ZIPPER-TYPE CIRCUIT FABRIC AND SMART CLOTHES COMPOSED THEREOF

Abstract

A zipper-type circuit fabric and smart clothes composed thereof include a clothes body. The clothes body is made of waterproof conductive fabric body. The waterproof conductive fabric body includes a plurality of conductive wires and conductive contacts. Rectangular elongated conductive media and folded conductive media are arranged inside the conductive wires so that the conductive media are stable and ductile. The clothes body is further provided with a waterproof zipper body. The zipper teeth on the waterproof zipper body are all electrically connected to the conductive wires. When the zipper body is closed, a metal probe on a zipper tooth is placed into a connecting slot so that the left and right sides of the clothes body form a closed circuit. The clothes body can be connected to glove bodies and includes a plurality of flexible sensors internally.

Claims

1. A zipper-type circuit fabric, comprising a conductive fabric body and a zipper body, wherein a plurality of conductive wires and conductive contacts are distributed inside the conductive fabric body, a plurality of conductive contacts being arranged on two sides of the exterior of the zipper body, an end of the conductive fabric body being connected to one side of the zipper body, the plurality of conductive wires and conductive contacts being able to electrically connected to a plurality of electronic components, the conductive fabric body being provided with an insulating fabric waterproof layer, the plurality of conductive contacts and the plurality of conductive wires being distributed on the insulating fabric waterproof layer, a stretchable adhesive coating being arranged on each of the two sides of the conductive wires, the conductive wires being internally provided with a first conductive medium, the first conductive medium including rectangular elongated conductive media and folded conductive media, alternatively the conductive contacts being able to be connected by means of a conductive fabric belt, the upper layer of the conductive fabric belt being an insulating fabric, the middle being provided with a second conductive medium, the lower layer being a stretchable adhesive coating, and the second conductive medium being provided with a plurality of conductive nodes, and the second conductive medium including rectangular elongated conductive media and folded conductive media.

2. The zipper-type circuit fabric according to claim 1, wherein there are a plurality of the folded conductive media with a wavelength of L and an amplitude of M, and a rectangular elongated conductive medium with a length of 2M and a width of M being arranged on the central axis position at each interval of N sawtooth waves.

3. The zipper-type circuit fabric according to claim 2, wherein the conductive wires are connected to the zipper body, one side of the first layer of the zipper body being a reinforcing core, the other side being a zipper fabric belt with a marking position, the second layer being a plurality of parallel striped conductive media with a width of K and perpendicular to the reinforcing core, the distance between the center points of two adjacent parallel striped conductive media being W, the third layer being an insulating layer covering the parallel striped conductive media, and the insulating layer exposing a separate conductive medium with a width of K and the marking position and being laminated/sewn with other conductive wires.

4. The zipper-type circuit fabric according to claim 3, wherein the zipper body is provided with a first tooth and a second tooth, which are distributed left and right in a stagger manner, the upper end of the first tooth being provided with a placement slot, the lower end being provided with a placement block, the placement slots and the placement blocks on different sides forming a structure of left-right staggered buckling, the middle of the second tooth being provided with a metal probe, the middle of the first tooth being provided with a connecting slot, and the metal probe and the connecting slot both being electrically connected to the conductive wires.

5. The zipper-type circuit fabric according to claim 4, wherein outside of the second tooth is an elastic resin zipper tooth, the metal probe being a V-shaped metal clip, the rear end of the V-shaped metal clip having a first clamping portion, the first clamping portion clamping the parallel striped conductive media, outside of the first tooth being a rigid resin zipper tooth, the inner connecting slot being an H-shaped metal clip, the rear end of the H-shaped metal clip having a second clamping portion, and the second clamping portion clamping the parallel striped conductive media.

6. The zipper-type circuit fabric according to claim 4, wherein outside of the second tooth is an elastic resin zipper tooth, the metal probe being a V-shaped metal clip, the rear end of the V-shaped metal clip having a first clamping portion, the first clamping portion clamping the parallel striped conductive media, outside of the first tooth being a rigid resin zipper tooth, the connecting slot being a Y-shaped metal clip, the rear end of the Y-shaped metal clip having a third clamping portion, and the third clamping portion clamping the parallel striped conductive media.

7. The zipper-type circuit fabric according to claim 5, wherein the first conductive medium and the second conductive medium are made of 316L stainless steel metal fiber sewing threads, and the first conductive medium and the second conductive medium forming rectangular elongated conductive media and folded conductive media by the zigzag stitching method.

8. The zipper-type circuit fabric according to claim 5, wherein the first conductive medium and the second conductive medium are made of resilient conductive adhesive and directly laminated on the insulating fabric waterproof layer, the lamination method being soldering, bonding or sewing, and the lower layer being a liftable adhesive coating.

9. A smart clothes composed of the zipper-type circuit fabric as in claim 8, comprising a clothes body and a zipper body, wherein the clothes body is made through tailoring of the conductive fabric body, detachable glove bodies being arranged at the cuffs of the clothes body, a plurality of conductive contacts being arranged at the sleeves of the glove bodies, the conductive contacts being connected to the conductive wires, the front of the clothes body being provided with a zipper body, a plurality of flexible sensors being arranged at the joints of the clothes body and the glove bodies, the flexible sensors being electrically connected to the conductive wires, and a plurality of the conductive contacts distributed in the pockets being electrically connected to external electronic devices.

10. The smart clothes according to claim 9, wherein a plurality of conductive contacts are arranged at the cuffs of the clothes body, and cooperated with a plurality of conductive contacts which being arranged at the sleeves of the glove bodies, a plurality of conductive contacts being arranged at the cuffs of the clothes body and being able to be electrically connected to a flexible screen by means of the zipper teeth, and a Velcro sticker being arranged on the back of the flexible screen and being able to be laminated on the surface of a cuff.

11. The smart clothes according to claim 9, wherein the flexible sensors are flexible capacitive sensors or flexible resistive sensors.

12. The smart clothes according to claim 10, wherein the conductive fabric body and the zipper fabric belt are formed integrally and sprayed on both sides with resilient insulating waterproof organosilicon gel.

13. The zipper-type circuit fabric according to claim 6, wherein the first conductive medium and the second conductive medium are made of 316L stainless steel metal fiber sewing threads, and the first conductive medium and the second conductive medium forming rectangular elongated conductive media and folded conductive media by the zigzag stitching method.

14. The zipper-type circuit fabric according to claim 6, wherein the first conductive medium and the second conductive medium are made of resilient conductive adhesive and directly laminated on the insulating fabric waterproof layer, the lamination method being soldering, bonding or sewing, and the lower layer being a liftable adhesive coating.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0022] In order to more clearly describe the technical solutions in the embodiments of the present utility model, attached drawings that need to be used in the embodiments will be briefly described below. It should be understood that the following attached drawings only show some embodiments of the present utility model, so they should not be deemed as a limitation to the scope. Those of ordinary skill in the art can also obtain other drawings without creative work based on these drawings.

[0023] FIG. 1 is structural schematic view 1 of the present utility model;

[0024] FIG. 2 is structural schematic view 2 of the present utility model;

[0025] FIG. 3 is structural schematic view 3 of the present utility model;

[0026] FIG. 4 is structural schematic view 4 of the present utility model;

[0027] FIG. 5 is structural schematic view 5 of the present utility model;

[0028] FIG. 6 is an enlarged view of Area A in FIG. 5 of the present utility model;

[0029] FIG. 7 is structural schematic view 1 of a zipper fabric belt provided by the present utility model;

[0030] FIG. 8 is structural schematic view 2 of a zipper fabric belt provided by the present utility model;

[0031] FIG. 9 is structural schematic view 3 of a zipper fabric belt provided by the present utility model;

[0032] FIG. 10 is an enlarged view of Area B in FIG. 9 of the present utility model;

[0033] FIG. 11 is structural schematic view 4 of a zipper fabric belt provided by the present utility model;

[0034] FIG. 12 is an enlarged view of Area C in FIG. 11 of the present utility model;

[0035] FIG. 13 is a structural schematic view of a conductive fabric body and a conductive fabric belt provided by the present utility model;

[0036] FIG. 14 is structural schematic view 1 of a zipper body provided by the present utility model;

[0037] FIG. 15 is a structural schematic view of a second tooth provided by the present utility model;

[0038] FIG. 16 is a structural schematic view of a first tooth provided by the present utility model;

[0039] FIG. 17 is structural schematic view 2 of a zipper body provided by the present utility model;

[0040] FIG. 18 is a structural schematic view of a V-shaped metal clip provided by the present utility model;

[0041] FIG. 19 is a structural schematic view of an H-shaped metal clip provided by the present utility model;

[0042] FIG. 20 is structural schematic view 3 of a zipper body provided by the present utility model;

[0043] FIG. 21 is a structural schematic view of a Y-shaped metal clip provided by the present utility model;

[0044] FIG. 22 is a structural schematic view of a clothes body provided by the present utility model;

[0045] FIG. 23 is a schematic view of a deformable capacitor in a flexible capacitive sensor provided by the present utility model;

[0046] FIG. 24 is a schematic view of the circuit of a flexible resistive sensor provided by the present utility model;

[0047] FIG. 25 is a specific structural schematic view of a flexible capacitive sensor;

[0048] FIG. 26 is a specific structural schematic view of a flexible resistive sensor.

[0049] In the figures: conductive fabric body 1, zipper body 2, conductive wire 3, conductive contact 4, insulating fabric waterproof layer 5, first conductive medium 6, rectangular elongated conductive medium 61, folded conductive medium 62, conductive fabric belt 7, second conductive medium 8, conductive node 9, reinforcing core 10, marking position 11, zipper fabric belt 12, parallel striped conductive medium 13, first tooth 14, second tooth 15, placement slot 16, placement block 17, metal probe 18, connecting slot 19, V-shaped metal clip 20, first clamping portion 21, H-shaped metal clip 22, second clamping portion 23, Y-shaped metal clip 24, third clamping portion 25, clothes body 27, glove body 28, conductive electrode layer 29, flexible organosilicon film 30, graphite coated silicone layer 31, flexible capacitive sensor 32, and flexible resistive sensor 33.

DETAILED DESCRIPTION

[0050] For easier understanding of the present utility model, the present utility model will be more comprehensively described below by referring to related attached drawings. The attached drawings show preferred embodiments of the present utility model, but the present utility model can be implemented in many different forms and are not limited to those described herein. On the contrary, the purpose of providing these implementation forms is for clearer and more comprehensive understanding of the content disclosed by the present utility model.

[0051] It should be noted that when it is said that a component is “fixed to” another component, it can be directly on another component or there may be a component between them. When a component is considered to “be connected to” another component, it can be directly connected to another component or there may be a component between them at the same time. Terms “vertical”, “horizontal”, “left”, “right” and similar expressions used herein is for the purpose of illustration only, and do not represent the only implementation form.

[0052] Unless otherwise defined, all technical and scientific terms used herein have the same meanings as those commonly understood by those skilled in the technical field of the present utility model. The terms used in the description of the present utility model herein are only for the purpose of describing specific embodiments and not intended to limit the present utility model. The term “and/or” as used herein includes any and all combinations of one or more relevant listed items.

[0053] Please refer to FIG. 1 to FIG. 26: a zipper-type circuit fabric and smart clothes composed thereof, comprising a conductive fabric body 1, a zipper body 2, flexible capacitive sensors 32, flexible resistive sensors 33, a clothes body 27 and glove bodies 28. The zipper body 2 can be arranged on the two sides of the edges of the conductive fabric body 1 so that the conductive fabric body 1 forms a complete closed circuit. A reliable, flexible and convenient connection solution can be provided for the circuit integration system of rigid electronic components and flexible electronic components of artificial intelligent clothes and other wearable devices. A plurality of conductive wires 3 and conductive contacts 4 are distributed inside the conductive fabric body 1. The conductive contacts 4 are arranged on the conductive wires 3. To facilitate circuit design, a plurality of conductive contacts 4 are arranged on two sides of the exterior of the zipper body 2, and the zipper body 2 is electrically connected to the conductive contacts 4 so that the zipper body 2 has a power-on function. An end of the conductive fabric body 1 is connected to a side of the zipper body 2. The plurality of conductive wires 3 and conductive contacts 4 can be electrically connected to a plurality of electronic components to achieve various functions. The conductive fabric body 1 is provided with an insulating fabric waterproof layer 5 to play an effect of insulation and waterproofing and avoid electric leakage. The plurality of conductive contacts 4 and the plurality of conductive wires 3 are distributed on the insulating fabric waterproof layer 5. A stretchable adhesive-coated waterproof layer is arranged on each of the two sides of the conductive wires 3. The conductive wires 3 are internally provided with a first conductive medium 6. The first conductive medium 6 includes rectangular elongated conductive media 61 and folded conductive media 62. The size and shape of the conductive media are set to achieve different effects and cause the conductive media to be ductile and stable. Alternatively, the conductive contacts 4 can be connected by means of a conductive fabric belt 7. The conductive fabric belt 7 can connect conductive wires at different locations by the methods of single-point abutting, swapping interconnection, overlapping, bifurcating interconnection, convergent interconnection and cornering. The upper layer of the conductive fabric belt 7 is an insulating fabric waterproof layer, the middle is provided with a second conductive medium 8, the lower layer is a stretchable adhesive-coated waterproof layer, and the second conductive medium 8 is provided with a plurality of conductive nodes 9. Different circuits can be formed through interconnection of a plurality of conductive fabric belts. The second conductive medium 8 includes rectangular elongated conductive media 61 and folded conductive media 62.

[0054] Preferably, there are a plurality of the folded conductive media 62 with a wavelength of L and an amplitude of M, and a rectangular elongated conductive medium 61 with a length of 2M and a width of M is arranged on the central axis position at each interval of N sawtooth waves.

[0055] In the foregoing technical solution, the first conductive medium 6 and the second conductive medium 8 typically are conductive metals, conductive cables, conductive inks or conductive adhesives formed by conductive particles. The conductive particles refer to carbon black, graphene, graphite, silver and metal powders, including conductive nanoparticles, etc. The lamination methods with a single conductive point can be soldering, bonding, stitching, etc.

[0056] Preferably, the conductive wires 3 are connected to the zipper body 2, one side of the first layer of the zipper body is a reinforcing core 10, and the other side is a zipper fabric belt 12 with a marking position 11. The second layer is a plurality of parallel striped conductive media 13 with a width of K and perpendicular to the reinforcing core 10. The distance between the center points of two adjacent parallel striped conductive media 13 is W. The third layer is an insulating waterproof layer covering the parallel striped conductive media 13. The insulating waterproof layer is provided with a marking position 11, exposes a separate conductive medium with a width of K, and is electrically connected to a metal clamping portion built in the zipper body.

[0057] In the foregoing technical solution, the reinforcing core 10 is used for strengthening the firmness of the occlusion between the circuit fabric 1 and the zipper teeth 2 for higher durability and tolerance to force. The marking position 11 facilitates the connection of the conductive wires 3. By setting a distance between the center points of two adjacent parallel striped conductive media 13, the two parallel striped conductive media 13 maintain a certain distance, avoiding confusion of wires.

[0058] Preferably, the zipper body 2 is provided with a first tooth 14 and a second tooth 15, which are distributed left and right in a stagger manner. The upper end of the first tooth 14 is provided with a placement slot 16, the lower end is provided with a placement block 17, and the placement slots 16 and placement blocks 17 on different sides form a structure of left-right staggered buckling. The middle of the second tooth 15 is provided with a metal probe 18, the middle of the first tooth 14 is provided with a connecting slot 19, and the metal probe 18 and the connecting slot 19 are both electrically connected to the parallel striped conductive media 13.

[0059] In the foregoing technical solution, the first tooth 14 on a side can be engaged with the first tooth 14 on the other side so that the zipper body 2 is closed, forming a closed circuit. When the first tooth 14 on a side is engaged with the first tooth 14 on the other side, the placement slot 16 is connected to the placement block 17, improving the vertical tensile strength of the zipper body. The second tooth 15 is fit with the first tooth 14, causing the metal probe 18 at the head of the second tooth 15 to be placed into and electrically connected to the connecting slot 19 of the first tooth 14.

[0060] Preferably, outside of the second tooth 15 is an elastic resin zipper tooth, the metal probe 18 is a V-shaped metal clip 20. The rear end of the V-shaped metal clip 20 has a first clamping portion 21. The first clamping portion 21 clamps the parallel striped conductive media 13. Outside of the first tooth 14 is a rigid resin zipper tooth. The connecting slot 19 is an H-shaped metal clip 22. The rear end of the H-shaped metal clip 22 has a second clamping portion 23. The second clamping portion 23 clamps the parallel striped conductive media 13.

[0061] In the foregoing technical solution, the first tooth 14 and the second tooth 15 are molded through injection molding, and the elastic resin zipper tooth of the second tooth 15 is closely engaged with the rigid resin zipper tooth of the first tooth 14 to enhance the waterproofness of the zipper body and to maintain the flexibility of the zipper body 2 as well. The V-shaped metal clip 20 and the H-shaped metal clip 22 are arranged inside the second tooth 15 and the first tooth 14. Through the wrapping of the first tooth 14 and the second tooth 15, the external surface of the zipper 2 is under insulating waterproof treatment to avoid electric leakage or short circuit. The first clamping portion 21 and the second clamping portion 23 ensure that the V-shaped metal clip 20 and the H-shaped metal clip 22 form a stable electrical connection with the parallel striped conductive media 13 and after the zipper 2 is closed, the electrical conduction is stable.

[0062] Preferably, the second tooth 15, which is made of resin for its external part is a plastic-steel zipper tooth. The metal probe 18 is a V-shaped metal clip 20. The rear end of the V-shaped metal clip 20 has a first clamping portion 21. The first clamping portion 16 clamps the parallel striped conductive media 31. The first tooth 14, which is made of resin for its external part is a plastic-steel zipper tooth. The connecting slot 19 is a Y-shaped metal clip 24. The rear end of the Y-shaped metal clip 24 has a third clamping portion 25. The third clamping portion 25 clamps the parallel striped conductive media 13.

[0063] In the foregoing technical solution, the first tooth 14 and the second tooth 15 are molded through injection molding, and the elastic resin zipper tooth of the second tooth 15 is closely engaged with the rigid resin zipper tooth of the first tooth 14 to enhance the waterproofness of the zipper body and to maintain the flexibility of the zipper body 2 as well. The V-shaped metal clip 20 and the Y-shaped metal clip 24 are arranged inside the second tooth 15 and the first tooth 14. Through the wrapping of the first tooth 14 and the second tooth 15, the external surface of the zipper 2 is under insulating waterproof treatment to avoid electric leakage or short circuit. The first clamping portion 21 and the second clamping portion 23 ensure that the V-shaped metal clip 20 and the Y-shaped metal clip 24 form a stable electrical connection with the parallel striped conductive media 13 and after the zipper 2 is closed, the electrical conduction is stable.

[0064] Preferably, the first conductive medium 6 and the second conductive medium 8 are made of 316L stainless steel metal fiber sewing threads. The first conductive medium 6 and the second conductive medium 8 form rectangular elongated conductive media 61 and folded conductive media 62 by the zigzag stitching method.

[0065] In the foregoing technical solution, 316L is widely used in the chemical industry because of its excellent corrosion resistance. 316L is also a stainless-steel derivative of 18-8 austenitic stainless steel, with 2 to 3% element Mo added. On the basis of 316L, many steel grades have been derived, such as 316Ti by adding a small amount of Ti, 316N by adding a small amount of N, and 317L by increasing the content of Ni and Mo. Using 316L stainless steel metal fiber as sewing threads causes the first conductive medium 6 and the second conductive medium 8 to have good electrical conductivity and corrosion resistance. In daily use, the conductive fabric body 1 can be washed with water and does not come off easily.

[0066] Preferably, the first conductive medium 6 and the second conductive medium 8 are made of resilient conductive adhesive and directly laminated on the insulating fabric waterproof layer 5, and the lower layer is a liftable adhesive waterproof coating.

[0067] In the foregoing technical solution, the resilient conductive adhesive adopts 60-80% conductive particles, 20-30% adhesive, and 5-10% gelling agent. The conductive adhesive can be laminated directly to the bottom of the insulating fabric waterproof layer 5, forming stretchable elongated conductive media. The lamination method can be soldering, bonding or sewing, etc. The lower layer is a stretchable adhesive coating.

[0068] Preferably, the clothes body 27 is made through tailoring of the conductive fabric body 1, detachable glove bodies 28 are arranged at the cuffs of the smart clothes body 27, and the zipper teeth on a side of a zipper body 2 arranged at the sleeve of a glove body 28 are electrically connected to the zipper teeth on the other side of the zipper body 2 arranged at the clothes body 27. A plurality of flexible sensors are arranged at the joints of the clothes body 27 and the glove bodies 28, and electrically connected to the zipper teeth on a side of the zipper body 2 by means of the conductive wires 3 of the conductive fabric body 1, and the zipper teeth on the other side of the zipper body 2 are electrically connected to external electronic devices by means of the conductive wires 3 of the conductive fabric body 1.

[0069] In the foregoing technical solution, a plurality of conductive wires 3 are arranged inside the clothes body 27, forming different circuits. The glove bodies 28 can be electrically connected to the clothes body 27, achieving data transmission. Through the clothes body 27, the glove bodies 28, the zipper body 2 and the flexible sensors, the clothes body 27 can sense activities of the human body and achieve to report electrical signals to a controller. By electrically connecting a plurality of conductive wires 3 arranged inside a pocket to different devices, the functions like body movement analysis, health monitoring and man-machine interaction can be achieved.

[0070] Preferably, the zipper body at each cuff of the clothes body 27 can also be electrically connected to a flexible screen. The flexible screen establishes an electrical connection with the zipper teeth on the two sides of the zipper body 2 by means of the conductive fabric body 1, and a Velcro sticker is arranged on the back of the flexible screen. During use, the flexible screen is laminated with the external surface of the cuff, and then the zipper is pulled to close the zipper body.

[0071] In the foregoing technical solution, the clothes body 27 can connect the flexible screen and cause the flexible screen to be attached to a cuff of the clothes body 27, achieving data transmission between the flexible screen and the clothes body 27.

[0072] The flexible material for flexible sensors is a concept opposite to a rigid material. Generally, flexible materials have properties such as softness, low modulus and easy deformation. Common flexible materials include: polyvinyl alcohol (PVA), polyester (PET), paper sheets and textile material, etc. Flexible sensors are sensors made of flexible materials, have good flexibility and ductility, can be freely bent or even folded, adopt flexible and diverse structural forms and can be freely arranged according to the requirements of the measurement conditions to achieve easy measurement and detection. New types of flexible sensors are widely used in electronic skin, healthcare, electronic engineering, sports equipment, textiles, aeronautics and astronautics, environmental monitoring and other fields.

[0073] Flexible sensors include flexible pressure sensors, flexible gas sensors, flexible humidity sensors, flexible temperature sensors, flexible strain sensors, flexible magnetic impedance sensors and flexible heat flow sensors. According to the sensing mechanisms, flexible sensors include flexible resistive sensors, flexible capacitive sensors, flexible piezomagnetic sensors and flexible inductive sensors.

[0074] The flexible sensors are flexible capacitive sensors or flexible resistive sensors.

[0075] By referring to FIG. 22 and FIG. 23, the flexible sensors in the present utility model are flexible capacitive sensors 32. The conductive electrode layer 29 is a conductive layer. The flexible organosilicon film 30 is a flexible organosilicon film made of electroactive polymer (not electrically conductive).

[0076] In the foregoing technical solution, the flexible capacitive sensors are suitable for monitoring pressure over large human body area, such as center of palm, and back, etc. Each flexible capacitive sensor is a parallel-plate capacitor consisting of electrodes and a dielectric layer, with a capacitance value C=E*R*A/d, where E is a vacuum dielectric constant, R is a relative dielectric constant, A is an effective area of electrode, and d is distance between electrode plates. When the capacitor is made of a soft material, the three variables of the capacitance value are liable to be affected by pressure. When the pressure increases, the dielectric layer gets thinner, the effective area of the electrodes gets larger, and the distance between the electrode plates gets smaller. Change in capacitance can be detected in the process of deformation under the condition of a voltage applied. Therefore, the pressure can be measured based on the change of capacitance signal, and the pressure at the center of palm or on the back can be monitored, thereby determining the posture of the human body, such as propping up on the ground, and lying down.

[0077] By referring to FIG. 22 and FIG. 24, alternatively, the flexible sensors in the present utility model can be flexible resistive sensors 33.

[0078] In the foregoing technical solution, flexible resistive sensors are suitable for monitoring the bending displacement of small parts of the body, such as fingers, elbows and wrists. In the flexible resistive sensors, the distance between conductive particles is very short. When a sensor is kept straight, the resistance is low. But when it is bent, the distance between the particles increases, resulting in an increase in resistance and a decrease in current. The formula for output voltage Vo is Vo=Vi(R1/(R1+R2)), where Vi is input voltage, 5V in general, R1 is the resistance value of the flexible resistive element, and R2 is the resistance value of the fixed resistor. When the resistive element is bent, change will occur in the resistance value R1. When the input voltage is fixed, the output voltage will change according to the degree of bending of the resistive element, so that the bending activities of the human body parts such as fingers, elbows and wrists can be monitored, thereby determining movements such as gripping and hand turning.

[0079] Preferably, the conductive fabric body 1 and the zipper fabric belt 12 are formed integrally and sprayed on both sides with resilient insulating waterproof organosilicon gel.

[0080] In the foregoing technical solution, the insulating waterproof organosilicon gel has the same characteristics as other silicone, such as high temperature resistance, UV resistance, insulation and hydrophobicity, and can effectively isolate moisture. Further, the internal circuit components can be wrapped with waterproof breathable films to better protect the circuit.

[0081] Preferably, the zipper body 2 is a waterproof zipper body, and the internals of the elastic resin zipper teeth and the rigid resin zipper teeth are highly closely engaged and waterproof.

[0082] In the foregoing technical solution, when the smart clothes need to be washed, the electronic device can be removed through the zipper, avoiding the problem that water enters the electronic device during wash of the clothes body.

[0083] By referring to FIG. 25, the flexible capacitive sensors 32 have the following structure: in two square conductive fabric bodies 1, a plurality of the conductive contacts 4 of the first conductive medium 6 are electrically connected in parallel to form an upper conductive electrode layer 29 and a lower conductive electrode layer 29 relative to the middle dielectric layer, which is made of an organosilicon material. The middle flexible organosilicon film 30 and the upper and lower first conductive medium 6 layers jointly constitute a flexible capacitor, which can absorb and store electric charges. When being squeezed under a pressure, the conductive fabric body 1 and the flexible organosilicon film 30 both become thinner and wider together, and the capacitance changes.

[0084] By referring to FIG. 26, the flexible resistive sensors 33 have the following structure, of the two conductive wires 3 adjacent to the conductive fabric body 1, one is a voltage input terminal, and the other is a voltage output terminal. A graphite coated silicone layer 31 with certain conductivity is arranged over the first conductive medium 6. The graphite coated silicone layer 31 as a flexible resistive element is flexible and stretchable. When the conductive fabric body 1 and the graphite coated silicone layer 31 are bent together, the output voltage will change.

[0085] Working principle: The clothes body 27 is made through tailoring of the conductive fabric body 1. A plurality of conductive wires 3 and conductive contacts 4 are arranged on the conductive fabric body 1, the middle of the clothes body 27 is provided with a zipper body 2, zipper bodies 2 are arranged at cuffs and pockets, flexible sensors are arranged inside the clothes body 27, i.e., the joints of human body, and flexible sensors are arranged inside the glove bodies 28, i.e., the joints of palms to sense movements of the human body.

[0086] During use, after the clothes body 27 is worn, one side of the zipper body arranged at the sleeve of each glove body 28 is connected to the other side of the zipper body 2 arranged at a cuff of the clothes body 27 for closure, thereby achieving data inter-communication between the glove bodies 28 and the clothes body 27. When the zipper body 2 is closed, the metal probe 18 and the connecting slot 19 are engaged with each other so that the V-shaped metal clip 20 is placed into the H-shaped metal clip 22 or the Y-shaped metal clip 24, the left and right sides of the clothes body 27 constitute a circuit, and electrical signals corresponding to movements of the human body are transmitted through flexible sensors to a microprocessor, thereby identifying movements of the human body, sending data to the cloud/a controller and achieving different feedbacks.

[0087] The foregoing embodiments only represent the preferred embodiments of the present utility model. Their descriptions are concrete and detailed, but they shall not be therefore understood as limitations to the scope of the present utility model patent. It shall be noted that for those skilled in the art, various changes and modifications may be made to the embodiments without departing from the spirit of the present utility model, such as: combinations of different features of the embodiments. All these shall be in the protective scope of the present utility model. Therefore, the protection scope of the present utility model patent should be based on the appended claims.