CN114947790A

CN114947790A - Wrist strap equipment

Info

Publication number: CN114947790A
Application number: CN202210325280.8A
Authority: CN
Inventors: 王军委; 于新亮; 张超
Original assignee: Goertek Techology Co Ltd
Current assignee: Goertek Techology Co Ltd
Priority date: 2022-03-30
Filing date: 2022-03-30
Publication date: 2022-08-30

Abstract

The invention discloses a wrist strap device, which is applied to the field of intelligent wearable devices and comprises the following components: the wrist strap touch control system comprises a light-emitting fabric arranged in a wrist strap display area, a touch control fabric arranged in a wrist strap touch control area and a processor; the luminous fabric comprises first luminous yarns and second luminous yarns, wherein the first luminous yarns and the second luminous yarns are arranged in a crossed mode to form at least 1 luminous cross point, and the luminous cross point is a luminous pixel point in a display area of the wrist strap; the touch fabric comprises first conductive yarns and second conductive yarns, wherein the first conductive yarns and the second conductive yarns are arranged in a crossed mode to form at least 1 touch cross point, and the touch cross point is a pressure acquisition point in a wrist strap detection area; according to the invention, the touch and display functions of the wrist strap equipment can be realized through the arrangement of the touch fabric and the light-emitting fabric in the wrist strap equipment, and the wearing comfort of the wrist strap equipment can be improved because the touch fabric and the light-emitting fabric have the characteristics of textiles.

Description

Wrist strap equipment

Technical Field

The invention relates to the field of intelligent wearable equipment, in particular to wrist strap equipment.

Background

The textile is visible everywhere in our life, including the appearance package of various clothes and consumer products in daily life, and the like, and the textile is widely known by users by the characteristics of elasticity, softness, easy stretchability, comfort and the like. However, the textile has inherent disadvantages that the textile can only be used as a protective mesh or in other existing forms, and cannot interact with a control layer, so that functional electronic devices such as keys and screens must be added to become consumer goods.

At present, electronic equipment such as a key, a touch screen and a display screen is mostly adopted in common wrist strap equipment with touch control and display functions, so that wearing comfort of the wrist strap equipment is poor. Therefore, how to utilize the characteristic of the wearing comfort of textiles on the basis of realizing the touch and display functions of the wrist strap equipment, the wearing comfort of the wrist strap equipment is improved, and the problem which needs to be solved urgently is solved nowadays.

Disclosure of Invention

The invention aims to provide wrist strap equipment, which is used for improving the wearing comfort of the wrist strap equipment on the basis of realizing the touch and display functions of the wrist strap equipment through the arrangement of touch fabric and luminous fabric.

To solve the above technical problem, the present invention provides a wristband apparatus, comprising: the wrist strap touch control system comprises a light-emitting fabric arranged in a wrist strap display area, a touch control fabric arranged in a wrist strap touch control area and a processor;

the luminous fabric comprises first luminous yarns and second luminous yarns, wherein a plurality of first luminous yarns and a plurality of second luminous yarns are arranged in a crossed mode to form at least 1 luminous cross point, and the luminous cross point is a luminous pixel point in the display area of the wrist strap;

the touch fabric comprises first conductive yarns and second conductive yarns, wherein the first conductive yarns and the second conductive yarns are arranged in a crossed mode to form at least 1 touch cross point, and the touch cross point is an pressure acquisition point in the wrist strap detection area and is used for acquiring resistance information corresponding to pressure information of the pressure acquisition point;

the processor is used for acquiring a touch instruction according to the resistance information of the pressure acquisition point; and controlling the lighting and closing of the luminous pixel points according to the acquired display information so as to display the display information.

Optionally, the knitting direction of the first luminescent yarn is perpendicular to that of the second luminescent yarn, and an insulating yarn is arranged between two adjacent first luminescent yarns or two adjacent second luminescent yarns; the weaving direction of the first conductive yarns is perpendicular to that of the second conductive yarns, and insulating yarns are arranged between every two adjacent first conductive yarns or second conductive yarns.

Optionally, the wristband display area is the same as the wristband touch area, the first light-emitting yarns and the first conductive yarns are woven in a warp direction, and the second light-emitting yarns and the second conductive yarns are woven in a weft direction; the first luminescent yarns and the first conductive yarns are alternately arranged, and the insulating yarns are arranged between the adjacent first luminescent yarns and the adjacent first conductive yarns; the second luminous yarns and the second conductive yarns are alternately arranged, and the insulating yarns are arranged between the adjacent second luminous yarns and the second conductive yarns.

Optionally, the wrist strap touch area is arranged below the wrist strap display area along a wrist strap annular direction.

Optionally, the method includes: an elastically stretched region and an inelastic region; wherein the inelastic zone comprises the wristband display area and the wristband touch area; the elastic stretching area is provided with elastic fabrics for adjusting the wearing tight fit force of the wrist strap equipment.

Optionally, the first conductive yarn and the second conductive yarn each include: the resistance induction device comprises a conductive core wire and a resistance induction part which covers the surface of the conductive core wire in a preset structure.

Optionally, the wristband device further comprises: a voltage dividing resistor;

the first end of each voltage-dividing resistor is connected with a direct-current power supply, the second end of each voltage-dividing resistor is connected with one end of the corresponding touch intersection, the connected public end is connected with the processor, and the other end of the touch intersection is grounded.

Optionally, the first luminescent yarn and the second luminescent yarn each include a conductive core wire, an inorganic luminescent part, and a bonding part between the conductive core wire and the inorganic luminescent part; wherein the inorganic light emitting member is covered on the surfaces of the conductive core wire and the bonding member with a predetermined covering structure.

Optionally, the wristband device further comprises: a first controllable switch and a second controllable switch;

a first end of each first controllable switch is connected with an alternating current power supply, a second end of each first controllable switch is connected with one end of a corresponding light-emitting cross point, the other end of the light-emitting cross point is grounded through a corresponding second controllable switch, and control ends of the first controllable switch and the second controllable switch are connected with the processor.

Optionally, the wristband device further comprises: the heart rate acquisition fabric is arranged in the heart rate acquisition area;

the heart rate acquisition fabric comprises third conductive yarns and fourth conductive yarns, wherein the third conductive yarns and the fourth conductive yarns are arranged in a crossed mode to form at least 1 heart rate acquisition cross point, and the heart rate acquisition cross point is a heart rate acquisition point in the heart rate acquisition area and is used for acquiring resistance information corresponding to the heart rate information of the heart rate acquisition point.

The present invention provides a wristband apparatus, including: the wrist strap touch control system comprises a light-emitting fabric arranged in a wrist strap display area, a touch control fabric arranged in a wrist strap touch control area and a processor; the luminous fabric comprises first luminous yarns and second luminous yarns, wherein the first luminous yarns and the second luminous yarns are arranged in a crossed mode to form at least 1 luminous cross point, and the luminous cross point is a luminous pixel point in a display area of the wrist strap; the touch fabric comprises first conductive yarns and second conductive yarns, wherein the first conductive yarns and the second conductive yarns are arranged in a crossed mode to form at least 1 touch cross point, and the touch cross point is a pressure acquisition point in a wrist strap detection area and is used for acquiring resistance information corresponding to pressure information of the pressure acquisition point; the processor is used for acquiring a touch instruction according to the resistance information of the pressure acquisition points; controlling the lighting and closing of the luminous pixel points according to the acquired display information so as to display the display information;

therefore, the touch and display functions of the wrist strap equipment can be realized through the arrangement of the touch fabric and the light-emitting fabric in the wrist strap equipment, and the wearing comfort of the wrist strap equipment can be improved due to the fact that the touch fabric and the light-emitting fabric have the characteristics of textiles, so that the use experience of a user is improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.

Fig. 1 is a block diagram of a wristband apparatus according to an embodiment of the present invention;

fig. 2 is a schematic diagram of a light-emitting control circuit of a wristband apparatus according to an embodiment of the present invention;

fig. 3 is a schematic view of a light-emitting yarn of a wristband apparatus according to an embodiment of the present invention;

FIG. 4 is a schematic view of another light-emitting yarn of the wristband apparatus according to an embodiment of the present invention;

FIG. 5 is a schematic diagram of a pressure acquisition circuit of a wrist band apparatus according to an embodiment of the present invention;

FIG. 6 is a schematic view of conductive yarns of a wristband apparatus according to an embodiment of the invention;

fig. 7 is a schematic diagram of a hybrid fabric structure of a wristband apparatus according to an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. All other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

Referring to fig. 1, fig. 1 is a schematic structural diagram of a wristband apparatus according to an embodiment of the present invention. The wristband device may include: the light-emitting fabric 10 is arranged in a display area of the wrist strap, the touch fabric 20 is arranged in a touch area of the wrist strap, and the processor 30;

the luminous fabric 10 comprises first luminous yarns and second luminous yarns, wherein a plurality of first luminous yarns and a plurality of second luminous yarns are arranged in a crossed mode to form at least 1 luminous cross point, and the luminous cross point is a luminous pixel point in a display area of the wrist strap;

the touch fabric 20 comprises first conductive yarns and second conductive yarns, wherein the first conductive yarns and the second conductive yarns are arranged in a crossed manner to form at least 1 touch cross point, and the touch cross point is a pressure acquisition point in a wrist strap detection area and is used for acquiring resistance information corresponding to pressure information of the pressure acquisition point;

the processor 30 is configured to obtain a touch instruction according to the resistance information of the pressure collection point; and controlling the lighting and closing of the luminous pixel points according to the acquired display information so as to display the display information.

It is understood that the light-emitting textile 10 disposed in the wristband display area in the present embodiment may include a first light-emitting yarn and a second light-emitting yarn, the first light-emitting yarn and the second light-emitting yarn are disposed in a crossed manner in the textile structure to form a crossover (i.e., a light-emitting crossover), so that when an alternating current is applied to the first light-emitting yarn and the second light-emitting yarn, an electric field is formed at the light-emitting crossover, and inorganic light-emitting layers capable of exciting the first light-emitting yarn and the second light-emitting yarn at positions covered by the electric field (i.e., light-emitting crossovers) form light-emitting points (i.e., light-emitting pixel points); accordingly, the processor 30 may perform on-off control of the light-emitting pixel points of the light-emitting fabric 10 in the display area of each wristband through the display driving, thereby implementing display control of the graphics or the text.

That is to say, in this embodiment, two ends of each light-emitting intersection (e.g., a field-control light-emitting pixel point in fig. 2) formed by the crossing arrangement of the first light-emitting yarns and the second light-emitting yarns in the light-emitting fabric 10 may be respectively connected to an ac power supply (e.g., a high-voltage ac power supply in fig. 2) through a corresponding controllable switch (e.g., an optical coupler switch), so that the processor 30 (e.g., a micro control unit MCU in fig. 2) may control the on and off of the light-emitting intersections (i.e., the light-emitting pixel points) by controlling the controllable switches at the two ends of the light-emitting intersections. As shown in fig. 2, the high voltage dc power source connected to the two ends of the field emission pixel (i.e. the light emission cross point) through the controllable switch can provide a high voltage ac signal. So as to meet the voltage and current driving requirements of the controllable switch; although the high-voltage alternating current signal has high voltage, according to the field system luminescence principle, the high-voltage does not generate current in the luminescence process of the field system luminescence pixel point, even if the current is generated, the current is only leakage current, and the current is in nA level.

Correspondingly, the wrist strap device provided by the embodiment may further include a first controllable switch and a second controllable switch; a first terminal of each first controllable switch is connected to the ac power source, a second terminal of each first controllable switch is connected to one terminal of the corresponding light emitting intersection, the other terminal of the light emitting intersection is grounded through the corresponding second controllable switch, and control terminals of the first controllable switch and the second controllable switch are connected to the processor 30.

Correspondingly, the wrist strap device provided by the embodiment may further include a high-voltage ac power supply, for example, the high-voltage ac power supply may include an inverter circuit for converting a dc signal of a battery in the wrist strap device into a high-voltage ac signal, such as an ac signal greater than or equal to 100V.

Further, the wristband device provided by the embodiment may further include an IO expansion chip; the processor 30 may be connected to the control ends of the first controllable switch and the second controllable switch through an IO expansion chip; as shown in fig. 2, the IO expansion chip connected to the MCU may expand an IO port of the MCU when the IO port (e.g., a digital IO port) is insufficient.

Specifically, for the specific yarn structures of the first luminescent yarn and the second luminescent yarn in the luminescent fabric 10 in this embodiment, the yarn structures may be set by the designer according to the practical situation and the user requirement, as shown in fig. 3 and 4, each of the first luminescent yarn and the second luminescent yarn may include a conductive core wire, an inorganic luminescent part of an inorganic luminescent layer, and a bonding part of a bonding layer between the conductive core wire and the inorganic luminescent part. Wherein the bonding member of the bonding layer may bond the conductive core wire and the inorganic luminescent layer to activate an electroluminescent function of the inorganic luminescent layer; the inorganic matter luminous component covers the surfaces of the conductive core wire and the combination component in a preset covering structure so as to generate luminous points on the surface of the inorganic matter luminous component by the principle of electroluminescence; as shown in fig. 3, the inorganic light emitting member may be coated on the surfaces of the conductive core wire and the bonding member in a spiral structure, i.e., the predetermined coating structure may be a spiral structure; as shown in fig. 4, the inorganic luminescent component may also be covered on the surfaces of the conductive core wire and the bonding component in a tubular structure, i.e. the predetermined covering structure may also be a tubular structure; the predetermined covering structure may also adopt other structures such as a double spiral structure, and the embodiment does not limit this. Likewise, the present embodiment does not limit the specific material types of the first luminescent yarn and the second luminescent yarn, for example, the conductive core wires in the first luminescent yarn and the second luminescent yarn may be silver-plated fiber conductors or metal wires.

It should be noted that, in this embodiment, the touch fabric 20 disposed in the touch area of the wristband may include first conductive yarns and second conductive yarns, and the first conductive yarns and the second conductive yarns are disposed in a crossed manner in a fabric structure to form intersections (i.e., touch intersections), so that when the first conductive yarns and the second conductive yarns are energized, sensing points (i.e., pressure collection points) may be formed at positions of the touch intersections, and each sensing point may perform pressure detection at a corresponding position through pressure sensing; the principle of pressure sensing can be that at each pressure acquisition point, the crossed first conductive yarn and the second conductive yarn can form a resistance area which is in up-and-down contact, the resistance area can acquire the change of the pressure at the position, and the resistance of the resistance area is smaller when the pressure is larger, so that the pressure sensing acquisition at the position is completed.

Specifically, as shown in fig. 5, in this embodiment, each touch intersection (pressure sensing collection pixel) formed by crossing a plurality of first conductive yarns and a plurality of second conductive yarns in the touch fabric 20 may be connected to a current source (e.g., a constant current source) through a corresponding voltage-dividing resistor, so as to convert a resistance change signal (i.e., resistance information) corresponding to pressure information of the touch intersection into a voltage signal, so that the processor 30 may obtain the resistance change signal of the touch intersection according to the received voltage signal; further, in this embodiment, the current source connected to the touch cross point may be a constant current source, so that the processor 30 can obtain a relatively accurate voltage signal by using the constant current source, and meanwhile, the processor 30 can obtain an initial voltage signal value with a required appropriate size by adjusting the output current of the constant current source.

Correspondingly, the wrist strap device provided by the embodiment may further include a voltage dividing resistor; a first end of each voltage dividing resistor is connected to a dc power supply (e.g., a 3.3V dc power supply), a second end of each voltage dividing resistor is connected to one end of a corresponding touch intersection, and a common end of the connection is connected to the processor 30, and the other end of the touch intersection is grounded.

Further, as shown in fig. 5, the wrist band device provided in this embodiment may further include a multi-way switch; the common end of each divider resistor connected to the corresponding touch cross point can be connected to the MCU (i.e., the processor 30) through the corresponding multi-way switch, so that the MCU can select the pressure sensing channel in a scanning manner, thereby saving an Analog-to-Digital Converter (ADC) interface; correspondingly, the MCU can acquire the resistance information of the pressure acquisition point corresponding to the voltage signal received by the ADC interface by using the analog-to-digital conversion circuit.

Specifically, for the specific yarn structures of the first conductive yarn and the second conductive yarn in the touch fabric 20 in this embodiment, the yarn structures can be set by a designer according to a practical scene and a user requirement, for example, the first conductive yarn and the second conductive yarn may include a conductive core wire and a resistance sensing component of a resistance sensing layer; the resistance sensing component can cover the surface of the conductive core wire in a preset structure; as shown in fig. 6, the resistance sensing part may be covered on the surface of the conductive core wire in a spiral structure, that is, the preset structure may be a spiral structure; the predetermined structure may also adopt other structures such as a tubular structure or a double spiral structure, and the present embodiment does not limit this. Likewise, the present embodiment does not limit the specific material types of the first conductive yarn and the second conductive yarn, and for example, the conductive core wires in the first conductive yarn and the second conductive yarn may be silver-plated fiber wires or metal wires.

It can be understood that, for the specific fabric structure in the light-emitting fabric 10 in the present embodiment, that is, the specific crossing manner between the first light-emitting yarns and the second light-emitting yarns, can be set by the designer according to the use scenario and the user requirement, for example, the weaving directions of the first light-emitting yarns and the second light-emitting yarns can be perpendicular; for example, the first luminescent yarn in the luminescent fabric 10 may be woven in the warp direction, and the second luminescent yarn may be woven in the weft direction; accordingly, the first luminescent yarn and the second luminescent yarn may cross in a criss-cross overlapping manner to form a luminescent crossover point. Similarly, the specific fabric structure of the touch fabric 20 in the light-emitting fabric 10 in this embodiment may be set in the same or similar manner as the fabric structure of the light-emitting fabric 10, and this embodiment also does not set any limitation.

Correspondingly, for the specific arrangement manner of the light-emitting fabric 10 and the touch fabric 20 in the wristband device in this embodiment, the arrangement manner may be set by a designer, for example, the light-emitting fabric 10 and/or the touch fabric 20 may be woven fabrics attached to the surface or the inside of the corresponding area of the wristband device body; the light emitting fabric 10 and/or the touch fabric 20 may also be a fabric woven on the body of the wristband device at a corresponding area of the woven fabric. The present embodiment does not set any limit to this.

Specifically, the specific region selection of the wristband display region and the wristband touch region in the embodiment, that is, the specific setting positions of the light-emitting fabric 10 and the wristband touch fabric 20, may be set by a designer according to a practical scene and user requirements, for example, the wristband display region and the wristband touch region may be the same region, that is, one region of the wristband device can simultaneously implement touch and display functions; for example, an area of the wristband device may be simultaneously woven with the first and second light-emitting yarns of the light-emitting fabric 10 and the first and second conductive yarns of the touch fabric 20, so that a light-emitting pixel point and an pressure collection point exist in the area at the same time; a light-emitting fabric 10 and a touch fabric 20 may be attached to an area of the wristband device at the same time, for example, when the light-emitting fabric 10 and the touch fabric 20 are the same woven fabric, the woven fabric may cover the surface layer of the area; when the light-emitting textile 10 and the touch textile 20 are different woven textiles, the light-emitting textile 10 may cover a surface layer of the area, and the touch textile 20 may be embedded under the surface layer. The wristband display area and the wristband touch area may also be different areas, for example, the wristband touch area may be disposed below the wristband display area along the annular direction of the wristband, so that when a user wears the wristband device, the displayed display information may be viewed in the wristband display area, and touch operation is performed in the wristband touch area below the wristband display area; for example, the wristband touch area may be disposed below the wristband display area in a circular direction of the wristband and in adjacent contact with the wristband display area.

Correspondingly, for the specific knitting manner of the first luminescent yarn and the second luminescent yarn in the luminescent fabric 10 and the first conductive yarn and the second conductive yarn in the touch fabric 20 in this embodiment, the specific knitting manner may be set by a designer, for example, insulating yarns may be disposed between two adjacent first luminescent yarns and between two adjacent second luminescent yarns, and insulating yarns may be disposed between two adjacent first conductive yarns and between two adjacent second conductive yarns, so as to reduce the interference of electrical signals between the yarns; for example, the display area of the wrist band is the same as the touch area of the wrist band, when the first light-emitting yarns and the first conductive yarns are woven in the first direction and the second light-emitting yarns and the second conductive yarns are woven in the second direction, the first light-emitting yarns and the first conductive yarns may be alternately arranged, and insulating yarns may be arranged between the adjacent first light-emitting yarns and the first conductive yarns; the second luminous yarns and the second conductive yarns can be alternately arranged, and insulating yarns are arranged between the adjacent second luminous yarns and the second conductive yarns so as to avoid electric signal interference between the yarns with two different functions. As shown in fig. 7, when the first luminescent yarn and the first conductive yarn are woven in the warp direction and the second luminescent yarn and the second conductive yarn are woven in the weft direction, the warp direction and the weft direction may be respectively arranged according to the sequence of the insulating yarn (cloth yarn) -conductive yarn (sensing yarn, i.e., first conductive yarn or second ear conductive yarn) -insulating yarn-luminescent yarn (i.e., first luminescent yarn or second luminescent yarn) -insulating yarn … ….

Specifically, the processor 30 in this embodiment may include a pressure sensing signal acquisition MCU and a light emitting display processing MCU; the pressure sensing signal acquisition MCU can be used for acquiring a voltage signal of each pressure acquisition point in a progressive scanning mode and processing the voltage signal to obtain corresponding resistance information data; comparing the acquired resistance information data with a preset threshold value, and determining the pressing condition of a pressure acquisition point; the light-emitting display processing MCU can be used for controlling the IO port corresponding to each light-emitting pixel point according to the display instruction corresponding to the pressing condition, controlling the light-emitting pixel points corresponding to each light-emitting pixel point to emit light in a line-by-line scanning mode, and finishing static or dynamic display of the set image. The pressure sensing signal acquisition MCU and the light emitting display processing MCU may also be the same MCU, which is not limited in this embodiment.

Further, the wrist strap device provided by the embodiment may further include a heart rate acquisition fabric disposed in the heart rate acquisition area; the heart rate acquisition fabric can comprise third conductive yarns and fourth conductive yarns, the plurality of third conductive yarns and the plurality of fourth conductive yarns are arranged in a crossed mode to form at least 1 heart rate acquisition cross point, and the heart rate acquisition cross point is a heart rate acquisition point in a heart rate acquisition area and is used for acquiring resistance information corresponding to the heart rate information of the heart rate acquisition point; that is to say, the heart rate collecting point in this embodiment can collect the pressure signal (i.e. heart rate information), and convert the pressure signal into corresponding resistance information.

Because the heart rate collecting principle of the heart rate collecting fabric in the embodiment is similar to the pressure collecting principle of the touch fabric 20, the specific fabric structure of the heart rate collecting fabric in the embodiment can be set in the same or similar mode as the touch fabric 20, and the embodiment does not limit the structure.

Specifically, to the specific region of the heart rate acquisition region in this embodiment, can be set by the designer according to practical scene and user's demand by oneself, if gather the accuracy in order to improve the heart rate of heart rate acquisition fabric, the heart rate acquisition region in this embodiment can set up the inboard region of wearing the wrist at wrist strap equipment, namely the region on the wrist strap equipment that the wrist inboard corresponds when the user wears wrist strap equipment.

Note that the wristband device in this embodiment may include an elastic stretch area and an inelastic area; wherein, the elastic stretching area can be provided with elastic fabrics for adjusting the wearing closing force of the wrist strap equipment. Specifically, the wrist band display area, the wrist band touch area and/or the heart rate acquisition area in the embodiment may be disposed in an inelastic area to ensure stability of the display, touch and/or heart rate acquisition functions of the wrist band device; the wristband display area, the wristband touch area and/or the heart rate acquisition area in this embodiment may also be disposed in the elastic stretch area, for example, when the wristband touch area is disposed in the elastic stretch area, if the elastic fabric is an elastic cord woven fabric, one or more strands of conductive yarn (i.e., the first conductive yarn or the second conductive yarn) may be spun on the surface of each elastic cord, and a crossing point between the elastic cords may be used as a pressure acquisition point. The present embodiment does not set any limit to this.

In this embodiment, the touch and display functions of the wristband device can be realized by the arrangement of the touch fabric 20 and the light-emitting fabric 10 in the wristband device, and the wearing comfort of the wristband device can be improved due to the fact that the touch fabric 20 and the light-emitting fabric 10 have the characteristics of textiles, so that the use experience of a user is improved.

A wrist band apparatus provided by the present invention is described in detail above. The principles and embodiments of the present invention have been described herein using specific examples, which are presented only to assist in understanding the method and its core concepts of the present invention. It should be noted that, for those skilled in the art, it is possible to make various improvements and modifications to the present invention without departing from the principle of the present invention, and those improvements and modifications also fall within the scope of the claims of the present invention.

Claims

1. A wristband apparatus, comprising: the wrist strap touch control system comprises a light-emitting fabric arranged in a wrist strap display area, a touch control fabric arranged in a wrist strap touch control area and a processor;

2. The wristband device according to claim 1, wherein the first light-emitting yarn is perpendicular to the weaving direction of the second light-emitting yarn, and an insulating yarn is arranged between two adjacent first light-emitting yarns or second light-emitting yarns; the weaving direction of the first conductive yarns is perpendicular to that of the second conductive yarns, and insulating yarns are arranged between every two adjacent first conductive yarns or second conductive yarns.

3. The wristband device of claim 2, wherein the wristband display area is the same as the wristband touch area, the first light emitting yarn and the first conductive yarn being woven in a warp direction, the second light emitting yarn and the second conductive yarn being woven in a weft direction; the first luminous yarns and the first conductive yarns are alternately arranged, and the insulating yarns are arranged between the adjacent first luminous yarns and the adjacent first conductive yarns; the second luminous yarns and the second conductive yarns are alternately arranged, and the insulating yarns are arranged between the adjacent second luminous yarns and the second conductive yarns.

4. The wristband device of claim 1, wherein the wristband touch area is disposed below the wristband display area in a wristband circle direction.

5. The wristband apparatus of claim 1, comprising: a stretch zone and a non-stretch zone; wherein the inelastic zone comprises the wristband display area and the wristband touch area; the elastic stretching area is provided with elastic fabrics for adjusting the wearing tight fit force of the wrist strap equipment.

6. The wristband apparatus of claim 1, wherein the first conductive yarn and the second conductive yarn each comprise: the resistance induction device comprises a conductive core wire and a resistance induction part which covers the surface of the conductive core wire in a preset structure.

7. The wristband apparatus of claim 6, further comprising: a voltage dividing resistor;

8. The wristband device of claim 1, wherein the first and second light emitting yarns each comprise a conductive core, an inorganic light emitting component, and a bonding component between the conductive core and inorganic light emitting component; wherein the inorganic light emitting component covers the surfaces of the conductive core wire and the bonding component in a predetermined covering structure.

9. The wristband apparatus of claim 8, further comprising: a first controllable switch and a second controllable switch;

10. The wristband apparatus according to any one of claims 1 to 9, further comprising: the heart rate acquisition fabric is arranged in the heart rate acquisition area;