fixed, performing arbitrary knitting operations within their respective black areas.
Referring to
Four movable yarn nozzles 40 are provided, with the movable yarn nozzles 40 arranged in at least two layers. Any one movable yarn nozzle 40 is independently arranged on any one layer structure of the yarn holder 10, and the active area 20 for controlling the movement covers the entire yarn holder 10. The remaining active area 20 for controlling the movement of movable yarn nozzles 40 is the independent active area 20 where the yarn nozzle is located.
The numbers 1, 2, 3, and 4 shown in
The yarn holder 10 can be divided into front and back layers (or multiple layers), with the yarn nozzles No. 1, No. 2, and No. 3 located in the back layer as shown in
When the entire yarn holder 10 is performing weaving operations, all the yarn nozzles will follow the movement of the entire yarn holder 10 and move (or remain fixed) within their respective movable ranges in any direction for weaving operations.
Referring to
Several independent yarn nozzles 60 are arranged on the yarn nozzle, the spacing between adjacent yarn nozzles 60 is adjustable, the height of the independent yarn nozzles 60 can be adjusted independently, and the size of the independent yarn nozzles 60 is adjustable. At least one of adjustable spacing, adjustable height, and adjustable size of the yarn nozzle 60 can be selected to form the optimized structure of the yarn nozzle. The structure of the yarn nozzle and the structure for adjusting the yarn nozzle can be arranged on both the fixed yarn nozzle and the movable yarn nozzle.
The first adjustment mechanism, second adjustment mechanism, and third adjustment mechanism referred to in the present application are structures that control the relative position changes of the corresponding yarn nozzles. When the yarn holder 10 with the movable yarn nozzle 40 is arranged on the weaving equipment, the weaving equipment controls the yarn holder 10 with the movable yarn nozzle 40 to move back and forth within the weaving area of the weaving equipment through displacement components. The first adjustment mechanism, second adjustment mechanism, and third adjustment mechanism are used to control the yarn nozzle on the yarn holder 10 when the yarn holder 10 is not being moved by the displacement component, to adjust and control the yarn nozzle on the yarn holder 10. The first adjustment mechanism, second adjustment mechanism, and third adjustment mechanism can either be independently active control structural components on the yarn holder 10 or transitional components for their linked adjustment. When the first adjustment mechanism, second adjustment mechanism, and third adjustment mechanism are transitional components, their structure still serves as the core for controlling the relative position changes of the corresponding yarn nozzles, but the driving force can be arranged on the weaving equipment. For example, the first adjustment mechanism comprises a tooth block and a spring. The tooth block and spring are arranged on the structure of the yarn holder 10. The weaving equipment is provided with a rack and a motor that controls the rotation of the rack. The rack meshes with the tooth block. At this time, the yarn nozzle corresponding to the first adjustment mechanism can be indirectly controlled to move up and down by controlling the rack. In the present application, the first adjustment mechanism, second adjustment mechanism, and third adjustment mechanism directly or indirectly control the movable yarn nozzle 40 to adjust front and back, left and right, and up and down. This is based on the displacement component controlling the yarn holder 10 with the movable yarn nozzle 40 to move back and forth within the weaving area of the weaving equipment. Further adjustments to the position of the movable yarn nozzle 40 are made independently of the front and back, left and right, and up and down adjustments. The displacement component controls the yarn holder 10 with the movable yarn nozzle 40 to move back and forth within the weaving area of the weaving equipment independently, without mutual interference. In the present application, the first adjustment mechanism is a general term for a structure that indirectly controls the movement of the movable yarn nozzle 40 by adjusting the yarn holder to influence the yarn nozzle; The second adjustment mechanism is a general term for a structure that directly controls the movement of the movable yarn nozzle 40, and the third adjustment mechanism is a general term for a structure that controls the swinging of the movable yarn nozzle 40. The first adjustment mechanism, second adjustment mechanism, and third adjustment mechanism can be integrated structures that control different directions, or they can be single structures that independently control a single direction.
In the prior art, the structure of the movable yarn nozzle 40 may comprise a yarn nozzle frame, within which upper and lower guide rails are provided. A yarn nozzle holder is arranged within the yarn nozzle frame, with a lower moving device that cooperates with the lower guide rail provided on the underside of the yarn nozzle holder. The yarn nozzle holder is connected to a left swing arm and a right swing arm, both of which are connected to upper moving devices that cooperate with the upper guide rail. An elastic adjustment device is provided between the left and right swing arms. The left swing arm and the right swing arm are arranged on the yarn nozzle holder through a rotating shaft. The swing arms' up-and-down movement is adjusted by an elastic adjustment device, causing the upper moving device to clamp tightly onto the upper guide rail, allowing the yarn nozzle holder to move back and forth on the yarn nozzle holder. The elastic adjustment device comprises a rotating shaft arranged on the yarn nozzle holder. A torsion spring is mounted on the rotating shaft, with both ends of the torsion spring connected to the left swing arm and the right swing arm, respectively. Both ends of the torsion spring press against the left swing arm and the right swing arm, causing the swing arms to move up and down. This allows the upper moving device on the swing arms to closely fit with the upper guide rail, thereby improving operational stability. The left swing arm and the right swing arm are rotatably connected to both sides of the yarn nozzle holder and are symmetrically arranged. Both the left swing arm and the right swing arm have a bent structure, with the upper end connected to the upper moving device and the lower end provided with a slot that cooperates with the torsion spring. The torsion spring is mounted on the rotating shaft of the yarn nozzle holder, with both ends in the slot, making it not easy to fall off, thereby improving the stability of the structure's installation. Additionally, the torsion spring is easy to install. A limit slot is provided on the yarn nozzle holder, which limits the maximum travel of the left swing arm and the right swing arm. The limit slot is a V-shaped groove provided on the rear side of the yarn nozzle holder. The left swing arm and the right swing arm can only move within the limit slot, restricting the highest position of the left swing arm and the right swing arm. Both the lower and upper moving devices use U-shaped bearings or rollers with U-shaped grooves. The U-shaped bearings or rollers are clamped with the upper and lower guide rails, increasing stability during movement, reducing shaking, and the rolling fit enhances smooth operation. Both ends of the yarn nozzle holder are connected with belt clamping blocks, which are connected to the belt through the belt clamping blocks. The end of the yarn nozzle frame is provided with a drive motor that drives the belt to rotate. The operation of the drive motor drives the belt to rotate, thereby achieving the reciprocating movement of the yarn nozzle holder.
Referring to
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According to some embodiments of the present application, optionally, each adjacent second angle 8022 is consistent. The present application utilizes a movable yarn nozzle to weave on the base fabric 70. The movable yarn nozzle can swing in any direction such as forward, backward, left, right, up, and down, and always maintains each adjacent second angle 8022 consistent, making the texture structure 80 smoother.
According to some embodiments of the present application, optionally, the size of each adjacent second angle 8022 is inconsistent. The present application utilizes a movable yarn nozzle to weave on the base fabric 70. The movable yarn nozzle can swing in any direction such as forward, backward, left, right, up, and down, and always maintains the size of each adjacent second angle 8022 inconsistent, making the texture structure 80 more diverse.
Referring to
Referring to
According to some embodiments of the present application, optionally, the colors of every two adjacent threads 801 are different. The present application can make the colors of every two adjacent threads 801 different by replacing different movable yarn nozzles, making the color of the texture structure 80 more diverse.
According to some embodiments of the present application, optionally, the threads 801 are woven from multiple yarns. The present application can weave threads 801 by moving the yarn nozzle carrying multiple yarns, thereby adjusting the thickness of the threads 801, enabling the texture structure 80 to achieve different raised structures.
According to some embodiments of the present application, optionally, the texture structure 80 is hidden and/or exposed woven on the base fabric 70. The texture structure 80 of the present application can be hidden within the base fabric 70, can be exposed outside the base fabric 70, or can be partially hidden and partially exposed, thereby achieving different visual effects and structural stability.
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Optionally, the warp structure 100 may be a straight warp structure 100, a bent warp structure 100, or a scattered warp structure 100.
Optionally, the warp structure 100 may be a combination of a straight warp structure 100 and a bent warp structure 100.
Optionally, the warp structure 100 may be a combination of a straight warp structure 100 and a scattered warp structure 100.
Optionally, the warp structure 100 is a combination of the bent warp structure 100 and the scattered warp structure 100.
According to some embodiments of the present application, optionally, the warp structure 100 is woven into the surface layer and/or the inner layer of the Flyknit fabric body 90.
Optionally, the warp structure 100 is woven into the surface layer of the Flyknit fabric body 90.
Optionally, the warp structure 100 is woven into the inner layer of the Flyknit fabric body 90.
Optionally, the warp structure 100 is woven into both the surface layer and the inner layer of the Flyknit fabric body 90.
According to some embodiments of the present application, optionally, the warp structure 100 is integrally woven with the Flyknit fabric body 90 through inlay, float thread, loop formation, tuck stitch, or needle-turn weaving methods.
Optionally, the warp structure 100 is integrally woven with the Flyknit fabric body 90 by inlaying. The present application uses a movable yarn nozzle to feed yarn in the warp direction of the Flyknit fabric body 90 and weaves the warp yarn into the surface layer and/or inner layer of the Flyknit fabric body 90 by inlaying, forming a warp structure 100 with an inlay effect.
Optionally, the warp structure 100 is integrally woven with the Flyknit fabric body 90 by floating. The present application uses a movable yarn nozzle to feed yarn in the warp direction of the Flyknit fabric body 90 and weaves the warp yarn into the surface layer and/or inner layer of the Flyknit fabric body 90 by floating, forming a warp structure 100 with a floating effect.
Optionally, the warp structure 100 is integrally woven with the Flyknit fabric body 90 through loop formation. The present application uses a movable yarn nozzle to feed yarn in the warp direction of the Flyknit fabric body 90 and weaves the warp yarn into the surface layer and/or inner layer of the Flyknit fabric body 90 through loop formation, making the connection between the warp structure 100 and the Flyknit fabric body 90 more stable and firm.
Optionally, the warp structure 100 is integrally woven with the Flyknit fabric body 90 through needle-turn weaving. The present application uses a movable yarn nozzle to feed yarn in the warp direction of the Flyknit fabric body 90 and weaves the warp yarn into the Flyknit fabric body 90 through needle-turn weaving, allowing the warp structure 100 to be laid out on the front and back surface layers of the Flyknit fabric body 90.
According to some embodiments of the present application, optionally, the warp structure 100 comprises several warp stripes 1001, which are parallel and/or intersecting with each other.
Optionally, the warp stripes 1001 are parallel to each other, thereby forming a warp structure 100 with a sense of regularity.
Optionally, the warp stripes 1001 intersect with each other, thereby forming a warp structure 100 with a sense of richness.
Optionally, some of the warp stripes 1001 are parallel to each other, and some intersect with each other, thereby forming a warp structure 100 that combines a sense of regularity and richness.
According to some embodiments of the present application, optionally, the color of the warp structure 100 is different from the color of the Flyknit fabric body 90.
According to some embodiments of the present application, optionally, the Flyknit fabric body 90 is single-layered, double-layered, or multi-layered.
According to some embodiments of the present application, the present application provides a weaving process for a Flyknit fabric with a warp structure 100, comprising the following steps:
According to some embodiments of the present application, optionally, it also comprises a fixed weaving between the introducing weaving and fabric weaving, and a movable weaving between fabric weaving and the lead-out weaving. The fixed weaving is to perform tuck weaving on the flying woven fabric during weaving, which serves to fix the warp yarns in the parked position to prevent sliding of the warp yarns during subsequent movements. Movable weaving is to perform moving weaving on the warp yarn during weaving, which serves to form a warp-directional curved bend on the Flyknit fabric body 90.
According to some embodiments of the present application, optionally, during fabric weaving, each adjacent two fabric weaving operations need to be offset by one needle position. The specific weaving process is as follows:
Set A, B, and C yarns as inlaid warp yarns, and D, E yarns as TPU.
The 1st and 2nd weaving rows are the yarn introducing actions to bring the A yarn into the weaving position, the 3rd and 4th weaving rows are the yarn introducing actions to bring the B yarn into the weaving position, and the 5th and 6th weaving rows are the yarn introducing actions to bring the C yarn into the weaving position,
The 7th weaving row is where the D yarn performs base weaving at the left and right edges, and face weaving in the middle with tight base stitches and face weaving with needle spacing.
The 8th row is woven with E yarn as the base.
The 9th row involves the yarn introducing action to bring A yarn out of the weaving position, the 10th row involves the yarn introducing action to bring B yarn out of the weaving position, and the 11th row involves the yarn introducing action to bring C yarn out of the weaving position.
The 12th row involves D yarn weaving as the base on the left and right edges, with the middle part weaving a tight tuck stitch as the base and alternating stitches for the face, offset by one needle position from the 7th row.
The 13th row is woven with E yarn as the base.
The 14th row is woven with D yarn as the base, the 15th row is woven with E yarn as the base, and the 16th and 17th rows are repetitions of the 14th and 15th rows.
The 18th and 19th rows involve the yarn introducing action to bring yarn A into the weaving position, the 20th and 21st rows involve the yarn introducing action to bring yarn B into the weaving position, and the 22nd and 23rd rows involve the yarn introducing action to bring yarn C into the weaving position.
The 24th row involves yarn D performing base weaving at the left and right edges, and face weaving with tight bottom loops and alternating stitches in the middle.
The 25th row involves yarn E performing base weaving.
The 26th row involves the yarn introducing action to bring yarn A out of the weaving position, the 27th row involves the yarn introducing action to bring yarn B out of the weaving position, and the 28th row involves the yarn introducing action to bring yarn C out of the weaving position.
The 29th weaving row involves D yarn doing base knitting at the left and right edges, and face knitting in the middle with tight bottom loops and face knitting separated by one needle position, offset by one needle position from the 24th weaving row.
The 30th weaving row involves E yarn doing base knitting, the 31st weaving row involves D yarn doing base knitting, the 32nd weaving row involves E yarn doing base knitting, the 33rd weaving row involves D yarn doing base knitting, and the 34th weaving row involves E yarn doing base knitting.
The 35th and 36th weaving rows involve bringing A yarn into the weaving position with the yarn introducing action, the 37th and 38th weaving rows involve bringing B yarn into the weaving position with the yarn introducing action, and the 39th and 40th weaving rows involve bringing C yarn into the weaving position with the yarn introducing action.
The 41st row is D yarn doing base weaving at the left and right edges, and face weaving in the middle with tight base stitches and alternating face stitches.
The 42nd row is E yarn doing base weaving.
The 43rd row is the yarn introducing action to bring A yarn out of the weaving position, the 44th row is the yarn introducing action to bring B yarn out of the weaving position, and the 45th row is the yarn introducing action to bring C yarn out of the weaving position.
The 46th row is D yarn doing base weaving at the left and right edges, and face weaving in the middle with tight base stitches and alternating face stitches, offset by one needle position from the 41 st row.
The 47th row is woven with E yarn as the base, the 48th row is woven with D yarn as the base, the 49th row is woven with E yarn as the base, the 50th row is woven with D yarn as the base, the 51st row is woven with E yarn as the base,
The 52nd and 53rd rows involve guiding A yarn into the weaving position, the 54th and 55th rows involve guiding B yarn into the weaving position, the 56th and 57th rows involve guiding C yarn into the weaving position,
The 58th row involves D yarn weaving the base at the left and right edges, and weaving the face in the middle with tight loops and alternating stitches between the base and face weaving,
The 59th row is base weaving with E yarn,
The 60th row involves the yarn introducing action to bring A yarn out of the weaving position, the 61 st row involves the yarn introducing action to bring B yarn out of the weaving position, the 62nd row involves the yarn introducing action to bring C yarn out of the weaving position,
The 63rd row involves D yarn doing base weaving at the left and right edges, and face weaving with tight tuck stitches and alternating stitches in the middle, offset by one needle position from the 58th row,
The 64th row is base weaving with E yarn, the 65th row is base weaving with D yarn, the 66th row is base weaving with E yarn, the 67th row is base weaving with D yarn, the 68th row is base weaving with E yarn.
Referring to
The warp structure 100 is formed by weaving with movable yarn nozzle along the warp direction of the Flyknit fabric body 90, creating a straight warp structure 100 without the need for the movable yarn nozzle to perform a yarn kicking avoidance action during weaving.
The warp structure 100 is woven into the surface layer and/or inner layer of the Flyknit fabric body 90.
The warp structure 100 is woven into the surface layer and/or inner layer of the Flyknit fabric body 90 through inlay, float thread, loop formation, tuck stitch, or needle-turn weaving methods.
Referring to
The warp structure 100 is formed by the movable yarn nozzle weaving the yarn in the warp direction of the Flyknit fabric body 90, creating a bent warp structure 100, and the movable yarn nozzle does not need to perform a yarn kicking avoidance action during the weaving process.
The warp structure 100 is woven into the surface layer and/or inner layer of the Flyknit fabric body 90.
The warp structure 100 is woven into the surface layer and/or inner layer of the Flyknit fabric body 90 through inlay, float thread, loop formation, tuck stitch, or needle-turn weaving methods.
Referring to
The warp structure 100 is formed by the movable yarn nozzle weaving the yarn in the warp direction of the Flyknit fabric body 90, creating a scattered warp structure 100, and the movable yarn nozzle does not need to perform a yarn kicking avoidance action during the weaving process.
The warp structure 100 is woven into the surface layer and/or inner layer of the Flyknit fabric body 90.
The warp structure 100 is woven into the surface layer and/or inner layer of the Flyknit fabric body 90 through inlay, float thread, loop formation, tuck stitch, or needle-turn weaving methods.
Referring to
The warp structure 100 is formed by the movable yarn nozzle weaving the yarn in the warp direction of the Flyknit fabric body 90, creating a combination of straight and bent warp structures 100, and the movable yarn nozzle does not need to perform a yarn kicking avoidance action during the weaving process.
The warp structure 100 is woven into the surface layer and/or inner layer of the Flyknit fabric body 90.
The warp structure 100 is woven into the surface layer and/or inner layer of the Flyknit fabric body 90 through inlay, float thread, loop formation, tuck stitch, or needle-turn weaving methods.
This embodiment provides a Flyknit fabric with a warp structure 100. The Flyknit fabric comprises a Flyknit fabric body 90 and a warp structure 100 integrally woven with the Flyknit fabric body 90.
The warp structure 100 is formed by multiple yarn nozzles weaving the yarn in the warp direction of the Flyknit fabric body 90, creating a straight warp structure 100, and the movable yarn nozzle does not need to perform a yarn kicking avoidance action during the weaving process.
The warp structure 100 is woven into the Flyknit fabric body 90 by inlaying.
Referring to
In
The 1st weaving row involves the yarn introducing action to bring yarn A to the weaving position,
The 2nd weaving row involves the yarn introducing action to bring yarn B to the weaving position,
The 3rd weaving row involves the yarn introducing action to bring yarn C to the weaving position,
After reaching the designated positions, yarns A, B, and C are fixed and parked,
The 4th weaving row involves yarn D performing base weaving and tuck stitch weaving,
The 5th weaving row is E yarn base knitting and tuck stitch knitting,
The 6th-27th weaving rows are repetitions of the 4th-5th weaving rows,
When the D and E yarn nozzles encounter the parked positions of the A, B, and C yarn nozzles during knitting, they do not perform the yarn nozzle kicking action to avoid them,
The 28th weaving row involves the yarn guiding action to bring the A yarn into the knitting position,
The 29th weaving row involves the yarn guiding action to bring the B yarn into the knitting position,
The 30th weaving row involves the yarn guiding action to bring the C yarn into the knitting position.
This embodiment provides a Flyknit fabric with a warp structure 100. The Flyknit fabric comprises a Flyknit fabric body 90 and a warp structure 100 integrally woven with the Flyknit fabric body 90.
The warp structure 100 is formed by multiple yarn nozzles weaving in the warp direction of the Flyknit fabric body 90, creating a bent warp structure 100, and the movable yarn nozzles do not need to perform the yarn kicking avoidance action during yarn weaving.
The warp structure 100 is woven into the inner layer of the Flyknit fabric body 90 by inlaying.
Referring to
In
The 1st weaving row involves the yarn introducing action to bring yarn A to the weaving position,
The 2nd weaving row involves the yarn introducing action to bring the yarn B to the weaving position,
The 3rd weaving row involves the yarn introducing action to bring yarn C to the weaving position,
The 4th weaving row is where yarn D performs face knitting with tight tuck stitches and empty needle spacing stitches, serving to fix the warp yarns in the parked position to prevent sliding when the warp yarns move subsequently,
The 5th weaving row is E yarn base knitting and tuck stitch knitting,
The 6th weaving row is where yarn D performs face knitting with empty needle spacing stitches,
The 7th weaving row is where yarn E performs bottom knitting with empty needle spacing stitches,
Rows 8-11 are a repeat of rows 6-7,
Row 12 involves yarn A moving to create a float thread with a tuck stitch,
Row 13 involves yarn B moving to create a float thread with a tuck stitch,
Row 14 involves yarn C moving to create a float thread with a tuck stitch,
Rows 15-22 follow the same weaving actions as rows 4-11,
Row 23 involves yarn A moving to create a float thread with a tuck stitch,
Row 24 involves yarn B moving to create a float thread with a tuck stitch,
Row 25 involves yarn C moving to create a float thread with a tuck stitch,
The warp yarn movements in rows 12-14 and rows 23-25 form warp-directional curved threads on the Flyknit fabric,
The weaving actions of rows 26-33 are consistent with those of rows 4-11,
Row 34 involves a yarn introducing action to bring yarn A out of the weaving position,
Row 35 involves a yarn introducing action to bring yarn B out of the weaving position,
Row 36 involves a yarn introducing action to bring yarn C out of the weaving position.
This embodiment provides a Flyknit fabric with a warp structure 100. The Flyknit fabric comprises a Flyknit fabric body 90 and a warp structure 100 integrally woven with the Flyknit fabric body 90.
The warp structure 100 is formed by multiple yarn nozzles weaving yarn in the warp direction of the Flyknit fabric body 90, creating a scattered warp structure 100, and the movable yarn nozzle does not need to perform a yarn kicking avoidance action during the weaving process.
The warp structure 100 is woven into the inner layer of the Flyknit fabric body 90 by inlaying.
Referring to
In
The 1st and 2nd weaving rows involve the yarn guiding action to bring yarn A into the weaving position,
The 3rd and 4th weaving rows involve the yarn guiding action to bring yarn B into the weaving position,
The 5th and 6th weaving rows involve the yarn guiding action to bring yarn C into the weaving position,
The 7th weaving row is where the D yarn performs base weaving at the left and right edges, and face weaving in the middle with tight base stitches and face weaving with needle spacing.
The 8th row is woven with E yarn as the base.
The 9th weaving row involves the yarn guiding action to bring yarn A out of the weaving position,
The 10th weaving row involves the yarn guiding action to bring yarn B out of the weaving position,
The 11th weaving row involves the yarn guiding action to bring yarn C out of the weaving position,
The 12th row involves D yarn weaving as the base on the left and right edges, with the middle part weaving a tight tuck stitch as the base and alternating stitches for the face, offset by one needle position from the 7th row.
The 13th row is woven with E yarn as the base.
The 14th weaving row involves yarn D as the base weaving,
The 15th row is woven with E yarn as the base.
The 16th and 17th rows are repetitions of the 14th and 15th rows.
The 18th and 19th rows involve guiding A yarn into the weaving position.
The 20th and 21st rows involve guiding B yarn into the weaving position.
The 22nd and 23rd rows involve guiding C yarn into the weaving position.
The 24th row involves yarn D performing base weaving at the left and right edges, and face weaving with tight bottom loops and alternating stitches in the middle.
The 25th row involves yarn E performing base weaving.
The 26th row involves guiding A yarn out of the weaving position.
The 27th row involves guiding B yarn out of the weaving position.
The 28th row involves guiding C yarn out of the weaving position.
The 29th weaving row involves D yarn doing base knitting at the left and right edges, and face knitting in the middle with tight bottom loops and face knitting separated by one needle position, offset by one needle position from the 24th weaving row.
The 30th row is woven with E yarn as the base.
The 31st row is woven with D yarn as the base.
The 32nd row is woven with E yarn as the base.
The 33rd row is woven with D yarn as the base.
The 34th row is woven with E yarn as the base.
The 35th and 36th rows involve guiding A yarn into the weaving position.
The 37th and 38th rows involve guiding B yarn into the weaving position.
The 39th and 40th rows involve guiding C yarn into the weaving position.
The 41st row is D yarn doing base weaving at the left and right edges, and face weaving in the middle with tight base stitches and alternating face stitches.
The 42nd row is E yarn doing base weaving.
The 43rd row involves guiding A yarn out of the weaving position.
The 44th row involves guiding B yarn out of the weaving position.
The 45th weaving row is the yarn introducing action to bring the C yarn out of the weaving position,
The 46th row is D yarn doing base weaving at the left and right edges, and face weaving in the middle with tight base stitches and alternating face stitches, offset by one needle position from the 41st row.
The 47th weaving row is the base weaving with E yarn,
The 48th weaving row is the base weaving with D yarn,
The 49th weaving row is the base weaving with E yarn,
The 50th weaving row is the base weaving with D yarn,
The 51st weaving row is the base weaving with E yarn,
The 52nd and 53rd weaving rows are the yarn introducing actions to bring the A yarn into the weaving position,
The 54th and 55th weaving rows are the yarn introducing actions to bring the B yarn into the weaving position,
The 56th and 57th weaving rows are the yarn introducing actions to bring the C yarn into the weaving position,
The 58th row involves D yarn weaving the base at the left and right edges, and weaving the face in the middle with tight loops and alternating stitches between the base and face weaving,
The 59th row is base weaving with E yarn,
The 60th weaving row is the yarn introducing action to bring the A yarn out of the weaving position,
The 61st weaving row involves the yarn guiding action to bring yarn B out of the weaving position,
The 62nd weaving row involves the yarn guiding action to bring yarn C out of the weaving position,
The 63rd row involves D yarn doing base weaving at the left and right edges, and face weaving with tight tuck stitches and alternating stitches in the middle, offset by one needle position from the 58th row,
The 64th weaving row involves using yarn E for base weaving,
The 65th weaving row involves using yarn D for base weaving,
The 66th weaving row involves using yarn E for base weaving,
The 67th weaving row involves using yarn D for base weaving,
The 68th weaving row involves using yarn E for base weaving.
This embodiment provides a Flyknit fabric with a warp structure 100. The Flyknit fabric comprises a Flyknit fabric body 90 and a warp structure 100 integrally woven with the Flyknit fabric body 90.
The warp structure 100 is formed by multi-head yarn nozzles weaving in the warp direction of the Flyknit fabric body 90, creating a combination of straight and bent warp structures 100, and the movable yarn nozzles do not need to perform a yarn avoidance action during the yarn release and weaving process.
The warp structure 100 is woven into the Flyknit fabric body 90 by inlaying.
Refer to
In
The first weaving row involves the yarn introducing action to bring yarn A to the weaving position,
The second weaving row involves the yarn introducing action to bring yarn B to the weaving position,
The 3rd and 4th weaving rows involve the yarn introducing action to bring yarn C to the weaving position,
Yarns A and B are fixed and parked after reaching the designated position,
The 5th weaving row involves yarn D performing base weaving and tuck stitch weaving,
The 6th weaving row involves yarn E performing base weaving and tuck stitch weaving,
The 7th to 10th weaving rows are repetitions of the 5th and 6th weaving rows,
The 11th weaving row involves yarn C moving to perform tuck stitch float thread weaving,
Rows 12-17 are a repeat of rows 5-10,
Row 18 involves C yarn moving to create a float thread with empty stitches,
Rows 19-24 are a repeat of rows 12-17,
Row 25 involves yarn C moving to create a float thread with a tuck stitch, Rows 26-31 are a repeat of rows 19-24,
Row 32 involves the yarn introducing action to bring C yarn out of the weaving position,
Row 33 involves the yarn introducing action to bring B yarn out of the weaving position,
Row 34 involves the yarn introducing action to bring A yarn out of the weaving position.
This embodiment provides a Flyknit fabric with a warp structure 100. The Flyknit fabric comprises a Flyknit fabric body 90 and a warp structure 100 integrally woven with the Flyknit fabric body 90.
The warp structure 100 is formed by multi-head yarn nozzles weaving in the warp direction of the Flyknit fabric body 90, creating a combination of straight and bent warp structures 100, and the movable yarn nozzles do not need to perform a yarn avoidance action during the yarn release and weaving process.
The warp structure 100 is woven into the inner layer of the Flyknit fabric body 90 by inlaying.
Referring to
In
The 1st weaving row involves the yarn introducing action to bring yarn A to the weaving position,
The 2nd weaving row involves the yarn introducing action to bring yarn B to the weaving position,
The 3rd and 4th weaving rows involve the yarn introducing action to bring yarn C to the weaving position,
Yarns A and B are fixed and parked after reaching the designated position,
In the 5th weaving row, yarn D is used for face weaving,
In the 6th weaving row, yarn E is used for bottom weaving and bottom weaving with tight tuck stitch and skip stitch,
In the 7th weaving row, yarn D is used for face weaving,
In the 8th weaving row, yarn E is used for bottom weaving and bottom weaving with tight tuck stitch and skip stitch, offset by one needle position from the 6th row,
The 9th and 10th weaving rows have the same weaving action as the 5th and 6th rows,
The 11th weaving row involves yarn C moving to perform tuck stitch float thread weaving,
The 12th and 13th weaving rows have the same weaving action as the 7th and 8th rows,
The weaving action of rows 14-17 is consistent with that of rows 5-8,
Row 18 involves C yarn moving to create a float thread with empty stitches,
The weaving action of rows 19-31 is consistent with that of rows 5-17,
Row 32 involves the yarn introducing action to bring C yarn out of the weaving position,
Row 33 involves the yarn introducing action to bring B yarn out of the weaving position,
Row 34 involves the yarn introducing action to bring A yarn out of the weaving position.
It should be understood that the embodiments disclosed in the present application are not limited to the specific processing steps or materials disclosed herein, but should extend to equivalent substitutions of such features understood by those skilled in the relevant art. It should also be understood that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting.
The term ‘embodiment’ as used in the specification means that a particular feature, or characteristic described in connection with the embodiment is included in at least one embodiment of the present application. Therefore, the phrases or ‘embodiment’ appearing throughout the specification do not necessarily refer to the same embodiment.
Additionally, the described features or characteristics can be combined into one or more embodiments in any other suitable manner. In the above description, specific details such as thickness, quantity, etc., are provided to give a comprehensive understanding of the embodiments of the present application. However, those skilled in the relevant art will understand that the present application can be implemented without the above specific details or can be implemented using other methods, components, materials, etc.,
| Number | Date | Country | |
|---|---|---|---|
| Parent | PCT/CN2023/126782 | Oct 2023 | WO |
| Child | 18937920 | US |
