WO2012077893A1 - Conductive thread provided with feather yarn, method for manufacturing the conductive thread, and fabric manufactured by same - Google Patents

Abstract

In order to provide a conductive thread enabling a glove to be used with an electronic device employing an electric capacitance-type touch screen to be manufactured in a single continuous process; to provide a method for manufacturing the conductive thread; and to provide a fabric manufactured by same, the conductive thread according to the present invention comprises: a core yarn including a first core yarn and a second core yarn formed of a conductive yarn material, where the first core yarn and the second core yarn are mutually intersected, and circular or elliptical spaces are formed by the first core yarn and the second core yarn at the points of intersection; and a first feather yarn, wherein the feather yarn of a conductive material and having a finer thickness than the first core yarn and the second core yarn is inserted at one end between the first core yarn and the second core yarn at a first point where the first core yarn and the second core yarn intersect, and after being inserted at another end at a second point where the first core yarn and the second core yarn intersect, the feather yarn is pulled out of the one end and is pulled and fixed by the first core yarn and the second core yarn to thus produce the first feather yarn cut parallel to the axis formed by the first core yarn and the second core yarn.

Description

Conductive yarns with blades and a method for manufacturing conductive yarns and fabrics produced thereby

The present invention relates to a conductive yarn, a method for producing a conductive yarn and a fabric produced by the conductive yarn, and more particularly, a method for producing a conductive yarn using a yarn of a conductive material, and a conductive material produced by the above-described manufacturing method. It relates to a yarn and a fabric produced by the above conductive yarn.

Recently, a touch screen is in the spotlight as an input device of an electronic device. Such touch screens are already widely used in computers, game consoles, and the like, and recently, as they are adopted in mobile terminals or portable electronic devices, they are becoming new input devices replacing conventional mice or keyboards.

An input device using a touch screen is a core technology that accurately recognizes a touch point. There are various recognition methods such as a resistive film type, surface acoustic wave type, and capacitive type according to a method of recognizing a touch point.

1 is a view showing the operating principle of the resistive touch screen.

The resistive film type is one of the typical touch screen operation methods, which uses the principle of electrical communication when two conductor films are in contact with each other. An insulating layer (usually air is used) is formed between the conductor films, and when the conductor film is pressed, This results in the calculation of the location where the resistance changes, thereby determining the point of touch.

However, in the case of the resistive film method, the conductor film must be pressed, so that the conductor film is usually a soft material and uses a material that can be deformed when pressure is applied. As a result, if the pressure is repeatedly applied, the surface of the conductor film is damaged.

A surface acoustic wave type touch screen is proposed to compensate for this disadvantage. FIG. 2 is a view illustrating an operation principle of the surface acoustic wave type touch screen.

The surface acoustic wave touch screen enters a sound or light in a certain direction and then encounters an obstacle such as a pen or a hand at a specific point, that is, a change in the wave and detects the change to detect the position of the obstacle, that is, the touch point. It is the way of recognition.

However, in the case of the surface acoustic wave touch screen, since the resolution for recognizing the position of the touch point is determined according to the size of the obstacle, it is useful for a large touch screen but is not suitable for a small touch screen such as a mobile terminal (cell phone).

As another method for improving the disadvantage of the resistive touch screen, a capacitive touch screen is mainly used in a portable terminal.

3 is a view illustrating a principle of capacitive touch screen operation.

The capacitive touch screen is a method of detecting the location of the touch point by detecting a change in capacitance between two conductor plates.

That is, as shown in Figure 3, when touching a specific point (touch point) of the front plate, the capacitance at the touch point is changed by the dielectric constant of the finger, and the electric field is changed accordingly. Accordingly, the touch point is recognized by recognizing the point where the electric field is changed.

The capacitive touch screen is based on the fact that the human body is a conductor that affects the electric field and uses it for the touch screen.

However, in the case of the capacitive type, there is a disadvantage that the contact of the conductor is required. For example, when touched with non-conductive rubber or non-conductive fiber, since the capacitance does not change, the electric field does not change, so the touch point cannot be recognized.

On the other hand, portable terminals employing capacitive touch screens are rapidly spreading recently. If a user wears gloves, it is not inconvenient to use a portable terminal employing capacitive touch screens. .

Therefore, it is required to be able to use a portable terminal employing a capacitive touch screen even in a region where the temperature is low or even in winter, even when wearing gloves.

In accordance with such a request, US Patent Publication No. 2009-0000010 (published: 2009.01.01) discloses a glove having a structure in which a conductive material is added to an end portion of a finger part of the glove.

5 is a view showing the structure of a glove having a conductive region according to US Patent Publication No. US2009-0000010.

Since the gloves according to FIG. 5 have a conductive material added to the fingertips, when using a capacitive touch screen, when the fingertips are touched, the capacitance is changed by the conductive material and the electric field is changed accordingly, so take off the gloves. Capacitive touchscreens can be used without

However, in the case of the glove as described above, it is impossible to use it if you want to use a finger surface rather than a finger tip because the structure is added to the conductive material to the fingertips.

This can be solved by adding a conductive material to both the finger surface and the fingertip.

In this case, however, in order to manufacture gloves, a conductive material should be replaced with a thread of non-conductive material, or after completion of the glove with a thread of non-conductive material, a separate conductive material is added. Since there is a need to go through the process, there is a problem that the glove manufacturing process is increased and complicated.

The present invention has been proposed to solve the above problems, to provide a fabric, for example a glove that can be used without taking off the gloves even when using an electronic device employing a capacitive touch screen.

In addition, the present invention has been proposed to solve the above problems, to provide a method of manufacturing a conductive seal to make a glove capable of using an electronic device employing a capacitive touch screen by one continuous process. I would like to.

In addition, the present invention has been proposed to solve the above problems, and to provide a conductive seal that allows the glove capable of using an electronic device employing a capacitive touch screen to be manufactured by one continuous process.

Conductive yarn manufacturing method provided with a wing yarn according to an embodiment of the present invention for achieving the above object,

A screen knitting step in which a first screening and a second screening of a conductive material yarn are made to cross each other and a circular or elliptical space is formed by the first screening and the second screening between the crossing points;

At one side a first wing yarn made of a yarn of a conductive material having a thickness thinner than the first and second examinations between the first and second examinations at a first point where the first and second examinations intersect. Knitting a first wing yarn so that the wing yarn is fitted from one side of the other at the second point where the first and second examinations intersect and then emerge in the direction of one side; And

Fixing the first wing yarn by inserting the first wing yarn and tightening the first and second examinations,

The screening knitting step,

A first screen knitting step of knitting a first screen to cross two yarns of conductive material and to form a predetermined space of a circular or ellipse between the crossing points;

Cross the yarns of two conductive materials to each other, and a predetermined space of a circular or oval shape is formed at a predetermined angle with a predetermined space formed in the first examination between the crossing points and the intersection point of the first examination Or a second examination knitting step of simultaneously performing the second examination with the first examination knitting step so that the interval between the points of the second examination has a predetermined interval, or

The method may further include knitting and arranging at least one of the first and second examinations so as to be parallel to the first and second examinations, respectively.

Knitting the first wing yarn,

The second wing yarn is inserted into and coupled at a third point where the first and second examinations intersect in the same process as the first wing yarn or in the opposite direction to the first wing yarn, and is inserted and coupled at a fourth point. It may further comprise the steps of knitting,

And after the fixing of the first and second wing yarns, cutting the first and second wing yarns to a predetermined length symmetrically with respect to the axes formed by the first and second examinations. And

On the other hand, characterized in that it further comprises the step of knitting the fabric with a conductive thread consisting of the first and second wing yarns cut to the predetermined length and the first and second examinations.

Conductive seal provided with a wing yarn according to an embodiment of the present invention for achieving the above object,

A first examination and a second examination comprising a yarn made of a conductive material, wherein the first and second examinations cross each other, and a circular or oval space is formed by the first and second examinations between the intersections. Formed screening;

At the first point where the first and second examinations intersect, a wing thread of a conductive material having a thickness thinner than that of the first and second examinations is inserted between the first and second examinations on one side and the first examination and the second examination. At the second point where the audit and the second audit intersect, the wing thread is fitted on the other side and then comes out in the direction of one side to be tightened and fixed by the first audit and the second audit, and the first audit and the second audit are It is characterized by consisting of a first wing yarn cut parallel to the axis to be formed.

Conductive seal provided with a wing yarn according to another embodiment of the present invention for achieving the above object,

A first examination and a second examination comprising a yarn made of a conductive material, wherein the first and second examinations cross each other, and a circular or oval space is formed by the first and second examinations between the intersections. An examination in which the first examination and the second examination are each arranged at least two in parallel; And

At one side a wing yarn of a conductive material having a thickness thinner than the first and second examinations is provided between the first and second examinations at a first point where each of the at least two first and second examinations intersects. At the second point at which the first and second examinations intersect, the wing thread is fitted on the other side and then comes out in the direction of one side to be tightened and fixed by the first and second examinations and the first examination. And a first wing yarn cut parallel to the axis formed by the second examination.

Meanwhile, the first examination is knitted to cross two yarns of conductive material and form a predetermined space of a circular or oval shape between the crossing points.

The second examination allows the two conductive yarns to cross each other, and a predetermined space of a circular or oval shape is formed at a predetermined angle with a predetermined space formed at the first examination between the crossing points and the first examination. Between the intersection of and the intersection of the second examination may be knitted to have a predetermined interval,

In the same process that the first wing yarn is knitted or the second wing yarn that is fitted and coupled at a third point where the first and second examination intersects in the opposite direction to the first wing yarn and is inserted and coupled at a fourth point May be included.

Meanwhile, the fabric according to the embodiment of the present invention for achieving the above object is characterized in that the conductive fabric knitted into the conductive thread of the present invention.

The conductive fabric is, for example, characterized in that the pattern knitted on gloves or gloves made of the conductive thread.

The glove manufactured by the conductive seal according to the present invention having the above configuration can be used without taking off the glove even when the electronic device employing the capacitive touch screen.

In addition, the glove manufactured by the conductive seal according to the present invention having the configuration as described above can be manufactured by one continuous process without going through a separate process to have a conductive material to simplify the glove manufacturing process .

1 is a view showing the operating principle of the resistive touch screen.

2 is a view showing the operation principle of the surface acoustic wave type touch screen.

3 is a view illustrating a principle of capacitive touch screen operation.

4 is a view showing the structure of a glove having a conductive region according to the prior art.

5 is a schematic diagram illustrating a process of manufacturing a conductive seal according to the present invention.

6 is a view showing a process of knitting the screening of the process of manufacturing the conductive yarn according to the present invention.

7 is a view showing a state after completion of the screening and knitting of the wing yarn during the process of manufacturing the conductive yarn according to the present invention.

8 is an enlarged view of the conductive seal according to the present invention.

9 is an enlarged view of a structure of a conductive seal according to the present invention.

10 is a view for explaining the coupling structure of the screening and wing yarn in the conductive seal according to the present invention.

(Explanation of the sign)

510: First examination 520: Second examination

530, 530 ': Wing thread T: Wing thread cutting position

610: first examination 620: second examination

710: Judging 720: Wings

730: secondary screening

810: Judging 820: Wings

910: first examination 920: second examination

930, 930 ': the first wing

940, 940 ': Second Wingsman

1010: First Examination

1011: 1st examination 1st yarn 1012: 1st examination 2nd yarn

1020: second review

1021: second examination of the first yarn 1022: second examination of the second yarn

1030: first winger 1040, 1040 ': second winger

S1, S2, S3: where the wing is combined with the screening

Hereinafter, the manufacturing process of the conductive seal, the conductive seal according to the present invention will be described in detail with reference to the drawings.

However, the following examples are only for illustrating the present invention, and the contents of the present invention are not limited by the following examples.

FIG. 5 is a schematic view showing a process of manufacturing a conductive thread according to the present invention, in particular showing that the wing thread is fitted to the plurality of examinations.

First, the first examination 510 and the second examination 520 are knitted by a conventional knitting machine. In this case, it is possible to arrange the at least one first screening 510 and the second screening 520 in parallel with each other.

Thereafter, the at least one wing yarn 530 is inserted into and coupled between the first screening 510 and the second screening 520, where each wing screen 530 is the first screening 510 and the second screening 520. ), Make sure that the direction that starts to fit between and the direction that comes out after being fitted coincide.

That is, in FIG. 5, if the wing yarns 530 are fitted from the A direction to the B direction to be coupled to the first first examination 510 and the second examination 520, the intermediate first examination 510 and the second examination 520 is also inserted in the same direction and the first screening 510 and the second screening 520, which are the last screening, and then the first screening 510 and the second screening 520 in the direction A to B in the direction A again. After being inserted in the first direction 510 and the second examination (520) in the same direction in the same direction after being inserted into the first first screening (510) and the second screening (520) and combined in the direction A The wing thread 530 is completed to be combined with the screening.

If it is coupled to the first screening 510 and the second screening 520 in the B direction like the other wing thread 530 ', the first screening in the same process or in the opposite direction as the wing thread 530 ( 510 and the second examination 520 is finally combined with the wing yarn 530 'is inserted into the first screening 510 and the second screening 520 in the direction B, the wing thread 530' is coupled to the screening Is done.

Meanwhile, in FIG. 5, the wing yarns 530 and the wing yarns 530 ′ are shown to be coupled to the screening at different positions. It should be noted that the wing yarns 530 and the wing yarns 530 ′ may be coupled at the same position by adjusting the knitting machine.

The structure of the conductive thread according to the present invention in the state in which the combination of the screening and the wing yarn is completed through the above process is not preferable as the form of the yarn for manufacturing the fabric in the form of a net, so that the wing yarn to have the shape of the yarn The process of cutting is further performed.

That is, when the wing yarns 530 and the wing yarns 530 'are cut at the cutting position T with a cutter (for example, a blade), the lengths of the wing yarns 530 and the wing yarns 530' are the first examination 510. And it is cut symmetrically to the examination consisting of the second examination (520).

Wing yarns are preferably cut symmetrically upon screening, but can be cut asymmetrically as necessary.

On the other hand, in the above embodiment has been described an example in which the wing yarn is coupled to both sides with respect to the examination, it is also possible to combine only one side of the examination as necessary. That is, without the wing yarns 530 'coupled to the screening from the B direction to the A direction, it is also possible to configure the wing yarns with only the wing yarns 530 coupled to the screening from the A direction to the B direction.

When the wing yarns 530 and 530 'are cut, a conductive yarn is formed in which the wing yarns 530 and 530' are attached in a wing shape, and the conductive yarns are then used to manufacture various shapes of fabrics as necessary.

For example, it can be used to manufacture gloves, in the case of manufacturing gloves with a conductive thread according to the present invention after knitting with a conventional thread in order to have a conductive to the conventional gloves, a specific position of the glove, for example, the inner end of the finger When knitting the tip of the finger or the like, it is possible to eliminate the inconvenience in the manufacturing process that must be replaced again after replacing with a yarn having a separate conductivity.

In addition, when manufacturing a glove with a conductive thread according to the present invention, since the glove is conductive in its entirety, it is possible to control a mobile device employing a capacitive touch screen while wearing gloves.

6 is a view showing a process of knitting the screening of the process of manufacturing the conductive yarn according to the present invention.

In FIG. 6, each examination consists of two yarns, and a detailed structure thereof is described with reference to FIGS. 9 and 10, and thus description thereof will be omitted.

The first examination 610 and the second examination 620 is a structure in which a circular or oval space is formed between points where two conductive yarns cross each other.

The first screening 610 and the second screening 620 having the above-described structure are the same as the method of knitting the screen with two yarns while the center axis forms a predetermined angle and the intersection point has a predetermined interval. Knitting by a knitting machine in a manner.

The first screening 610 and the second screening 620 knitted through the process as described above is then subjected to the process of knitting the wing yarn.

7 is a view showing a state after completion of the screening and knitting of the wing yarn during the process of manufacturing the conductive yarn according to the present invention.

In FIG. 7, it can be seen that the first yarn 610 and the second yarn 620 that have undergone the knitting process of FIG. 6 are coupled to the wing yarn 720 by being fitted to the knitted yarn 710.

Since each wing yarn 720 is cut symmetrically to the central axis of each screening 710 at the cutting position T is used as a conductive thread for knitting the fabric according to the present invention.

8 is an enlarged conductive thread according to the present invention, it can be seen that the wing yarn 820 is coupled to the screening (810).

8 relates to an example in which the wing yarns 820 are cut asymmetrically with respect to the screening 810.

9 is a view showing a structure in which the wing yarn is coupled to the screening of the conductive thread according to the present invention, Figure 10 is a view illustrating a coupling structure of the screening and wing yarn in the conductive thread according to the present invention.

First, as shown in FIG. 10, the first examination 1010 has a structure in which two conductive yarns 1011 and 1012 cross each other, and likewise, the second examination 1020 also has two conductive yarns 1021 and 1022. It can be seen that is a structure intersecting with each other.

Meanwhile, a circular or elliptical space is formed between the points C1, C2 and C1 'and C2' where the two yarns 1011, 1012, 1021, and 1022 cross each other.

The circular or oval space as described above is exaggerated and greatly illustrated for convenience of description in FIG. 10. However, when the knitting machine is knitted, it is to be noted that the knitting machine needle is fine enough to pass.

On the other hand, the two examinations 1010 and 1020 are knitted in the same manner as the two yarns are knitted into the examination. The difference is that the points where the yarns of each examination intersect are spaced at predetermined intervals.

The reason for spaced apart at a predetermined interval in the above is because fitting the wing yarns in the spaced apart is most suitable for fixing the wing yarns to the screening.

That is, when the wing yarns 1030 and 1040 are inserted into the spaces S1, S2, and S3, and the screen is pulled out, the spaces are reduced and the wing yarns 1030 and 1040 and the screens 1010 and 1020 are in close contact. The wing yarns 1030 and 1040 are firmly fixed to the screenings 1010 and 1020.

Meanwhile, as described with reference to FIG. 5, the positions where the wing yarns 1030 and 1040 are coupled to the screenings 1010 and 1020 may be the same point.

That is, at the point S1, the first wing yarns 1030 are sandwiched and fitted between the screenings in the A direction and the B direction, and the second wing yarns 1040 may be fitted between the screenings in the B direction and the A direction.

Alternatively, it is also possible to have the positions where each of the wing yarns 1030 and 1040 are coupled to the screenings 1010 and 1020 to be spaced apart by one difference of a circular or oval space.

That is, at the point S1, the first wing yarn 1030 is fitted between the screenings 1010 and 1020 in the direction A to B, and is coupled to the screening points 1010 and 1020 in the direction A to the direction B at the point S2. The second wing 1040 'is fitted between the screening (1010, 1020) in the direction A to B at the point S2 and comes out after being fitted to the screening (1010, 1020) from the direction A to B at the point S3 It is possible to.

In addition, the wing yarns 1030 and 1040 may be set by varying the starting position that is fitted into the screening 1010 and 1020 and the final position that is coupled to the combined position.

For example, the start position and the final position where the first wing yarn 1030 is coupled to the screening 1010 and 1020 are spaced apart by two spaces of circular or oval shape, and the first wing yarn 1030 is screening 1010, If the starting position to be coupled to 1020 is S1, the final position to be coupled is S3.

9 illustrates that the position of the wing yarn and the screening described above and the wing yarn and the wing yarn is variable.

That is, the first wing 930 and the second wing 940 may be combined in the same position in the first screening 910 and the second screening 920, the first wing yarn in another way 930 ′ and the second wing yarn 940 ′ may set a coupling position with one circular or oval space.

Claims (23)

1. A screen knitting step in which a first screening and a second screening of a conductive material yarn are made to cross each other and a circular or elliptical space is formed by the first screening and the second screening between the crossing points;

   At one side a first wing yarn made of a yarn of a conductive material having a thickness thinner than the first and second examinations between the first and second examinations at a first point where the first and second examinations intersect. Knitting a first wing yarn so that the wing yarn is fitted from one side of the other at the second point where the first and second examinations intersect and then emerge in the direction of one side; And

   And inserting the first wing yarns and tightening the first and second examinations to fix the first wing yarns.
2. The method of claim 1,

   The screening knitting step,

   A first screen knitting step of knitting a first screen to cross two yarns of conductive material and to form a predetermined space of a circular or ellipse between the crossing points;

   Cross the yarns of two conductive materials to each other, and a predetermined space of a circular or oval shape is formed at a predetermined angle with a predetermined space formed in the first examination between the crossing points and the intersection point of the first examination And a second examination knitting step of performing a second examination simultaneously with the first examination knitting step so that the points between the intersections of the second examination have a predetermined interval.
3. The method of claim 1,

   The screening knitting step,

   And knitting and arranging at least one of the first and second examinations so as to be parallel to the first and second examinations, respectively.
4. The method of claim 2,

   Knitting the first wing yarn,

   A second wing yarn that is fitted and coupled at a third point where the first and second examinations intersect in the same process as the first wing yarn or in the opposite direction to the first wing yarn, and is fitted and coupled at a fourth point; The method of manufacturing a conductive yarn further comprising the step of knitting.
5. The method of claim 4, wherein

   And wherein the first point and the third point are the same position, and the second point and the fourth point are the same position.
6. The method of claim 4, wherein

   The first point and the third point, the second point and the fourth point is a conductive yarn manufacturing method, characterized in that spaced at intervals of at least one circular or elliptical space, respectively.
7. The method of claim 4, wherein

   The first point and the second point, the third point and the fourth point is a conductive yarn manufacturing method, characterized in that spaced at intervals of at least one or more circular or elliptical space, respectively.
8. The method according to any one of claims 1 to 7,

   After the fixing of the first and second wing yarns, further comprising cutting the first and second wing yarns to a predetermined length symmetrically to the axes formed by the first and second examinations. A conductive thread manufacturing method characterized by the above-mentioned.
9. The method of claim 8,

   And knitting the fabric with a conductive thread comprising the first and second wing yarns cut into the predetermined length, and the first and second check yarns.
10. The method of claim 9,

    The fabric made of the conductive thread is a conductive yarn manufacturing method, characterized in that the pattern knitted on the glove or gloves made of the conductive thread.
11. A first examination and a second examination comprising a yarn made of a conductive material, wherein the first and second examinations cross each other, and a circular or oval space is formed by the first and second examinations between the intersections. Formed screening;

    At the first point where the first and second examinations intersect, a wing thread of a conductive material having a thickness thinner than that of the first and second examinations is inserted between the first and second examinations on one side and the first examination and the second examination. At the second point where the audit and the second audit intersect, the wing thread is fitted on the other side and then comes out in the direction of one side to be tightened and fixed by the first audit and the second audit, and the first audit and the second audit are The conductive thread which consists of a 1st wing yarn cut parallel to the axis to form.
12. A first examination and a second examination comprising a yarn made of a conductive material, wherein the first and second examinations cross each other, and a circular or oval space is formed by the first and second examinations between the intersections. An examination in which the first examination and the second examination are each arranged at least two in parallel; And

    At one side a wing yarn of a conductive material having a thickness thinner than the first and second examinations is provided between the first and second examinations at a first point where each of the at least two first and second examinations intersects. At the second point at which the first and second examinations intersect, the wing thread is fitted on the other side and then comes out in the direction of the one side so as to be tightened and fixed by the first and second examinations and the first examination. And a first wing yarn cut parallel to the axis formed by the second examination.
13. The method according to claim 11 or 12, wherein

    The first examination is knitted to cross the yarns of the two conductive materials to each other and to form a predetermined space of circular or oval between the crossing points,

    The second examination allows the two conductive yarns to cross each other, and a predetermined space of a circular or oval shape is formed at a predetermined angle with a predetermined space formed at the first examination between the crossing points and the first examination. A conductive thread, characterized in that it is knitted so as to have a predetermined interval between the intersection of the intersection of the intersection and the intersection of the second examination.
14. The method of claim 13,

    In the same process that the first wing yarn is knitted or the second wing yarn that is fitted and coupled at a third point where the first and second examination intersects in the opposite direction to the first wing yarn and is inserted and coupled at a fourth point Conductive seal included.
15. The method of claim 14,

    And the space between the first and second points or the third and fourth points is at least one circular or elliptical space.
16. The method of claim 14,

    And wherein the first point and the third point are the same position, and the second point and the fourth point are the same position.
17. The method of claim 14,

    And the first and third points, and the second and fourth points are spaced apart from each other by at least one circular or elliptical space.
18. A fabric knitted with the conductive thread of claim 11.
19. A fabric knitted with the conductive thread of claim 13.
20. A fabric knitted with the conductive thread of claim 14.
21. The method of claim 18,

    The fabric knitted with the conductive thread is a fabric knitted with a conductive thread, characterized in that the glove or a pattern knitted on the glove made of the conductive thread.
22. The method of claim 19,

    The fabric knitted with the conductive thread is a fabric knitted with a conductive thread, characterized in that the glove or a pattern knitted on the glove made of the conductive thread.
23. The method of claim 20,

    The fabric knitted with the conductive thread is a fabric knitted with a conductive thread, characterized in that the glove or a pattern knitted on the glove made of the conductive thread.

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