CN214376556U - Sports label and clothing - Google Patents

Abstract

The utility model discloses a motion label and clothing, the motion label includes flexible shell, flexible center, flexible circuit module and battery are wrapped up in flexible center, flexible center is wrapped up in flexible shell, battery and flexible circuit module electric connection are used for providing the electric energy for the flexible circuit module, the flexible circuit module includes the treater, motion detection sensor and wireless communication module all with treater electric connection, motion detection sensor is used for monitoring motion signal, the treater is used for handling motion signal and controls wireless communication module and sends the handling result of motion signal for mobile terminal. The movement monitoring equipment is made to be flexible, so that the movement monitoring equipment can be sewn at any position of clothes according to the design of the clothes, and the statistics of the amount of movement of a user, the dressing state of the user and the identification of the movement state can be realized as long as the user wears the clothes.

Description

Sports label and clothing

Technical Field

The utility model relates to an electronic tags technical field especially relates to a motion label and clothing.

Background

With the acceleration of life rhythm, the phenomenon that the weight of people exceeds standard is more and more common. In pursuit of healthy physique, more and more people begin to pay attention to the exercise and fitness after work, monitor the amount of exercise through wearing special wearable equipment such as some intelligent bracelet.

The functions of the existing wearable equipment are approximately the same, the exercise heart rate, the exercise step number and the exercise time of the human body are monitored, and the consumed energy is converted. However, when people need to monitor the amount of exercise, the wearable devices must be worn by recording, often, users forget to use the wearable devices at home after using the wearable devices for a period of time, and the wearable devices are easy to forget or lose, and are collided and scratched on the surfaces of the wearable devices at times. Meanwhile, the large amount of sweating can also cause the discomfort of wearing the equipment to be aggravated.

SUMMERY OF THE UTILITY MODEL

In order to overcome the shortcoming and the deficiency that exist among the prior art, the utility model aims to provide a motion label and clothing to solve among the prior art motion monitoring facilities and wear trouble problem.

The purpose of the utility model is realized through the following technical scheme:

the utility model provides a motion label, including flexible shell, flexible center, flexible circuit module and battery, the flexible circuit module with the battery wrapped up in the flexible center, the flexible center wrapped up in the flexible shell, the battery with flexible circuit module electric connection is used for the flexible circuit module provides the electric energy, the flexible circuit module includes treater, motion detection sensor and wireless communication module, the motion detection sensor with wireless communication module all with treater electric connection, the motion detection sensor is used for monitoring motion signal, the treater is used for handling motion signal and control wireless communication module will motion signal's processing result is sent for mobile terminal.

Furthermore, a fixing part is arranged on the flexible shell and is positioned on the periphery of the flexible shell.

Further, the flexible shell is made of cloth or leather.

Further, the flexible middle frame is made of foaming materials.

Further, the surface of the flexible enclosure is coated with a water-proof melt film.

Further, the battery is a flexible battery.

Further, the motion detection sensor employs an acceleration sensor.

Further, the flexible circuit module further comprises a positioning module, the positioning module is electrically connected with the processor, and the positioning module is used for positioning the position of the motion tag.

Further, the flexible circuit module further comprises a power management module, the power management module is electrically connected with the battery and the processor respectively, and the power management module is used for controlling the battery to supply electric energy to the motion tag.

The utility model also provides a garment, including as above the motion label.

The utility model has the advantages that: the motion label includes flexible shell, flexible center, flexible circuit module and battery are wrapped up in flexible center, flexible center is wrapped up in flexible shell, battery and flexible circuit module electric connection are used for providing the electric energy for flexible circuit module, flexible circuit module includes the treater, motion detection sensor and wireless communication module all with treater electric connection, motion detection sensor is used for monitoring motion signal, the treater is used for handling motion signal and controls wireless communication module and sends the processing result of motion signal for mobile terminal. The movement monitoring equipment is made to be flexible, so that the movement monitoring equipment can be sewn at any position of clothes according to the design of the clothes, and the statistics of the amount of movement of a user, the dressing state of the user and the identification of the movement state can be realized as long as the user wears the clothes.

Drawings

Fig. 1 is a schematic structural diagram of a sports tag according to the present invention;

fig. 2 is a schematic diagram of a circuit structure of the motion tag of the present invention;

FIG. 3 is a graph of acceleration during intense exercise in accordance with the present invention;

FIG. 4 is a graph of acceleration when the garment of the present invention is worn in a forward or reverse direction;

fig. 5 is a control flow block diagram of the motion tag of the present invention.

Detailed Description

To further illustrate the technical means and effects of the present invention adopted to achieve the objectives of the present invention, the following detailed description will be made in conjunction with the accompanying drawings and preferred embodiments for the specific embodiments, structures, features and effects of the sports tag and the clothing according to the present invention as follows:

fig. 1 is the structure schematic diagram of the utility model discloses well motion label, fig. 2 is the utility model discloses well motion label's circuit structure schematic diagram, fig. 3 is the utility model discloses acceleration chart during well violent motion, fig. 4 is the utility model discloses acceleration chart when well clothing is just turning on, fig. 5 is the utility model discloses well motion label's control flow block diagram.

As shown in fig. 1 to 5, the utility model provides a motion label in fact, including flexible housing 10, flexible center 20, flexible circuit module 30 and battery 40 are wrapped in flexible center 20, flexible center 20 is wrapped in flexible housing 10, battery 40 and flexible circuit module 30 electric connection are used for providing the electric energy for flexible circuit module 30, flexible circuit module 30 includes treater 31, motion detection sensor 32 and wireless communication module 33 all with treater 31 electric connection, motion detection sensor 32 is used for monitoring motion signal, treater 31 is used for handling motion signal and controls wireless communication module 33 to send motion signal's processing result for mobile terminal.

The utility model discloses a make the motion monitoring equipment have the flexibility to can make at the arbitrary place of clothing according to the design of clothing, as long as the user wears the clothes, just can realize the statistics of user's amount of exercise, user wearing state, motion state's discernment. The motion label replaces the traditional clothing label to be combined with clothing, a new module is not introduced, the wearing comfort level is not influenced, and when the motion label is integrated with the traditional clothing, the motion label can be produced through mature machine sewing, gluing, hot pressing and other processes, is suitable for mass flow line production, and can be washed along with the clothing.

The flexible Circuit module 30 has a substrate made of polyimide or polyester film, and is a highly reliable and excellent flexible Printed Circuit board (flexible Printed Circuit board, fpcb for short) with high wiring density, light weight, and thin thickness. The processor 31, the motion detection sensor 32 and the wireless communication module 33 are all integrated on a flexible circuit board to form the flexible circuit module 30, and preferably, the processor 31, the motion detection sensor 32 and the wireless communication module 33 are distributed in an island shape with gaps therebetween to facilitate bending. The wireless communication module 33 may be at least one of a bluetooth module, a mobile network module, and a WIFI module, and the wireless communication module 33 may send a motion signal to a wireless receiving end (e.g., a mobile phone, a tablet computer, or a desktop computer) through bluetooth, a mobile network, or WIFI. The processor 31 is an MCU (micro control Unit). Of course, the processor 31, the motion detection sensor 32, and the wireless communication module 33 may be replaced with an integrated chip in which these functions are integrated at the same time, in order to achieve a minimum design and a minimum power consumption control.

Further, the flexible casing 10 is provided with a fixing portion 11, and the fixing portion 11 is located at a periphery of the flexible casing 10. The fixing part 11 is arranged to facilitate sewing of the sports tag on the garment without damaging the circuits and electronic components inside the sports tag.

Further, the flexible casing 10 is made of cloth or leather. The stitching of the flexible cover 10 may be by conventional machine stitching, gluing, heat pressing, etc. For application scenes (washable clothes) with waterproof requirements, a layer of waterproof material (waterproof fusion membrane) can be coated on one surface of the flexible shell 10, and a waterproof inner cavity is constructed in an adhesive mode. Preferably, a film (e.g., TPU film, Thermoplastic polyurethane elastomer rubber film) that can be fused by ultrasonic/hot pressing is disposed on one side of the flexible enclosure 10, and the film has a certain waterproof property, and the fusion of the upper and lower enclosures is achieved by ultrasonic, adhesive, and hot pressing, so as to construct a waterproof closed cavity. The fixing portion 11 can be adhered to the flexible casing 10, when the motion tag is sewn on a garment, a sewing needle can pierce the fixing portion 11, a small amount of water wets the fixing portion 11 along a needle hole, and therefore the fixing portion 11 is adhered to the flexible casing 10, and water can be prevented from entering the flexible casing 10. In other embodiments, the fixing portion 11 may be made of a different material from the flexible housing 10, and the fixing portion 11 may be made of a flexible plastic. Of course, the flexible middle frame 20 also has a certain waterproof property, and the waterproof performance can be further increased by arranging the waterproof fusion film.

Further, the flexible middle frame 20, which is typically a foamed material such as EVA (ethylene vinyl acetate), is mainly configured with a certain elasticity for fixing the flexible circuit module 30 and the battery 40.

Further, the battery 40 employs a flexible battery. The flexible battery is realized by the following steps: the paper folding structure is applied to a lithium battery, polyvinylidene fluoride (PVDF) modified carbon nanotube dust-free paper is used as a current collector, lithium cobaltate and lithium iron phosphate (LPF) are used as anode and cathode materials, the structure ensures smooth passing of current in the paper folding process, and the battery has high flexibility. Alternatively, a graphene battery may be used, since graphene has a layered structure and a large aspect ratio, and it can be assembled into a layered graphene membrane electrode having mechanical flexibility, and as for a flexible battery, reference is made to the prior art. Of course, the battery can also be divided into a plurality of tiny battery blocks, the plurality of battery blocks are distributed at intervals (in an island-shaped distribution), and then the plurality of battery blocks are electrically connected, so that the battery has certain flexibility.

Further, the motion detection sensor 32 is an acceleration sensor, preferably a flexible acceleration sensor, and the motion signal is an acceleration signal. The motion detection sensor 32 is designed as a flexible circuit by using flexible electronic technology, and the implementation process is as follows: the microelectronic structural elements in the motion detection sensor 32 are connected by flexible wires to form an island-bridge structure, while the non-electronic components (e.g., the substrate) in the motion detection sensor 32 are made of a flexible material (e.g., Polyimide (PI)), so that the integrated electronic device has high flexibility.

In this embodiment, the flexible circuit module 30 further includes a positioning module 34, the positioning module 34 is electrically connected to the processor 31, and the positioning module 34 is used for positioning the position of the moving tag. The positioning module 34 can be a GPS or beidou positioning module, and also can be a mobile network module, and the realization of the positioning function includes two kinds: the other is that a positioning base station calculates the coordinate position of a moving label through a positioning algorithm by capturing broadcast packet data and a signal intensity value sent by a mobile network module, and the other is that a GPS or Beidou positioning module is integrated in the moving label. When the positioning module 34 and the wireless communication module 33 both use mobile network modules, the positioning module 34 and the wireless communication module 33 can be combined into one module, that is, only one mobile network module needs to be provided.

Further, the flexible circuit module 30 further includes a power management module 35, the power management module 35 is electrically connected to the battery 40 and the processor 31, and the power management module 35 is configured to control the battery 40 to provide power for the motion tag. The power management module 35 may be a power switch, or may be a wireless charging module (electromagnetic coil) to charge the battery 40 of the motion tag.

As shown in fig. 5, the workflow of the present motion tag is:

step S1: acceleration data (motion signal) of the moving tag is acquired by the motion detection sensor 32.

Step S2: the acceleration data is pre-processed by the processor 31. The specific treatment process comprises the following steps: since the human beings are in different motion states, the acceleration values along the three axes X, Y, Z are obviously different by the human beings. As shown in fig. 3, is captured data of a forward jump or a jump. When the robot is in a forward stroke, a larger obvious peak value exists in the direction of an obvious Y axis, and when the robot is in a high jump, an obvious peak value exists in the direction of a Z axis. The motion states of different degrees can be classified according to the occurrence frequency and the keeping time length of amplitude values in the X, Y, Z three directions. For different application scenarios, different motion states need to be classified. For simple motion states, the motion amplitude (acc) can be compared with a preset threshold value, so that the corresponding motion state can be calculated. The amplitude can be selected directly from the output (x, y, z) of the motion detection sensor 32, the classification results in the three axial directions are integrated, and the motion amplitude is obtained according to the principle that the motion intensity is high in priority, namely according to the formula (1).

acc＝|max(x,y,z)| (1)

Of course, the selection of the amplitude can also classify the motion state according to the intensity of the resultant acceleration of the acceleration in three axial directions, and the calculation formula of the resultant acceleration is shown as formula (2).

Of course, more generally, the classification of the motion state may be performed based on an algorithm such as machine learning/deep learning. Firstly, test data is collected, data acquisition (x, y, z) is carried out according to scenes (static lying, turning over, standing, running, jumping, falling and the like) to be classified, the acquired data and corresponding states are sent to a machine learning/deep learning model, and a group of model parameters are trained. And secondly, storing parameters corresponding to the model into a target product, comparing the real-time acceleration data (x, y, z) with the model parameters, calculating a classification result and returning to obtain a corresponding motion state.

Step S3: and comparing the motion amplitude value tested in real time with a first threshold value of the violent motion, and judging the violent motion when the motion amplitude value is greater than the first threshold value, wherein the first threshold value can be set by self or can be set according to model parameters.

Step S4: and when the motion amplitude of the real-time test is smaller than or equal to the first threshold of the violent motion, comparing the motion amplitude of the real-time test with a second threshold of the daily walking, and when the motion amplitude is larger than the second threshold, judging the daily walking, wherein the second threshold can be set by self or can be set according to the model parameters.

Further, when the motion amplitude value tested in real time is smaller than or equal to the second threshold value of the violent motion, the quiet state is judged, the comparison is finally ended, and the next comparison is started.

Furthermore, whether the clothes are worn reversely can be judged according to the change of the positive and negative signs of the acceleration values. Due to different wearing modes of the clothes, the partial acceleration perpendicular to the direction of the motion tag is overturned, and whether the clothes are worn reversely can be judged according to the change of the positive and negative signs of the acceleration values. As shown in FIG. 4, when the garment is worn correctly, the Z-axis is negative and the garment is worn backwards.

Further, whether the garment is worn correctly can be determined according to the axial direction. When the garment is worn, the garment is generally tightly attached to the outline of a person, the outline of the person has an arc-shaped surface, and the garment is overturned in an inconsistent mode due to axial change. Thus, more generally, the change in the angle of the resultant acceleration to a given axial direction can be calculated. Since the sewing of the motion label can be appointed in the production instruction book, the axial direction of the clothes when being worn can be roughly determined, and whether the clothes is worn correctly or not can be determined according to the axial direction. Here, the X axis is a horizontal direction (relative to the ground plane), the Y axis is a vertical direction (relative to the ground plane), and the Z axis is perpendicular to the surface of the garment for further description, and at this time, whether the garment is normally worn can be determined by calculating an included angle between the garment and the Y axis after the garment is worn. Namely, the change of the included angle between the calculation vector (x, y, z) and (0,1,0), when the included angle belongs to [0 degrees, 180 degrees ], the clothes are worn normally, and when the included angle belongs to [180 degrees, 360 degrees ], the clothes are worn reversely, and the specific range is related to the position and the direction of the motion label sewn on the clothes. The calculation formula of the included angle is shown in formula (3). Thereby recording the identification and statistics of the motion state, the dressing state, the sleep quality, the wearing duration and the like of the user.

Further, the motion tag has a unique MAC address and an ID value, and has a storage unit capable of recording the identity information of the user. Identity information can be broadcasted in real time through Bluetooth broadcasting, data can be encrypted through an Encryption algorithm before being broadcasted, the Encryption algorithm comprises AES (Advanced Encryption Standard), RSA (public key Encryption algorithm) and the like, other equipment which knows a secret key and a communication protocol can acquire the identity information of a user, and therefore business card exchange and entertainment interaction can be further expanded. The motion tag can record personal information of a user and realize functions of business card interaction and the like according to the setting of the user.

The utility model also provides a garment, including as above the motion label.

In this document, the terms of upper, lower, left, right, front, rear and the like are used to define the positions of the structures in the drawings and the positions of the structures relative to each other, and are only used for the sake of clarity and convenience in technical solution. It is to be understood that the use of the directional terms should not be taken to limit the scope of the claims. It is also to be understood that the terms "first" and "second," etc., are used herein for descriptive purposes only and are not to be construed as limiting in number or order.

The above description is only a preferred embodiment of the present invention, and the present invention is not limited to the above description in any form, and although the present invention has been disclosed with the preferred embodiment, it is not limited to the present invention, and any skilled person in the art can make some changes or modifications within the technical scope of the present invention without departing from the technical scope of the present invention, and the technical contents of the above disclosure can be utilized to make equivalent embodiments, but the technical contents of the present invention are not broken away from, and any simple modification, equivalent change and modification made to the above embodiments according to the technical spirit of the present invention all still belong to the protection scope of the technical solution of the present invention.

Claims (10)

1. A motion tag, comprising a flexible housing (10), a flexible middle frame (20), a flexible circuit module (30) and a battery (40), wherein the flexible circuit module (30) and the battery (40) are wrapped in the flexible middle frame (20), the flexible middle frame (20) is wrapped in the flexible housing (10), the battery (40) is electrically connected with the flexible circuit module (30) and used for providing electric energy for the flexible circuit module (30), the flexible circuit module (30) comprises a processor (31), a motion detection sensor (32) and a wireless communication module (33), wherein the motion detection sensor (32) and the wireless communication module (33) are electrically connected with the processor (31), the motion detection sensor (32) is used for monitoring motion signals, and the processor (31) is used for processing the motion signals and controlling the wireless communication module (33) to carry the motion signals And sending the processing result of the dynamic signal to the mobile terminal.

2. The sports tag according to claim 1, characterized in that said flexible casing (10) is provided with a fixing portion (11), said fixing portion (11) being located at the periphery of said flexible casing (10).

3. The sports tag according to claim 1, characterized in that said flexible casing (10) is made of cloth or leather.

4. The sports tag according to claim 1, characterized in that said flexible middle frame (20) is made of a foamed material.

5. The sports tag according to claim 1, characterized in that the surface of the flexible casing (10) is coated with a waterproof melt film.

6. The sports tag according to claim 1, characterized in that the battery (40) is a flexible battery.

7. The motion tag according to claim 1, wherein the motion detection sensor (32) comprises an acceleration sensor.

8. The kinematic tag according to claim 1, characterized in that the flexible circuit module (30) further comprises a positioning module (34), the positioning module (34) being electrically connected to the processor (31), the positioning module (34) being configured to position the kinematic tag.

9. The sports tag according to claim 1, wherein the flexible circuit module (30) further comprises a power management module (35), the power management module (35) is electrically connected to the battery (40) and the processor (31), respectively, and the power management module (35) is configured to control the battery (40) to provide power to the sports tag.

10. A garment comprising a sports tag according to any one of claims 1 to 9.

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