阅读说明：本技术 一种用于智能服装的编织成型的弹性导电线及编织工艺 (Elastic conductive wire for knitting forming of intelligent clothes and knitting process ) 是由 颜韶峰 于 2020-12-21 设计创作，主要内容包括：本发明公开了智能服装导电线材领域中的一种编织成型的弹性导电线及编织工艺,该用于智能服装的编织成型的弹性导电线包括若干可拉伸并回弹的弹线及呈S形回旋排列的电源线,电源线往返穿插于弹线中,并与弹线编织固定形成扁平状的弹性导电线；编织工艺包括了排列弹线以及在弹线中往返穿插电源线的过程。本发明克服了现阶段智能服装领域中导电线材没有弹性,而具有弹性的导电线材无法植入服装中,或是植入服装后异物感强、不舒适的缺陷,本发明具有良好的伸缩率,且产品的阻值较低,另外,本发明的整条弹性导电线的受力更加分散,充分保护了电源线不易受损,且编织方式加工速度快,产品生产效率高。(The invention discloses a knitted elastic conductive wire and a knitting process in the field of conductive wires of intelligent clothing, wherein the knitted elastic conductive wire for the intelligent clothing comprises a plurality of stretchable and rebounding elastic wires and power wires which are arranged in an S-shaped convolution manner, and the power wires are inserted into the elastic wires back and forth and are knitted and fixed with the elastic wires to form flat elastic conductive wires; the weaving process includes the process of arranging the elastic thread and inserting the power line in the elastic thread back and forth. The elastic conductive wire overcomes the defects that the conductive wire is not elastic and cannot be implanted into the clothes in the field of intelligent clothes at the present stage, or foreign bodies are strong and uncomfortable after the conductive wire is implanted into the clothes.)

1. A woven shaped elastic conductive thread for smart apparel comprising:

a plurality of elastic lines which can stretch and rebound, wherein the elastic lines are arranged in parallel;

and the power line is arranged in an S-shaped convolution way, is inserted in the elastic wire in a reciprocating way and is woven and fixed with the elastic wire to form a flat elastic conductive wire.

2. The woven elastic conductive thread for smart garments as claimed in claim 1, wherein said power cord is passed through said elastic thread in a forward direction and then in a reverse direction within a convolution period of said power cord.

3. The woven elastic conductive thread for smart clothing according to claim 1, wherein the power cord comprises a first power cord and a second power cord, and the first power cord and the second power cord are distributed side by side from left to right.

4. The woven elastic conductive thread for smart clothing as claimed in claim 1, wherein during a convolution cycle of the power cord, the power cord repeatedly passes through two adjacent elastic threads in a forward direction and then repeatedly passes through two adjacent elastic threads in a reverse direction.

5. The knitted elastic conductive wire for intelligent clothing according to claim 4, further comprising a plurality of parallel knitted wires, wherein the knitted wires are arranged in an S-shaped convolution manner, and repeatedly pass through two adjacent elastic wires and fix the power line on the elastic wires.

6. A knitting process of the knitted elastic conductive thread for smart clothes according to any one of claims 1 to 3, wherein a plurality of elastic strands are knitted into an elastic thread, and during the knitting process, a power supply wire is repeatedly and convolutely inserted into the elastic strand being knitted.

7. The knitting process of the knitted elastic conductive thread for smart garments as claimed in claim 6, wherein the power cord comprises two power cords, one power cord is inserted between the elastic strands during the knitting process, and the other power cord is inserted between the elastic strands in the same direction after the elastic strands are knitted for a distance.

8. A knitting process of the knitted elastic conductive wire for intelligent clothes according to any one of claims 1 to 3, characterized in that a plurality of strands of elastic strands are respectively knitted into a first elastic wire, a second elastic wire and a third elastic wire, and during the knitting process, the first power wire is repeatedly and convolutely inserted into the first elastic wire and the second elastic wire being knitted, and the second power wire is repeatedly and convolutely inserted into the second elastic wire and the third elastic wire being knitted.

9. The knitting process of the elastic conductive thread for smart garment knitting as claimed in claim 1, 2, 4 or 5, characterized in that a plurality of parallel elastic threads are formed in parallel, a first power cord is inserted between two adjacent elastic threads in a forward direction and repeatedly rotated, and a second power cord is inserted between two adjacent elastic threads in a reverse direction and repeatedly rotated.

10. The knitting process of the elastic conductive thread for smart garment knitting molding as claimed in claim 9, further comprising a knitting process of a forward knitting thread and a knitting process of a reverse knitting thread:

after the first power line is inserted in the forward direction, the forward braided wire is inserted between every two adjacent elastic wires in the forward direction, and after the first power line is rotated back, the forward braided wire is inserted between every two adjacent elastic wires in the reverse direction;

and after the second power line is rotated, the reverse braided wire is inserted between every two adjacent elastic wires in the forward direction.

Technical Field

The invention relates to the field of conductive wires of intelligent clothing, in particular to an elastic conductive wire for knitting and forming of intelligent clothing and a knitting process.

Background

With the development of the electronic industry, intelligent design is applied to various industries, wherein structures such as a signal acquisition device and an auxiliary electrode are added in an intelligent garment to become a mainstream product of the intelligent garment, however, no matter what kind of functional products, circuit wiring needs to be carried out inside the intelligent garment, and thus a structure of a conductive wire needs to be added. Traditional electric wire includes electric core and is located electric core outlying insulating layer, and electric core and insulating layer do not all possess tensile ability, and after it was applied to intelligent clothing, clothing itself probably stretched or compressed when different posture, motion, and the electric wire that does not have tensile ability probably takes place damage, electric leakage, even fracture and the unable condition of using.

In order to solve this problem, it is conventional to add an elastic structure to the existing power line, or to directly arrange the power line in a spiral shape, so as to increase the stretching ability. However, the production speed of the electric wire with the structure is low, the product cost is high, in addition, the telescopic rate of the power line with the structure is low, the electric wire cannot be well used in occasions with large deformation, such as intelligent clothes, and the like, and the resistance value of the electric wire is high (up to 40 omega/m), so that the line loss of the product is large, and the spreading and application of the electric wire are not facilitated.

The above-mentioned drawbacks are worth solving.

Disclosure of Invention

In order to overcome the defects of the prior art, the invention provides an elastic conductive wire for knitting and forming intelligent clothing and a knitting process.

The technical scheme of the invention is as follows:

a woven shaped elastic conductive thread for smart apparel comprising:

a plurality of elastic lines which can stretch and rebound, wherein the elastic lines are arranged in parallel;

and the power line is arranged in an S-shaped convolution way, is inserted in the elastic wire in a reciprocating way and is woven and fixed with the elastic wire to form a flat elastic conductive wire.

The invention according to the above scheme is characterized in that in a convolution period of the power line, the power line passes through the elastic line in a forward direction and then passes through the elastic line in a reverse direction.

The invention according to the above aspect is characterized in that the power line includes a first power line and a second power line, and the first power line and the second power line are distributed side by side in the left-right direction.

The invention according to the above aspect is characterized in that, in a convolution period of the power line, the power line repeatedly passes through two adjacent snapping lines in a forward direction and then repeatedly passes through two adjacent snapping lines in a reverse direction.

The power cord is characterized by further comprising a plurality of braided wires which are arranged in parallel, the braided wires are arranged in an S-shaped convolution mode, the braided wires repeatedly penetrate through two adjacent elastic wires, and the power cord is fixed on the elastic wires.

The invention also provides a knitting process of the elastic conductive wire for intelligent clothing knitting molding.

A weaving process of a woven elastic conductive wire for intelligent clothes is characterized in that a plurality of strands of elastic strands are woven into elastic wires, and in the weaving process, power wires are repeatedly and convolutely inserted into the elastic strands being woven.

The invention according to the above scheme is characterized in that the power cord comprises two power cords, one power cord is inserted between the elastic strands during the knitting process, and the other power cord is inserted between the elastic strands in the same direction after the elastic strands are knitted for a certain distance.

A weaving process of a woven elastic conductor wire for intelligent clothes is characterized in that a plurality of strands of elastic strand wires are respectively woven into a first elastic wire, a second elastic wire and a third elastic wire, in the weaving process, a first power wire is repeatedly and convolutely inserted into the first elastic wire and the second elastic wire which are being woven, and a second power wire is repeatedly and convolutely inserted into the second elastic wire and the third elastic wire which are being woven.

A weaving process of an elastic conductive wire for intelligent clothing weaving forming is characterized by comprising the following steps:

the power supply lines are arranged to form a plurality of parallel elastic lines, the first power supply line is inserted between every two adjacent elastic lines in a forward penetrating and repeatedly circling manner, and the second power supply line is inserted between every two adjacent elastic lines in a reverse penetrating and repeatedly circling manner.

The invention according to the above aspect is characterized by further comprising a knitting process of the forward knitting yarn and a knitting process of the reverse knitting yarn:

after the first power line is inserted in the forward direction, the forward braided wire is inserted between every two adjacent elastic wires in the forward direction, and after the first power line is rotated back, the forward braided wire is inserted between every two adjacent elastic wires in the reverse direction;

and after the second power line is rotated, the reverse braided wire is inserted between every two adjacent elastic wires in the forward direction.

Compared with the traditional electric wire with an elastic structure, the elastic conductive wire has good expansion rate which can reach 50%, and the resistance of the product is low, and the resistance of each meter of elastic conductive wire is only 0.03-0.05 omega; in addition, the power line is fixed in a weaving mode, so that the stress of the whole elastic conductive wire is more dispersed, the power line is fully protected from being damaged, the processing speed of the weaving mode is high, and the production efficiency of the product is high.

Drawings

FIG. 1 is a schematic structural diagram according to a first embodiment of the present invention;

FIG. 2 is a schematic structural diagram according to a second embodiment of the present invention;

fig. 3 is a schematic diagram of a third clockwise routing half-turn according to an embodiment of the present invention;

fig. 4 is a schematic diagram of three counterclockwise routing half-loops according to an embodiment of the present invention;

fig. 5-12 are flow charts of simultaneous clockwise and counterclockwise routing according to a third embodiment of the present invention;

FIG. 13 is a schematic view of one and a half turns of clockwise routing according to the third embodiment of the present invention;

FIG. 14 is a schematic view of one and a half turns of three counter-clockwise routing in accordance with an embodiment of the present invention;

fig. 15 is a schematic diagram of simultaneously routing clockwise and counterclockwise for one and a half turns in the third embodiment of the present invention.

In the figure, 11-first snapping line; 12-a second snapping line; 13-a third snapping line;

21-a first elastic thread; 22-a second elastic thread; 23-a third elastic thread; 24-a fourth elastic thread; 25-a fifth elastic thread; 26-a sixth elastic thread;

101-a first power supply line; 102-a second power supply line;

201-a first forward braided wire; 202-second forward braided wire; 203-third forward braided wire; 204-fourth forward braided wire; 205-fifth forward braided wire;

301-a first reverse braided wire; 302-a second reverse braid; 303-a third reverse braided wire; 304-fourth reverse braided wire; 305-a fifth reverse knit line; 306-sixth reverse braid.

Detailed Description

The invention is further described with reference to the following figures and embodiments:

a woven elastic conductive wire for intelligent clothes comprises a plurality of elastic wires capable of stretching and rebounding and a power wire for conducting electricity. The elastic wires are arranged in parallel to each other, provide a routing channel for the power line and drive the power line to rebound through the resilience force of the elastic wires; the power line is inserted in the elastic wire in a reciprocating way, the power line is arranged in an S-shaped convolution mode to enable the power line to have stretching and rebounding spaces, and the power line and the elastic wire are woven and fixed to form a flat elastic conductive wire.

The power line comprises a first power line and a second power line which are respectively connected with the anode and the cathode of the controller, so that a complete circuit loop is realized. When the elastic conductive wire for the weaving and forming of the intelligent clothes is unfolded in a plane shape, the first power line and the second power line are positioned on the same plane; because the elastic conducting wire for the weaving forming of the intelligent clothes can be bent and deformed, when the elastic conducting wire for the weaving forming of the intelligent clothes is bent at the same latitude, the curved surface where the first power line and the curved surface where the second power line are located at the same latitude have the same curvature; the first power line and the second power line may have different curvatures because the flat elastic conductive wire may be bent at various angles.

The flat elastic conductive wire can be laid in the intelligent clothes, does not cause discomfort of wearing of a human body, and has good extensibility.

Example one

As shown in fig. 1, a woven elastic conductive wire for smart clothing includes a plurality of elastic wires arranged in parallel and a power line arranged in an S-shaped convolution, wherein the power line is inserted into the elastic wires back and forth and is woven and fixed with the elastic wires to form a flat elastic conductive wire. The power cord includes first power cord 101 and second power cord 102, and first power cord 101 distributes with second power cord 102 side by side about for when being used for the fashioned elasticity conducting wire of weaving of intelligent clothing to open up the flat plane, first power cord 101 and second power cord 102 are all parallel in each latitude position.

Specifically, the left to right direction in the figure is taken as the forward direction, and the right to left direction is taken as the reverse direction: in a convolution period of the power line, the power line passes through the elastic thread in the forward direction and then passes through the elastic thread in the reverse direction, so that the elastic thread and the power line are crossed and woven. The elastic thread of this embodiment includes a plurality of strands of elastic strand, weaves each other between the elastic strand and forms the elastic thread, and the power cord passes between the elastic strand after weaving for the elastic thread can be with the power cord weave including and fix. Preferably, the elastic strands which can be three strands or four strands or five strands are mutually woven to form a braid shape, so that not only can a space for the power cord to pass through be provided, but also the elastic strands have good elasticity, and the elastic wire structure is firmer and is not easy to damage.

In this embodiment, the elastic threads include a first elastic thread 11, a second elastic thread 12 and a third elastic thread 13, and the first elastic thread 11, the second elastic thread 12 and the third elastic thread 13 are respectively stranded and arranged in parallel to form three rows. In the process of extending along the elastic thread from bottom to top, the first power line 101 and the second power line 102 are routed in an S-shape and are inserted into the elastic strands of each elastic thread: in a convolution period of the first power line 101, the first power line 101 sequentially passes through the first elastic line 11, the second elastic line 12 and the third elastic line 13 in a forward direction, and then sequentially passes through the third elastic line 13, the second elastic line 12 and the first elastic line 11 in a reverse direction; in a convolution period of the second power line 102, the second power line 102 sequentially passes through the first elastic line 11, the second elastic line 12 and the third elastic line 13 in a forward direction, and sequentially passes through the third elastic line 13, the second elastic line 12 and the first elastic line 11 in a reverse direction, and the second power line 102 is always located on the right side of the first power line 101.

According to the knitting process of the elastic conductive wire for knitting the intelligent clothes, a plurality of strands of elastic strands are knitted into elastic wires, and in the knitting process, power wires are repeatedly and convolutely inserted into the elastic strands being knitted. The power cord comprises a first power cord 101 and a second power cord 102, one power cord (such as the first power cord 101) is inserted between the elastic strands in the weaving process, and the other power cord (such as the second power cord 102) is inserted between the elastic strands in the same direction after the elastic strands are woven for a certain distance.

The method specifically comprises the following steps:

s11, weaving a plurality of strands of elastic strands into elastic threads.

Specifically, the first elastic thread 11, the second elastic thread 12, and the third elastic thread 13 are respectively formed by weaving a plurality of elastic strands.

And S12, weaving the elastic strands for a certain distance, and obliquely inserting the power supply wire between the elastic strands. Specifically, the method comprises the following steps:

s121, weaving a first elastic thread 11, a second elastic thread 12 and a third elastic thread 13 for a certain distance respectively, preferably, the length of the woven first elastic thread 11 is smaller than that of the second elastic thread 12, and the length of the woven second elastic thread 12 is smaller than that of the third elastic thread 13;

s122, inserting the second power line 102 between the multiple elastic strands of the first elastic thread 11 in the forward direction, then inserting the second power line 102 between the multiple elastic strands of the second elastic thread 12 in the forward direction, and then inserting the third elastic thread 13 between the multiple elastic strands in the forward direction;

s123, knitting the first elastic thread 11, the second elastic thread 12 and the third elastic thread 13 for a certain distance, respectively, so that the second power cord 102 is fixed, preferably, the length of the knitted first elastic thread 11 is equal to (may be different in other embodiments) the length of the second elastic thread 12 and the length of the third elastic thread 13;

s124, the first power line 101 is inserted between the elastic strands of the first elastic thread 11, the second elastic thread 12, and the third elastic thread 13 in the forward direction.

S13, the knitting is continued to form the elastic threads so that the first power supply wire 101 is fixed between the elastic strands of the respective elastic threads.

And S14, after weaving the elastic strands for a certain distance, reversely and obliquely inserting the power supply wires among the elastic strands. Specifically, the method comprises the following steps:

s141, knitting the first elastic thread 11, the second elastic thread 12 and the third elastic thread 13 for a certain distance, preferably, the length of the knitted first elastic thread 11 is greater than the length of the second elastic thread 12, and the length of the knitted second elastic thread 12 is greater than the length of the third elastic thread 13;

s142, reversely inserting the first power line 101 into the space between the multiple elastic strands of the third elastic thread 13, then forwardly inserting the first power line 101 into the space between the multiple elastic strands of the second elastic thread 12, and then forwardly inserting the first power line 11 into the space between the multiple elastic strands;

s143, knitting the first elastic thread 11, the second elastic thread 12, and the third elastic thread 13 for a certain distance, respectively, so that the first power cord 101 is fixed, preferably, the length of the knitted first elastic thread 11 is equal to (or different in other embodiments) the length of the second elastic thread 12, and the length of the third elastic thread 13;

s144, the second power line 102 is inserted between the elastic strands of the third elastic thread 13 in the reverse direction, then inserted between the elastic strands of the second elastic thread 12 in the forward direction, and then inserted between the elastic strands of the first elastic thread 11 in the forward direction.

S15, the knitting is continued to form the elastic threads so that the reversely inserted second power supply wire 102 is fixed between the elastic strands of the respective elastic threads.

And S16, repeating the steps S12 to S14 until the elastic conductive wire with the required length is completed.

In the finally formed elastic conductive lines, the first elastic line 11, the second elastic line 12 and the third elastic line 13 respectively extend vertically, and the first conductive line and the second conductive line respectively have an S-shaped convolution shape.

The elastic conductive wire formed by weaving in the embodiment is applied to an intelligent garment, when the elastic conductive wire is pulled, the first elastic wire 11, the second elastic wire 12 and the third elastic wire 13 simultaneously drive the first power line 101 and the second power line 102 to stretch, and the convolution structures of the first power line 101 and the second power line 102 provide corresponding stretching spaces; when the external force is released, the resilience of the first elastic wire 11, the second elastic wire 12 and the third elastic wire 13 drives the first power line 101 and the second power line 102 to retract to the original shape.

This embodiment disperses tensile force through each bullet line, reduces external force direct action on the power cord, has reduced the damage to the power cord, and this weave structure is more simple and convenient simultaneously, easily processing.

Example two

As shown in fig. 2, a woven elastic conductive wire for smart clothing includes a plurality of elastic wires arranged in parallel and a power line arranged in an S-shaped convolution, wherein the power line is inserted into the elastic wires back and forth and is woven and fixed with the elastic wires to form a flat elastic conductive wire. The power cord includes first power cord 101 and second power cord 102, and first power cord 101 and second power cord 102 control and distribute side by side for when being used for the fashioned elasticity conducting wire of weaving of intelligent clothing to open up the flat plane, the plane that first power cord 101 and second power cord 102 place after S-shaped circles round respectively is the coplanar.

Specifically, the left to right direction in the figure is taken as the forward direction, and the right to left direction is taken as the reverse direction: in a convolution period of the power line, the power line passes through the elastic thread in the forward direction and then passes through the elastic thread in the reverse direction, so that the elastic thread and the power line are crossed and woven. The elastic thread of this embodiment includes a plurality of strands of elastic strand, weaves each other between the elastic strand and forms the elastic thread, and the power cord passes between the elastic strand after weaving for the elastic thread can be with the power cord weave including and fix. Preferably, the elastic strands which can be three strands or four strands or five strands are mutually woven to form a braid shape, so that not only can a space for the power cord to pass through be provided, but also the elastic strands have good elasticity, and the elastic wire structure is firmer and is not easy to damage.

In this embodiment, the elastic threads include a first elastic thread 11, a second elastic thread 12 and a third elastic thread 13, and the first elastic thread 11, the second elastic thread 12 and the third elastic thread 13 are respectively stranded and arranged in parallel to form three rows. In the process of extending along the elastic thread from bottom to top, the first power line 101 and the second power line 102 are routed in an S-shape and are inserted into the elastic strands of each elastic thread:

in a convolution period of the first power line 101, the first power line 101 sequentially passes through the first elastic line 11 and the second elastic line 12 in a forward direction, and then sequentially passes through the second elastic line 12 and the first elastic line 11 in a reverse direction; in a convolution period of the second power line 102, the second power line 102 sequentially passes through the second elastic line 12 and the third elastic line 13 in the forward direction, and sequentially passes through the third elastic line 13 and the second elastic line 12 in the reverse direction, and the second power line 102 is always located on the right side of the first power line 101.

According to the knitting process of the elastic conductive wire for knitting and forming of the intelligent clothes, a plurality of strands of elastic strands are respectively knitted into a first elastic wire 11, a second elastic wire 12 and a third elastic wire 13, in the knitting process, a first power wire 101 is repeatedly and rotatably inserted into the first elastic wire 11 and the second elastic wire 12 which are being knitted, and a second power wire 102 is repeatedly and rotatably inserted into the second elastic wire 12 and the third elastic wire 13 which are being knitted.

The method specifically comprises the following steps:

and S21, weaving a plurality of strands of elastic strands into a first elastic thread 11, a second elastic thread 12 and a third elastic thread 13 respectively.

And S22, inserting the power line in the forward direction for the first time. In particular, the method comprises the following steps of,

s221, respectively weaving elastic strands to form a first elastic thread 11, a second elastic thread 12 and a third elastic thread 13 for a certain distance;

s222, the first power line 101 is inserted between the elastic strands of the first elastic thread 11 in a forward and oblique direction, and the second power line 102 is inserted between the elastic strands of the second elastic thread 12 in a forward and oblique direction.

S23, continuously weaving the elastic strands to form elastic threads, so that the first power cord 101 is fixed on the first elastic thread 11 and the second power cord 102 is fixed on the second elastic thread 12.

S24, after the elastic strands are woven for a certain distance, the first power cord 101 is inserted between the elastic strands of the second elastic thread 12 in a forward and oblique direction, and the second power cord 102 is inserted between the elastic strands of the third elastic thread 13 in a forward and oblique direction.

S25, knitting is continued to form each elastic thread so that the first power cord 101 is fixed to the second elastic thread 12 and the second power cord 102 is fixed to the third elastic thread 13.

S26, after knitting the elastic strands for a distance, reversely and obliquely inserting the first power cord 101 between the elastic strands of the second elastic cord 12, and reversely and obliquely inserting the second power cord 102 between the elastic strands of the third elastic cord 13.

S27, knitting is continued to form each elastic thread so that the first power cord 101 is fixed to the second elastic thread 12 and the second power cord 102 is fixed to the third elastic thread 13.

S28, after knitting the elastic strands for a distance, obliquely inserting the first power line 101 in the opposite direction between the elastic strands of the first elastic thread 11, and obliquely inserting the second power line 102 between the elastic strands of the second elastic thread 12 in the opposite direction.

And S29, repeating the steps S22 to S28 until the elastic conductive wire with the required length is completed.

In the above steps, the lengths of the first elastic thread 11, the second elastic thread 12 and the third elastic thread 13 which are knitted simultaneously may be equal or different. Preferably, the first power line 101 and the second power line 102 obliquely inserted through have the same angle, so that the product structure is more attractive.

EXAMPLE III

As shown in fig. 3 to 15, a woven elastic conductive wire for smart clothing includes a plurality of elastic wires arranged in parallel and a power line arranged in an S-shaped circle, and the power line is inserted into each elastic wire in a reciprocating manner, so that the power line and the elastic wires are woven and fixed to each other to form a flat elastic conductive wire. Still alternate between the bullet line of this embodiment and the power cord and have a plurality of braided wires, fix the power cord on playing the line through the braided wire. The power lines include a first power line 101 and a second power line 102, and the first power line 101 and the second power line 102 are distributed side by side up and down, so that a plane (or a curved surface) where the first power line 101 is located and a plane (or a curved surface) where the second power line 102 is located are parallel.

Specifically, the left to right direction in the figure is taken as the forward direction, and the right to left direction is taken as the reverse direction: in a rotation period of the power line (the first power line 101 or the second power line 102), the power line repeatedly passes through every two adjacent elastic lines in the forward direction and then repeatedly passes through every two adjacent elastic lines in the reverse direction. Because the power line needs to bypass the last line in the direction during the forward and reverse wiring processes, the direction of the power line passing through the power line in the forward wiring process is opposite to the direction of the power line passing through the power line in the reverse wiring process in any two adjacent elastic lines.

In this embodiment, the elastic thread is a single elastic thread, and includes a first elastic thread 21, a second elastic thread 22, a third elastic thread 23, a fourth elastic thread 24, a fifth elastic thread 25, and a sixth elastic thread 26, and the first elastic thread 21, the second elastic thread 22, the third elastic thread 23, the fourth elastic thread 24, the fifth elastic thread 25, and the sixth elastic thread 26 are all sequentially arranged in parallel, and provide tracks for the first power line 101 and the second power line 102 to route, and achieve a springback effect.

This a woven fashioned elasticity conductor wire for intelligent clothing still includes a plurality of parallel arrangement' S braided wire, and the braided wire is the same with power cord layout mode, all is the S-shaped range of circling round, and the braided wire passes two adjacent elastic wires repeatedly to on being fixed in the elastic wire with the power cord, fix power cord and elastic wire through weaving the line, make whole product be difficult for taking place deformation, can make simultaneously to apply the power on the power cord more dispersed, fully protected the power cord.

In this embodiment, the braided wire includes a forward braided wire and a reverse braided wire, the braiding direction of the forward braided wire is the same as that of the first power supply line 101, and the braiding direction of the reverse braided wire is the same as that of the second power supply line 102. Namely: in a convolution period of the braided wire, the forward braided wire is parallel to the first power line 101 in the same row, and the reverse braided wire is parallel to the second power line 102 in the same row. The forward and reverse directions here depend on whether the direction in which the knitting yarn starts to enter the yarn is clockwise or counterclockwise when the knitting yarn is knitted. In this embodiment, the first power line 101 and the forward braided wire are defined as clockwise defense lines, and the second power line 102 and the reverse braided wire are defined as counterclockwise defense lines.

Preferably, the number of forward braided wires is different from the number of reverse braided wires. In this embodiment, the number of the reverse braided wires is 1 more than the number of the forward braided wires. Specifically, the forward braided wire includes a first forward braided wire 201, a second forward braided wire 202, a third forward braided wire 203, a fourth forward braided wire 204, and a fifth forward braided wire 205, and the reverse braided wire includes a first reverse braided wire 301, a second reverse braided wire 302, a third reverse braided wire 303, a fourth reverse braided wire 304, a fifth reverse braided wire 305, and a sixth reverse braided wire 306.

As shown in fig. 5 to 15, in the knitting process of the elastic conductive thread for knitting and forming of the smart garment, a plurality of parallel elastic threads are arranged, the first power cord 101 is inserted into the space between two adjacent elastic threads in a forward direction and repeatedly rotated, and the second power cord 102 is inserted into the space between two adjacent elastic threads in a reverse direction and repeatedly rotated. The method also comprises the weaving process of the forward weaving wire and the weaving process of the reverse weaving wire:

after the first power line 101 is inserted in the forward direction, the forward braided wire is inserted between every two adjacent elastic wires in the forward direction, and after the first power line 101 rotates back, the forward braided wire rotates back and is inserted between every two adjacent elastic wires in the reverse direction; after the second power line 102 is inserted in the reverse direction, the reverse braided wire is inserted between every two adjacent elastic wires in the reverse direction, and after the second power line 102 is rotated, the reverse braided wire is rotated and inserted between every two adjacent elastic wires in the forward direction.

The method specifically comprises the following steps:

s31, arranging a plurality of elastic wires in parallel, as shown in figure 5.

Specifically, the first elastic thread 21, the second elastic thread 22, the third elastic thread 23, the fourth elastic thread 24, the fifth elastic thread 25, and the sixth elastic thread 26 are arranged side by side in this order. The lower end in the defined figure is the starting end, and all the elastic lines extend from bottom to top in turn.

S32, sequentially inserting the first power cord 101 in the forward direction through the elastic cord, and making the threading directions of the first power cord 101 on the left and right sides of the same elastic cord opposite, sequentially inserting the second power cord 102 in the reverse direction through the elastic cord, and making the threading directions of the second power cord 102 on the left and right sides of the same elastic cord opposite, as shown in fig. 6.

The first power line 101 is defined as a clockwise trace, and the second power line 102 is defined as a counterclockwise trace. In the present embodiment, the first power line 101 sequentially passes from left to right around the upper side of the first elastic wire 21, the lower side of the second elastic wire 22, the upper side of the third elastic wire 23, the lower side of the fourth elastic wire 24, the upper side of the fifth elastic wire 25, and the lower side of the sixth elastic wire 26, the second power line 102 sequentially passes from right to left around the upper side of the sixth elastic wire 26, the lower side of the fifth elastic wire 25, the upper side of the fourth elastic wire 24, the lower side of the third elastic wire 23, the upper side of the second elastic wire 22, and the lower side of the first elastic wire 21, and the first power line 101 and the second power line 102 intersect between the second elastic wire 22 and the third elastic wire 23 (at the winding position in the drawing, the power line partially bends upward to represent winding from the upper side, and partially bends downward to represent winding from the lower side).

S33, sequentially inserting the first forward braided wire 201 in the forward direction through the elastic wires, and making the threading directions of the first forward braided wire 201 on the left and right sides of the same elastic wire opposite, and making the threading directions of the first forward braided wire 201 and the first power line 101 opposite. Specifically, the first forward braided wire 201 passes around the lower side of the first elastic wire 21, the upper side of the second elastic wire 22, the lower side of the third elastic wire 23, the upper side of the fourth elastic wire 24, the lower side of the fifth elastic wire 25, and the upper side of the sixth elastic wire 26 in this order from left to right, as shown in fig. 7.

The first reverse braided wire 301 is sequentially inserted through the elastic wires in a reverse direction, and the threading directions of the first reverse braided wire 301 on the left side and the right side of the same elastic wire are opposite, and the threading directions of the first reverse braided wire 301 and the second power wire 102 are opposite. Specifically, the first reverse braided wire 301 sequentially passes from right to left around the lower side of the sixth elastic wire 26, the upper side of the fifth elastic wire 25, the lower side of the fourth elastic wire 24, the upper side of the third elastic wire 23, the lower side of the second elastic wire 22, and the upper side of the first elastic wire 21, and the first forward braided wire 201 and the first reverse braided wire 301 intersect between the second elastic wire 22 and the third elastic wire 23.

S34, the second forward braided wire 202 is sequentially inserted through the elastic wires in the forward direction, and the threading directions of the second forward braided wire 202 on the left and right sides of the same elastic wire are opposite, and the threading directions of the second forward braided wire 202 and the first forward braided wire 201 are opposite. Specifically, the second forward braided wire 202 passes around the upper side of the first elastic wire 21, the lower side of the second elastic wire 22, the upper side of the third elastic wire 23, the lower side of the fourth elastic wire 24, the upper side of the fifth elastic wire 25, and the lower side of the sixth elastic wire 26 in this order from left to right, as shown in fig. 8.

The second reverse braided wire 302 is inserted through the elastic wire in reverse order, and the threading directions of the second reverse braided wire 302 at the left side and the right side of the same elastic wire are opposite, and the threading directions of the second reverse braided wire 302 and the first reverse braided wire 301 are opposite. Specifically, the second reverse braided wire 302 sequentially passes from right to left around the upper side of the sixth elastic wire 26, the lower side of the fifth elastic wire 25, the upper side of the fourth elastic wire 24, the lower side of the third elastic wire 23, the upper side of the second elastic wire 22, and the lower side of the first elastic wire 21, and the second forward braided wire 202 and the second reverse braided wire 302 cross between the second elastic wire 22 and the third elastic wire 23.

And S35, repeating the step S34 until all the forward knitting yarns and all the reverse knitting yarns are knitted, and finishing the knitting of the forward knitting yarns and the reverse knitting yarns, as shown in figures 9 to 12.

Specifically, knitting of the third forward knitting yarn 203, the fourth forward knitting yarn 204, the fifth forward knitting yarn 205, the third reverse knitting yarn 303, the fourth reverse knitting yarn 304, the fifth reverse knitting yarn 305, and the sixth reverse knitting yarn 306 is completed, and the intersection of the third forward knitting yarn 203 and the third reverse knitting yarn 303, the intersection of the fourth forward knitting yarn 204 and the fourth reverse knitting yarn 304, and the intersection of the fifth forward knitting yarn 205 and the fifth reverse knitting yarn 305 are all crossed between the second elastic yarn 22 and the third elastic yarn 23.

S36, the first power cord 101 bypasses the last elastic cord in the forward direction and then is inserted through each elastic cord in the reverse direction, and the threading directions of the first power cords 101 on the left and right sides of the same elastic cord are opposite, as shown in fig. 3. Specifically, the method comprises the following steps:

the first power cord 101 sequentially passes from right to left around the upper side of the sixth elastic cord 26, the lower side of the fifth elastic cord 25, the upper side of the fourth elastic cord 24, the lower side of the third elastic cord 23, the upper side of the second elastic cord 22, and the lower side of the first elastic cord 21.

After bypassing the last elastic thread in the reverse direction, the second power cord 102 sequentially passes through the elastic threads in the forward direction, and the threading directions of the second power cords 102 on the left and right sides of the same elastic thread are opposite, as shown in fig. 14. Specifically, the method comprises the following steps:

the second power line 102 sequentially passes around the upper side of the first elastic line 21, the lower side of the second elastic line 22, the upper side of the third elastic line 23, the lower side of the fourth elastic line 24, the upper side of the fifth elastic line 25 and the lower side of the sixth elastic line 26 from left to right, and the first power line 101 after passing around and the second power line 102 after passing around intersect between the fourth elastic line 24 and the fifth elastic line 25.

S37, the forward braided wires are wound around the last elastic wire in the forward direction and then are inserted through the elastic wires in the reverse direction, the threading directions of the forward braided wires on the left side and the right side of the same elastic wire are opposite, and the threading direction of one forward braided wire is opposite to the threading direction of the first power wire 101 or the previous forward braided wire; the reverse braided wires are passed around the last reverse elastic wire and then sequentially inserted through the elastic wires in the forward direction, so that the threading directions of the reverse braided wires on the left side and the right side of the same elastic wire are opposite, and the threading direction of one reverse braided wire is opposite to the threading direction of the second power wire 102 or the previous reverse braided wire, as shown in fig. 15.

For example, the rear end of the first forward braided wire 201 passes around the sixth elastic wire 26, and then sequentially passes around the lower side of the sixth elastic wire 26, the upper side of the fifth elastic wire 25, the lower side of the fourth elastic wire 24, the upper side of the third elastic wire 23, the lower side of the second elastic wire 22, and the upper side of the first elastic wire 21 from right to left; the rear end of the first reverse braided wire 301 passes around the first elastic wire 21 and then sequentially passes around the lower side of the first elastic wire 21, the upper side of the second elastic wire 22, the lower side of the third elastic wire 23, the upper side of the fourth elastic wire 24, the lower side of the fifth elastic wire 25 and the upper side of the sixth elastic wire 26 from left to right; the first forward braided wire 201 after being wound back and the first reverse braided wire 301 after being wound back cross between the fourth elastic wire 24 and the fifth elastic wire 25.

S38, the first power cord 101 and each forward braided cord are passed around the forward first elastic cord (i.e., the first elastic cord 21), and the second power cord 102 and each reverse braided cord are passed around the reverse first elastic cord (i.e., the sixth elastic cord 26).

And S39, repeating the steps S32 to S37 until the elastic conductive wire with the required length is completed.

It should be noted that, because the first power line 101 is crossed and woven with each forward woven wire when running in the reverse direction, and is crossed and woven with the looped forward woven wire when running in the subsequent forward direction, the present embodiment does not limit the upper and lower positions of these woven positions, and those skilled in the art can implement various designs, and the routing and weaving of the second power line 102 are the same.

In this embodiment, each forward weaving yarn is essentially the same as each reverse weaving yarn, and the difference is only in the starting direction of the running yarn.

In a preferred embodiment, the first elastic thread 21, the second elastic thread 22, the third elastic thread 23, the fourth elastic thread 24, the fifth elastic thread 25 and the sixth elastic thread 26 are all spandex threads; the first forward knitting yarn 201, the second forward knitting yarn 202, the third forward knitting yarn 203, the fourth forward knitting yarn 204, the fifth forward knitting yarn 205, the first reverse knitting yarn 301, the second reverse knitting yarn 302, the third reverse knitting yarn 303, the fourth reverse knitting yarn 304, the fifth reverse knitting yarn 305, and the sixth reverse knitting yarn 306 are all made of polyester materials.

The elastic conductive wire of the present invention has the following effects:

1. the product is simple in weaving mode, the weaving process is quicker, and the production efficiency of the product is high;

2. the elastic conductive wire has high expansion rate which can reach 50 percent, and the elastic conductive wire is easier to rebound;

3. the power line is woven in the elastic wire, so that the stress of the whole product is more dispersed, the power line is protected from being damaged easily, and the service life of the product is prolonged;

4. compared with the traditional 40 omega/m, the resistance value of the woven conductive wire is only 0.03-0.05/m;

5. after the invention is woven into a finished product, the internal electromagnetic interference is weaker, and the mutual influence is smaller.

It will be understood that modifications and variations can be made by persons skilled in the art in light of the above teachings and all such modifications and variations are intended to be included within the scope of the invention as defined in the appended claims.

The invention is described above with reference to the accompanying drawings, which are illustrative, and it is obvious that the implementation of the invention is not limited in the above manner, and it is within the scope of the invention to adopt various modifications of the inventive method concept and technical solution, or to apply the inventive concept and technical solution to other fields without modification.