CN110916867A - Neck wearable equipment, neck wearable system and interactive platform thereof - Google Patents

Abstract

The present invention provides a neck wearable system adapted to be worn around the neck of a user, comprising: an interactive control module; an audio-visual module, wherein the interactive control module is controllably connected to the audio-visual module; and the acquisition module acquires use data related to the neck of the user, and the interaction control module is controlled to send a control instruction to the audio-visual module according to the use data so that the use data can be fed back through the audio-visual module. In addition, the invention further provides a neck wearable platform and neck wearable equipment, which are supported by shoulders or a trunk, reduce the load of electronic equipment on the neck and are suitable for acquiring the neck data of a user and performing personalized analysis.

Description

Neck wearable equipment, neck wearable system and interactive platform thereof

Technical Field

The invention relates to wearable equipment and interaction thereof, in particular to neck wearable equipment, a neck wearable system and an interaction platform thereof.

Background

The head has most senses, vision, hearing, sound output, etc. located on the neck of the human body. External hardware devices such as earphones, microphones, glasses, and the like need to be worn on the head. Moreover, as the number of voice-controlled smart devices increases, signal acquisition for voice output and signal accuracy for speech listening are important. Most of the existing external hardware devices are directly worn on the head, so that the weight is added to the head, and the neck also needs to bear heavier burden.

Other sound control devices are often placed near the power source near the far body, and these devices are relatively far from the head of the body. Therefore, unless speaking loudly or closely, it is difficult for the sound output of the human body to provide a voice signal to the control device. In contrast, the feedback sound emitted by the device must also be loud for the human body to listen to at a distance. The physical distance between the intelligent device and the human body is an inevitable restriction factor for the development of the signal acquisition technology.

Our body head is supported by the neck during 24 hours a day, while the neck relies mainly on the supporting force of the cervical spine. The cervical spine not only supports the head, but also conducts sensation and controls the nerve center of the body. Neck health is critical to daily life. To relax the neck or neck muscles, it is necessary to remain lying or lean against to partially release the weight of the head.

There is currently substantially no means for releasing the weight of the head to allow the neck to relax. As electronic devices, smart devices, and the like have a large percentage of lives, more and more people need external hardware devices to live or work. More, the sitting posture does not help much to prevent the neck from loosening. The neck must bear the full head weight when sitting for a long period of time. If the cervical vertebrae can be in a natural bent posture, the muscles of the neck are kept in a certain balance, and the nerves are not pressed. However, when the user keeps the posture for a long time in a static state, muscles of the neck are not moved and exercised, and the user generally cannot keep the natural bending. This potential stress can potentially cause nerve paralysis, affecting a healthy body state, if the cervical spine is in an unhealthy posture or if the muscles are unbalanced due to personal habits.

If discomfort occurs in the neck, there has been a serious problem that the cervical vertebrae or neck muscles are not well-conditioned. Prevention of neck diseases should be paid more attention. However, the existing neck fixing devices are medical neck rests, are used for serious and high diseases too much, and have terrible appearance. Medical neck collars cannot be used easily in daily life, and use without advice may cause more problems. A correct sitting posture or necessary correction is necessary in the daily life. Real-time detection of the physical state may also accumulate more datamation information.

Disclosure of Invention

One of the main advantages of the present invention is to provide a neck wearable device, a neck wearable system and an interactive platform thereof, which are supported by shoulders or a trunk, thereby reducing the load on the neck electronic device.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interaction platform thereof, which provide at least one external interface suitable for connecting an electronic device such that the electronic device is used near the head of a user.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interactive platform thereof, in which an electronic device is detachably connected to the neck wearable device for optional use according to the user's needs.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interactive platform thereof, wherein the neck wearable device comprises a support frame adapted to support and stabilize around the head.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interactive platform thereof, which can directly and conveniently transmit data information to a sense organ by arranging a desired electronic device on a user's head around the neck.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interactive platform thereof, wherein the neck wearable device collects neck and head data in a wearing state, thereby forming a personalized usage data, assisting in monitoring a healthy bow posture of the neck, and avoiding unhealthy postures daily.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interaction platform thereof, which can save the data of the electronic device used by the user by using the usage data, and provide a more convenient preparation and use base for using the electronic device.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interaction platform thereof, wherein the usage status is identified and analyzed according to the usage data, so as to prompt the user to correct the current usage status.

It is another advantage of the present invention to provide a neck wearable device, a neck wearable system and an interaction platform thereof, wherein a plurality of aggregated analyses of the usage data provide personalized cues to a particular user.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interaction platform thereof, wherein the neck wearable system provides a basic data for matching the usage data, and monitors the usage status of the neck wearable device in real time.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interaction platform thereof, wherein a user can select to share the usage data according to needs, and provide different corrective reminders according to different basic data.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interaction platform thereof, wherein the neck wearable device is adapted to different users or different body states of the users, and maintains a healthy neck posture for a comfortable resting user.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interaction platform thereof, wherein the neck wearable device can be adjusted to accommodate different neck postures according to different users.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interactive platform thereof, wherein the neck wearable device is supported in the lower jaw to assist in maintaining the natural bending posture of the neck, so as to prevent cervical vertebra from being inclined and prevent neck diseases.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interactive platform thereof, wherein the neck of the user can be rotated under the limitation of the neck wearable device to avoid nerve paralysis during long wearing periods and to adapt to daily head rotations.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interactive platform thereof, wherein the neck of the user can collect the usage data during the process of the neck wearable device, collect the usage conditions, the angle, the height and the rotation degree of the head, provide a personal database, record the data in the use of the user, and summarize the data into habitual data or count bad habits.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interaction platform thereof, wherein the neck wearable device is foldable to reduce the size for storage or carrying.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interaction platform thereof, wherein the neck wearable device adapts to sitting postures without affecting normal daily life.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interactive platform thereof, wherein the neck wearable device comprises a support frame adapted to support the head around the support frame for stability, and an adjusting unit for adjusting the shape of the support frame for different users.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interactive platform thereof, wherein the support frame stably locks the adjustment in a predetermined position, and continues to remain fixed to the user's head unless the adjustment unit is unlocked.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interaction platform thereof, wherein the wearable neck device further comprises a hardware unit disposed on the support frame for receiving and collecting the usage data.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interaction platform thereof, wherein the hardware unit is preferably connected with other smart devices to reduce the distance between the user and the smart devices.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interactive platform thereof, wherein the hardware unit is detachably connected to the support frame, and the support frame provides an interface for connecting the hardware units with different functions, so that a user can use the different functions individually by external connection.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interaction platform thereof, in which a hardware unit directly receives a signal or provided information to enhance a connection between a user and a smart device.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interaction platform thereof, wherein the wearable neck device can directly acquire sound data from a position close to the user's mouth.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interactive platform thereof, wherein the external interface is used by connecting different electronic devices, and enjoys different functions by replacing the required electronic devices.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interaction platform thereof, wherein the neck wearable device not only provides health correction and prevention, but also facilitates electrical intelligent life.

Another advantage of the present invention is to provide a neck wearable device, a neck wearable system and an interactive platform thereof, wherein the neck wearable device reduces neck load, thereby protecting the neck and enabling a user in daily life to be closely connected with a smart device.

Additional advantages and features of the invention will be set forth in the detailed description which follows and in part will be apparent from the description, or may be learned by practice of the invention as set forth hereinafter.

In accordance with one aspect of the present invention, the foregoing and other objects and advantages are achieved in a neck wearable system adapted to be worn around a neck of a user, comprising:

an interactive control module;

an audio-visual module, wherein the interactive control module is controllably connected to the audio-visual module;

and the acquisition module acquires use data related to the neck of the user, and the interaction control module is controlled to send a control instruction to the audio-visual module according to the use data so that the use data can be fed back through the audio-visual module.

According to an embodiment of the present invention, the neck wearable system further comprises a matching module, wherein the audiovisual module, the matching module and the acquisition module are cooperatively connected under the control of the interactive control module, wherein the matching module obtains the evaluation of the neck state according to the usage data.

According to one embodiment of the invention, the matching module evaluates according to preset standard data.

According to one embodiment of the invention, the matching module evaluates according to a history of the usage data.

According to one embodiment of the invention, the matching module obtains user neck bow data from the usage data.

According to another aspect of the present invention, there is further provided a neck wearable platform adapted to provide neck status to at least one user, comprising:

at least one neck wearable system and a processing center, wherein the processing center manages and stores usage data relating to a user's neck, wherein the processing center is selected to provide a base data to the neck wearable system, wherein the processing center provides for uploading and downloading of personal login data of at least one user.

According to another aspect of the present invention, there is further provided a neck wearable device, comprising:

a support frame and at least one adjusting unit, wherein the adjusting unit is arranged on the support frame, wherein the support frame can be connected to the adjusting unit in a folding way, and the support frame can be supported on the trunk of a user in a shape changing way through the adjusting unit.

According to one embodiment of the invention, the support frame comprises at least two support legs and a holding arm, wherein the holding arm is foldably mounted to the support legs, wherein a holding angle is formed between the support legs and the holding arm, wherein an adjustment angle is provided between the two support legs, wherein the holding angle and the adjustment angle are adjusted by the adjustment unit.

According to one embodiment of the invention, the neck wearable device further comprises a hardware unit, wherein the hardware unit is mounted on the support frame to collect signals emitted by the user.

According to one embodiment of the invention, the hardware unit collects usage data relating to the neck of the user.

Further objects and advantages of the invention will be fully apparent from the ensuing description and drawings.

These and other objects, features and advantages of the present invention will become more fully apparent from the following detailed description, the accompanying drawings and the claims.

Drawings

FIG. 1 is a block diagram of a neck wearable system and its interaction platform according to a preferred embodiment of the present invention.

Fig. 2 is a schematic diagram of the neck wearable system and its interactive platform data collection according to the above preferred embodiment of the present invention.

Fig. 3 is a schematic diagram of the neck wearable system and its interactive platform data collection according to the above preferred embodiment of the present invention.

Fig. 4 is a schematic diagram of the neck wearable system and its interactive platform data application according to the above preferred embodiment of the present invention.

Fig. 5 is a schematic diagram of the neck wearable system and its interactive platform data application according to the above preferred embodiment of the present invention.

Fig. 6 is a schematic view of the neck wearable system and the data processing flow of the interactive platform thereof according to the above preferred embodiment of the present invention.

Fig. 7 is a schematic diagram of the neck wearable system and the interactive platform terminal control thereof according to the above preferred embodiment of the present invention.

Fig. 8 is a schematic view of the neck wearable system and the data processing flow of the interactive platform thereof according to the above preferred embodiment of the present invention.

Fig. 9A is an overall schematic view of the neck wearable device according to the above preferred embodiment of the present invention.

Fig. 9B is an overall schematic view of the neck wearable device according to the above preferred embodiment of the present invention.

Fig. 10 is a schematic view of the height adjustment of the neck wearable device according to the above preferred embodiment of the present invention.

Fig. 11 is a schematic view of tightness adjustment of the neck wearable device according to the above preferred embodiment of the present invention.

Fig. 12 is an unlocking schematic diagram of the neck wearable device according to the above preferred embodiment of the present invention.

Fig. 13A is a schematic diagram of a possible hardware configuration of the neck wearable device according to the above preferred embodiment of the present invention.

Fig. 13B is a schematic diagram of a possible hardware configuration of the neck wearable device according to the above preferred embodiment of the present invention.

Fig. 14 is a schematic diagram of a possible hardware configuration of the neck wearable device according to the above preferred embodiment of the present invention.

Fig. 15 is an interaction diagram of the neck wearable device and the smart device according to the above preferred embodiment of the present invention.

Fig. 16 is a schematic diagram of a possible hardware configuration of the neck wearable device according to the above preferred embodiment of the present invention.

Fig. 17 is a schematic diagram of a possible battery and electrical wiring configuration of the neck wearable device according to the above preferred embodiment of the present invention.

Detailed Description

The following description is presented to disclose the invention so as to enable any person skilled in the art to practice the invention. The preferred embodiments in the following description are given by way of example only, and other obvious variations will occur to those skilled in the art. The basic principles of the invention, as defined in the following description, may be applied to other embodiments, variations, modifications, equivalents, and other technical solutions without departing from the spirit and scope of the invention.

It will be understood by those skilled in the art that in the present disclosure, the terms "longitudinal," "lateral," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in an orientation or positional relationship indicated in the drawings for ease of description and simplicity of description, and do not indicate or imply that the referenced devices or components must be in a particular orientation, constructed and operated in a particular orientation, and thus the above terms are not to be construed as limiting the present invention.

It is understood that the terms "a" and "an" should be interpreted as meaning that a number of one element or element is one in one embodiment, while a number of other elements is one in another embodiment, and the terms "a" and "an" should not be interpreted as limiting the number.

The present invention provides a neck wearable system, as shown in fig. 1-17, adapted to be worn around the neck of a user to collect usage data 800 of the user during use. The neck wearable system further utilizes the collected usage data 800 for analysis to grasp the user's usage status.

As shown in fig. 1 to 8, the neck wearable system includes an interactive control module 100, an audio-visual module 200, a matching module 300 and an acquisition module 400, wherein the interactive control module 100 can be controllably connected to the audio-visual module 200, the matching module 300 and the acquisition module 400. The interactive module 100 is used for conducting controlled guidance on the operations of the audiovisual module 200, the matching module 300 and the acquisition module 400, so that the audiovisual module 200, the matching module 300 and the acquisition module 400 meet the use requirements of users. The audiovisual module 200, the matching module 300 and the acquisition module 400 are cooperatively connected with each other under the control of the interactive control module 100. The acquisition module 400 acquires the usage data 800 of the user such that the neck data or audio-visual data of the user is acquired and awaits analysis processing. That is, through the interactive control module 100, the user can control the operations of the audiovisual module 200, the matching module 300, and the acquisition module 400, so as to avoid an unsafe feeling in the using process of the neck-worn device.

More, the acquisition module 400 further performs data acquisition on the lifting angle, the height and the rotation degree of the neck of the user. That is, the angle of relative lifting of the chin of the user's neck, head height, angle of head rotation, and the like can all be collected and recorded. By means of the data acquisition, the spinal state of the neck can be obtained accordingly. The spine state of the neck of the user can be obtained through the collection of the collection module 400 in use without special detection of the cervical vertebrae.

The user may further be optionally informed of the usage status or whether there is a problem with the usage status with respect to the collected usage data 800. The matching module 300 processes and analyzes the usage data 800 obtained by the acquisition module 400, and the result of the processing is output by the audio-visual module 200. That is, the matching module 300 in turn obtains assessments of different neck states for the usage data 800. The user may select a process placement of the matching module 300. Preferably, the matching module 300 evaluates the usage data 800 according to the basic data 801 and evaluates the usage data according to preset standard data. Further preferably, the matching module 300 evaluates against a personal login data history.

It is worth mentioning that the invention further provides a neck wearable interactive platform, which manages at least one neck wearable system and stores personal login data of each neck wearable system accordingly. The neck wearable interactive platform further comprises a processing center. That is, the processing center of the neck wearable interaction platform manages and saves the usage data 800 of the user. Preferably, the neck wearable interaction platform provides the basic data 801 so that each neck wearable system can obtain corresponding data for analysis. In addition, the neck wearable platform provides for uploading and downloading of different personal login data, and the usage data 800 is provided to the corresponding logged-in neck wearable system according to different login conditions. That is, the neck wearable platform provides retrieval of the usage data 800, or the neck wearable platform provides the usage data 800 to another database or processing terminal, particularly for users wearing different neck devices. In addition, the usage data 800 of the user's history or the usage data 800 of a nearby user may influence the basic data 801, and when the basic data 801 has more wisdom and more variety of data conclusions, the user can get more advantageous usage environment and notification effect from the neck wearable platform according to the basic data 801.

Further, the present invention additionally provides a neck wearable device that assists the user's body in supporting the head and relieving neck stress. The neck wearable device is worn around a neck of a user. Preferably, the neck wearable device carries the acquisition module 400 of the neck wearable device, the acquisition module 400 collecting the usage data 800 during wearing and use. In a further possible embodiment, the neck wearable system is fully mounted on the neck wearable device.

An example is shown in fig. 4, during the use of the neck wearable device, the user selects a corrective reminder of sitting posture via the usage data 800. The acquisition module 400 acquires the neck of the user, and particularly monitors the bow of the cervical spine of the user. The matching module 300 matches and evaluates the sitting posture expressed by the usage data 800 based on the base data 801. According to the analysis result, the audio-visual module 200 reminds and gives an alarm in case of serious conditions.

Another possible use example is shown in fig. 5, where the user makes a database call according to the personal login data in the usage data 800 during the process of using the neck wearable device. The audiovisual module 200 acquires a corresponding data cylinder from the neck wearable platform according to the control of the unit of the interactive control module 100, and the audiovisual module 200 plays the data cylinder for use. For example, if there is playing data enjoyed by the user in the history of the usage data 800, the audiovisual module 200 obtains the corresponding resource and plays the resource by calling the usage data 800 in the basic data 801 accordingly. It is worth mentioning that the neck wearable device of the present embodiment transfers the physical weight of the audiovisual module 200 to the shoulder or the trunk of the body, so as to avoid the adverse effect on the neck of the user caused by long-time use. In particular, the physical weight of the interactive control module 100, the audiovisual module 200, the matching module 300 and the acquisition module 400 of the neck wearable system may be mostly transferred out of the neck of the user by the neck wearable device.

Specifically, as shown in fig. 1, the interactive control module 100 includes an input unit 110, a program module 120, and an external interface 130. The program module 120 is preset with a certain interactive program. Through the instruction input of the input unit 110 to the program module 120, the external interface 130 correspondingly performs control to perform instruction output to the audio-visual module 200, the matching module 300, or the acquisition module 400. The interactive control module 100 further includes a communication module 140, the communication module 140 being communicatively mated with the neck wearable platform. In particular, the data of the neck wearable platform may be accessed to the communication module 140 at the user's permission, so that the interactive control module 100 acquires the required data.

The audiovisual module 200 comprises an audio unit 220 and a storage unit 230. The audio unit 220 is connected to the external interface 130 of the interactive control module 100. The external interface 130 of the interactive control module 100 emits a sound signal to the audio unit 220. Preferably, the audio unit 220 is connected to the input unit 110 of the interactive control module 100, and the input unit 110 of the interactive control module 100 collects voice commands from the audio unit 220. The storage unit 230 buffers the communication between the audiovisual module 200 and the interactive control module 100. Preferably, the storage unit 230 is preset to play the data source, and the audio unit 220 can directly call for use.

More particularly, in another possible preferred embodiment, the audiovisual module 200 further comprises a display unit 210. The external interface 130 of the interactive control module 100 provides display data to the display unit 210. The data source in the storage unit 230 can be called by the display unit 210.

More specifically, the use of sitting posture correction as shown in figure 4. The acquisition module 400 acquires the neck of the user, and particularly monitors the bow of the cervical spine of the user. The matching module 300 matches and evaluates the sitting posture expressed by the usage data 800 based on the base data 801. If a certain correction prompt appears in the analysis result, the audio unit 220 of the audio-visual module 200 sends out a sound prompt according to the interactive control module 100, and the display unit 210 further provides a light flashing prompt. More generally, the display unit 210 is implemented as an AR display, which, based on the analysis results, prompts the user with the correct sitting position, an image indication of how the body needs to be moved.

More specifically, an application played by a user using the neck wearable device as shown in fig. 5. The personal login data is submitted through the input unit 110 of the interactive control module 100 to make a database call. The audiovisual module 200 obtains corresponding data from the neck wearable platform according to the control of the external interface 130 of the interactive control module 100, and plays the data for the display unit 210 and the audio unit 220 of the audiovisual module 200. In particular, the physical weight of the audiovisual module 200 is not directly applied to the user's head. That is, the audio-visual devices are applied to the shoulder or the trunk of the user through the neck wearable device, protecting the health of the neck by reducing the load of the neck. More particularly, to audio-visual equipment of higher complexity and quality that can be used for a longer period of time.

The preferred embodiment also provides for the monitoring of the neck condition simultaneously with the audiovisual module 200. That is, the capture module 400 can be enabled to collect head and neck values so that the user can play an entertainment event with the audiovisual module 200 while maintaining neck health. Of course, it will be understood by those skilled in the art that the audiovisual module 200 provides anti-addiction, etc. anti-fatigue functionality as appropriate, in conjunction with the data monitoring of the acquisition module 400, as desired.

Further, the acquisition module 400 includes an angle acquisition unit 410, the height acquisition unit 420, and the rotation acquisition unit 430. The acquisition module 400 acquires data for the neck of the user in use, and then obtains the state of the cervical vertebra of the user. The angle collecting unit 410, the height collecting unit 420 and the rotation degree collecting unit 430 are respectively connected to the interactive control module 100, and the matching module 300 collects data from one or more of the angle collecting unit 410, the height collecting unit 420 and the rotation degree collecting unit 430 as required. It is worth mentioning that the angle acquisition unit 410 acquires the angle of the head of the user relative to the neck, the height acquisition unit 420 acquires the distance of the head relative to the neck, and the rotation acquisition unit 430 acquires the angle of the head relative to the neck. The lifting angle, the height and the rotation degree of the neck of the user are subjected to data acquisition. That is, the angle of relative lifting of the chin of the user's neck, head height, angle of head rotation, and the like can all be collected and recorded. By means of the data acquisition, the spinal state of the neck can be obtained accordingly. That is, the angle collecting unit 410, the height collecting unit 420, and the rotation degree collecting unit 430 collect the state of the neck with respect to the head without directly exploring the shape of the cervical vertebrae. In the preferred embodiment, the state of the cervical vertebrae is obtained by processing and fitting the data acquired by the angle acquisition unit 410, the height acquisition unit 420, and the rotation acquisition unit 430. Also, the basic data 801 includes predetermined warning or reference data with respect to the angle acquisition unit 410, the height acquisition unit 420, and the rotation degree acquisition unit 430.

The basic data 801 may be set in advance, or may be obtained by summarizing the history of personal login data.

More specifically, the matching module 300 includes a basic data unit 310, a determining unit 320 and a scheme unit 330. The basic data unit 310 can obtain the basic data 801, the judging unit 320 obtains the data of the angle collecting unit 410, the height collecting unit 420 and the rotation degree collecting unit 430 and matches the data with the basic data unit 310, and according to the result, the scheme unit 330 searches for an output scheme in a preset control action, so as to implement scheme feedback through the audio-visual module 200. Specifically, in the personal login data state, the basic data unit 310 is communicably connected to the angle acquisition unit 410, the height acquisition unit 420, and the rotation degree acquisition unit 430 to obtain data and obtain the basic data 801 related to the usage history of the user. In the connected state to the neck wearable platform, the basic data unit 310 obtains the basic data 801 from the neck wearable platform. It should be noted that the determining unit 320 is a matching program independently matched with the program module 120 of the interactive control module 100, so that the analysis of the collected data ensures the precision and the data speed, and also ensures the smooth operation of the main program. The scheme unit 330 obtains the matching result from the judging unit 320, and further provides the working scheme of display or audio to the audiovisual module 200.

In particular, the interactive control module 100 is further arranged to preferentially output a health prompt to the audiovisual module 200. That is, the resulting solution to the analysis results from the matching module 300 can be performed proactively, ensuring that health alerts are not ignored.

Further, the usage data 800 acquired by the angle acquisition unit 410, the height acquisition unit 420, and the rotation acquisition unit 430 may be selectively uploaded to the neck wearable platform by a user. Specifically, as shown in fig. 6, personal data is logged in the neck wearable platform, so as to obtain the saved usage data 800, i.e. obtain a personal database by logging in a personal account. The user selects whether to upload the data of the acquisition module 400 in this use through the input unit 110 of the interactive control module 100. If the user agrees, the usage data 800 collected by the collection module 400 is shared to the neck wearable interaction platform through the communication unit 140 of the interaction control module 100. The neck wearable interaction platform manages and saves the usage data 800 for the user. In the personal login data state, the basic data unit 310 is communicably connected to the angle acquisition unit 410, the height acquisition unit 420, and the rotation degree acquisition unit 430 to obtain data and to obtain the basic data 801 related to the usage history of the user. That is, the neck wearable interaction platform provides the basic data 801 so that each neck wearable system can obtain corresponding data for analysis. Further, the user optionally obtains the required usage data 800 from the neck wearable platform. That is, by logging in personal data, the neck wearable platform provides for uploading and downloading of different personal login data, and according to different login situations, the usage data 800 is provided to the corresponding logged in neck wearable system. In particular, the usage data 800 may be obtained by an otherwise authorized user from the neck wearable platform. For example, a hospital or doctor needs a user's daily neck health status in a doctor, and the neck wearable platform provides for the user's daily download of neck data.

In addition, the neck wearable system of the present invention further provides an external control device 900, as shown in fig. 7. The usage data 800 is displayed on the external control device 900 through the interactive control module 100. The external control device 900 provides an interface for the interactive control module 100 and user control instructions. One possible embodiment is shown in fig. 7. By mounting the interactive control module 100 on the external control device 900, the user can know the usage data 800 in real time through the interactive control module 100, and can control and operate the audiovisual module 200, the matching module 300, and the acquisition module 400. In a preferred case, the user can view the information of the display unit 210 from the external control device 900 and listen to the information of the audio unit 220 from the neck wearable device. In addition, the data of the angle acquisition unit 410, the height acquisition unit 420 and the rotation degree acquisition unit 430 of the acquisition module 400 are also displayed, so that the user can obtain whether the neck state is normal from the feedback of the external control device 900 without the intervention of the matching module 300.

More specifically, the prompt analysis processing flow of the matching module 300 based on the angle collecting unit 410, the height collecting unit 420 and the rotation degree collecting unit 430 of the collecting module 400 is shown in fig. 8. The acquisition module 400 stores the usage data 800 generated during the usage of the user. The matching module 300 obtains corresponding data to be processed, such as the health data portion of the usage data 800 or user action operation data, etc., from the acquisition module 400. Then, it is confirmed whether the usage data 800 is shared. If sharing is confirmed, that is, the matching module 300 is connected to the neck wearable platform, so that the usage data 800 and the basic data 801 are both communicated. If the sharing is not confirmed, the matching module 300 applies the logged-in personal data to process. That is, the basic data unit 310 of the matching module 300 has different data acquisition modes. The judging unit 320 processes the usage data 800 in use according to the above-mentioned manner, and further feeds back the usage status of the user in real time and finally displays the usage status by the audiovisual module 200. It will be appreciated by those skilled in the art that the above-described flow is provided as an example to illustrate the preferred processing of the data obtained by the acquisition module 400 by the matching module 300. According to the analysis result, the interactive control module 100 performs a prompt instruction on the audiovisual module 200, and the audiovisual module 200 outputs prompt information.

Specifically, the application state in fig. 4 is exemplified. A user selects a corrective reminder of sitting posture through the usage data 800 to the input unit 110 of the interactive control module 100 during use of the neck wearable device. The acquisition module 400 acquires the neck of the user and mainly monitors the degree of bow of the cervical vertebrae of the user. And confirming whether the health data acquired by the acquisition module 400 is shared. If sharing is confirmed, that is, the matching module 300 is connected to the neck wearable platform, and then the current usage status is evaluated using the predetermined basic data 801 as a reference. If the sharing is not confirmed, the matching module 300 applies the logged-in personal data to process. The determination unit 320 of the matching module 300 matches and evaluates the sitting posture expressed by the usage data 800 according to the basic data 801. According to the analysis result, the audio-visual module 200 reminds and gives an alarm in case of serious conditions. If a certain correction prompt appears in the analysis result, the audio unit 220 of the audio-visual module 200 sends out a sound prompt according to the interactive control module 100, and the display unit 210 further provides a light flashing prompt. More generally, the display unit 210 is implemented as an AR display, which, based on the analysis results, prompts the user with the correct sitting position, an image indication of how the body needs to be moved. In particular, in one usage state, the angle acquisition unit 410 and the height acquisition unit 420 of the acquisition module 400 acquire neck data of a user. According to the analysis of the basic data unit 310, the user has a state of long-time head-lowering, which is harmful to the health of the cervical vertebrae. Or from more data analysis, the user is at risk of walking low. In other words, the matching module 300 can be provided with a need to alert the user to change an existing gesture. The audiovisual module 200 prompts according to the analysis results so that the user is aware of the potential risk. In addition, the data history of the usage data 800 is selectively uploaded to the neck wearable platform and downloaded as needed.

Further, a preferred embodiment of the neck wearable device is shown in fig. 9A to 17. The neck-worn device is used for supporting the head of a user to reduce neck compression for the user in daily life. The neck wearable device comprises a support frame 10 and at least one adjusting unit 20, wherein the adjusting unit 20 is arranged on the support frame 10 to adjust the shape of the support frame 10 so as to be worn by different users appropriately. In other words, the support stand 10 is wearable and different users are adapted to adjust the adjustment unit 20 to fit different users' heads. The support frame 10 is adapted to be supported on the shoulders or torso of a user when worn, reducing the weight burden on the neck of the user from the head of the user. The support stand 10 is firmly supported around the head of the user, and the adjustment unit 20 is adjusted or fixed to maintain the fastened form of the support stand 10 to sufficiently support the head of the user.

Additionally, the neck wearable device includes a support frame 10 and a hardware unit 30, as shown in fig. 13A to 17. The hardware unit 30 is mounted on the support stand 10 and connected with an intelligent system to transmit signals between a user and the intelligent system. The hardware unit 30 comprises a processor 31 and at least one electronic device connected to and controlled by the processor 31. That is, the hardware unit 30 may be used while wearing the support stand 10. On one hand, the locking neck shifts the weight that the head bore, on the other hand, directly uses the function of electron device, carries out intelligent life and amusement. In the preferred embodiment, the electronic device is detachably mounted on the support frame 10. In other possible manners, the electronic device may also be integrally formed or assembled with the supporting frame 10.

The electronic device may be implemented as an electronic device, that is, the electronic device may be a stand-alone device connected to the neck wearable device.

As shown in fig. 9A to 11, it is worth mentioning that the support frame 10 is supported in a balanced and natural position to limit the spine of the head and neck of the user to avoid movement of the head in an undesired direction. Therefore, the support frame 10 is restricted to the rotation or inclination of the neck, preventing the movement to the right or left side and the upward or downward direction, so as to maintain the neck at a natural position and angle, avoiding nerve paralysis of the cervical vertebrae due to bad habit. The movement of the surrounding neck rotation is not limited by the support frame 10, so that the user can freely turn and look around without any inclination of the cervical vertebrae by the protection of the support frame 10. Therefore, the support frame is shown in the figure, and the adjusting unit 20 does not completely restrict the movement of the neck to provide a predetermined space to relax the neck muscles. It is worth mentioning that the neck wearable device in the preferred embodiment is not capable of replacing a medical collar for treatment. The neck wearable device is helpful for preventing cervical vertebra diseases in daily work or study and life.

In particular, as shown in fig. 9A and 9B, the support stand 10 according to the embodiment of the present invention includes at least two support legs 11 and a holding arm 12. The retaining arm 12 is foldably mounted to the support leg 11 and forms a retaining angle between the support leg 11 and the retaining arm 12. An adjusting angle is formed between the two supporting legs 11. The adjustment angle between the support leg 11 and the holding arm 12 is adjusted by the adjusting unit 20. The support legs 11 of the support stand 10 are supported around the head with a predetermined width according to the adjustment angle and the angle is adjusted as required. Preferably, the support legs 11 are supported on the front side of the user's body, as shown in fig. 9A, for example. Also preferably, the support legs 11 are supported on the rear side of the user's body, as shown in fig. 9B, for example.

The adjusting unit 20 includes a width adjusting mechanism 21 and a position adjusting mechanism 22. The width adjustment mechanism 21 is provided at both the support legs 11. The position adjustment mechanism 22 is disposed between the retaining arm 12 and the support leg 11 to connect the retaining arm 12 and the support leg 11 in an end-to-end manner. The width adjustment mechanism 21 is operable to vary the distance between the two support legs 11. The position adjustment mechanism 22 is operable to vary the distance between the support leg 11 and the retaining arm 12. Therefore, the support stand 10 is suitable for different users to adjust the distance and angle between the head and the neck.

It is worth mentioning that the holding arm 12 is rotated relative to the supporting leg 11 by the position adjusting mechanism 22 and causes the supporting stand 10 to be folded. When the support stand 10 is folded, the neck wearable device is at a minimum size for easy carrying or storage. In a state where the neck wearable device is used, the support leg 11 is first supported on the shoulder or the trunk of the user, and then the holding arm 12 is unfolded by rotating the position adjusting mechanism 22 to support the head of the user. The position adjusting mechanism 22 limits the holding angle to a value to keep the holding arm 12 from falling toward the supporting leg 11.

Preferably, the holding angle between the support legs 11 and the holding arms 12 is adjusted to match the angle between the neck and the chin of the user. Therefore, the support frame 10 can bear the weight of the head to prevent loosening of the neck.

Preferably, the adjustment angle between the two support legs 11 is adjusted to fit the dimensional width of the user's head.

According to the preferred embodiment, as shown in FIG. 11, the ends of the two support legs 11 are mounted on a pivot shaft 110 to form a V-shaped arrangement. The distance between the two support legs 11 is changed by the width adjustment mechanism 21, and the adjustment angle between the two support legs 11 is changed to fit the heads of different users. In order to fix the support stand 10 around the head, the width adjustment mechanism 21 needs to be operated to adjust the distance between the two support legs 11 when worn.

In other words, the end of the support leg 11 is rotatably connected with the pivot shaft 110. The free ends of the support leg 11, which are not connected to the pivot axis 110, are defined as a first end 111 and a second end 112, respectively. The retaining arm 12 also has a first end 121 and a second end 122. The first end 111 of the support leg 11 is pivotally connected to the first end 121 of the retaining arm 12 by the position adjustment mechanism 22. The second end 112 is pivotally connected to the second end 122 of the retaining arm 12 by the position adjustment mechanism 22.

In addition, the support stand 10 further includes a fastener 13, wherein the fastener 13 is configured to the retaining arm 12. Preferably, the retaining arm 12 and the fastener 13 are supported under the jaw and around the back of the head of the user, respectively. It should be noted that the fastening member 13 is provided with another width adjustment mechanism 21 for adjusting the length of the fastening member 13. As shown in fig. 11, by adjusting the adjustment angle between the two support legs 11 and adjusting the length of the fastening member 13, the head of the user is closely supported and held around the support frame 10.

The hardware unit 30 further comprises a low frequency massager mounted to the fastener 13. When the neck wearable device is worn by the user, the fastener 13 is tightly attached to the back of the neck of the user. The low frequency massager is controllably delivered a low frequency massage, preferably with the processor 31 connected thereto. It is worth mentioning that the fastening member 13 is preferably provided with two width adjustment mechanisms 21 for adjusting the length of the fastening member 13. That is, the position of the low frequency massager may vary with the position of the fastener 13. In addition, in a possible embodiment, the low frequency massager is connected to the processor 31 in a patch manner at the position adjusting mechanism 22. With the fasteners 13 removed, the low frequency massager may also be removed.

The retaining arm 12 has a retaining surface 120, wherein the retaining surface 120 is adapted to be disposed under the chin of the head. The retaining surface 120 of the retaining arm 12 has a curvature to accommodate the curvature of the user's mandible. The weight of the head is applied directly to the retaining surface 120 of the retaining arm 12. The retaining surface 120 also limits the upward or downward tilting rotation of the neck. Since the holding angle is determined by the position adjustment mechanism 22, the holding surface 120 and the support leg 11 are held in a mutually fixed position if the position adjustment mechanism 22 is not released. Thus, the holding arm 12 and the supporting leg 11 continuously support the weight of the head, the neck of the user is in a neutral and natural position, and the neck load is reduced to prevent long-term fatigue.

In particular, the width adjustment mechanism 21 includes two connectors and an adjustment knob 213, as shown in FIG. 11, the width adjustment mechanism 21 disposed on the fastener 13 and another width adjustment mechanism 21 disposed between the support legs 11. Two of the width adjustment mechanisms 21 are substantially similar in construction, and it will be understood by those skilled in the art that the width adjustment mechanism 21 between the support legs 11 is merely illustrative and exemplary and that another width adjustment mechanism 21 is disposed on the fastener 13.

The two connectors of the width adjustment mechanism 21 are defined as a left connector 211 and a right connector 212. The adjustment knob 213 mates both the left connector 211 and the right connector 212. The left connector 211 and the right connector 212 are partially overlapped with each other. The adjustment knob 213 determines the length of the overlapping portion of the left and right connectors 211 and 212. When the adjustment knob 213 controls the overlapping portions of the left and right connectors 211 and 212 as much as possible, the entire length of the left and right connectors 211 and 212 is as short as possible, that is, the length of the width adjustment mechanism 21 is as short as possible. Similarly, when the adjusting knob 213 controls the overlapping portion of the left connector 211 and the right connector 212 to be as long as possible, the entire length of the left connector 211 and the right connector 212 is as long as possible, that is, the length of the width adjusting mechanism 21 is as long as possible.

Those skilled in the art will appreciate that when the length of the width adjustment mechanism 21 is adjusted, the distance between the two support legs 11 is adjusted accordingly, according to fig. 11. The angle of adjustment and the width of the support frame 10 are thus adjustable.

As shown in fig. 10 and 12, the position adjustment mechanism 22 includes a movable arm 221, an arm 222, and an unlock switch 223. The movable fulcrum 221 is disposed at the free end of the support leg 11, and the fulcrum 222 is disposed at the end of the holding arm 12. The hand 222 is pivotally connected to the movable hand 221, and the unlocking switch 223 is controllably connected to the movable hand 221 and the electrostatic hand 222. The angle of rotation of the movable hand support 221 and the hand support 222 determines the holding angle between the support leg 11 and the holding arm 12 to match the angle between the neck and chin of different users.

When the unlock switch 223 is not operated to hold the rotation angle of the movable hand 221 to the hand 222, the movable hand 221 is restricted in position by the hand 222. The retaining arm 12 is held in position against the limb 222 relative to the support leg 11. The holding surface 120 and the supporting leg 11 are held in a mutually fixed position. When the unlock switch 223 is operated to release the angle between the hand 222 and the movable hand 221, the position of the movable hand 221 is not limited and is folded together with the hand 222 under the influence of gravity.

In other words, when the unlock switch 223 is operated to release the movable fulcrum 221, the holding arm 12 is released from the weight restriction of the position adjustment mechanism 22, and the movable fulcrum 221 is folded toward the fulcrum 222 lowered in the holding arm 12 of the supporting leg 11 with the supporting leg 11. When the unlock switch 223 is not operated, the holding angle is limited by the electrostatic hand 222 and the movable hand 221. Therefore, when the movable finger 221 rotates away from the finger 222, the holding angle increases and the support surface 120 rises and stays at a position under the restriction of the unlock switch 223.

In the preferred embodiment, two of the position adjustment mechanisms 22 are substantially similar in construction, and the position adjustment mechanisms 22 are disposed between the second end 112 and the second end 122, with the other position adjustment mechanism 22 being disposed between the first end 111 and the first end.

The holder 222 provides a receiving chamber 2210, wherein the receiving chamber 2210 is formed between an inner housing 2221 and an outer housing 2222 covering the inner housing 2221. The movable finger 221 includes a rotation shaft 2111 and a rotation gear 2212, wherein the rotation gear 2212 is coaxially mounted on the rotation shaft 2111. The rotation shaft 2111 and the rotation gear 2212 are accommodated in a housing chamber 2210. The unlock switch 223 is installed in the accommodation chamber 2210 and extends to the outside of the housing 2222. In other words, the unlock switch 223 is partially located inside the accommodation chamber 2210 and partially located outside the accommodation chamber 2210.

The threo fox rotating gear 2212 of the movable hand 221 is restricted from rotating about the rotating shaft 2211 in a one-way direction by the unlocking switch 223. As shown in fig. 12, the rotary gear 2212 of the movable hand 221 can rotate upward against the hand 222, and therefore the movable hand 221 can expand the holding angle with the hand 222 only by releasing the firm support of the switch. In other words, by restricting the unlock switch 223, the holding arm 12 is rotated upward to be unfolded from the supporting leg 11.

Until the unlocking switch 223 is operated from the outside of the accommodating chamber 2210, the movable hand 221 loses the relatively fixed supporting force, and falls toward the hand 222 with respect to the hand 222. As gravity acts, the retaining arm 12 rotates to fold with the support leg 11. Therefore, by operating the unlocking switch 223, the holding arm 12 is released to be supported and folded toward the supporting leg 11 to reduce the size of the neck wearable device for storage and carrying.

By operating the unlocking switch 223 outside the accommodation chamber 2210, the unlocking switch 223 is driven to release the rotary gear 2212 of the movable hand 221. The unlocking switch 223 includes a blocking portion 2232 movably engaged with the rotary gear 2212, a fulcrum 2233 and a pressing portion 2234. The pressing portion 2234 extends from the blocking portion 2232 to the outside of the accommodation chamber 2210 via the fulcrum 2233. Further, the blocking portion 2232 and the pressing portion 2234 are integrally formed around the fulcrum 2233 in a lever manner. By pressing the pressing portion 2234, the blocking portion 2232 is moved upward and away from the rotary gear 2212.

The unlocking switch 223 includes a resilient portion 2231, wherein the movement of the blocking portion 2232 is restricted by the resilient portion 2231 being mounted in the accommodating chamber 2210. When the pressing portion 2234 is not pressed down, the blocking portion 2232 is pushed by the elastic portion 2231 to be engaged with the rotary gear 2212. Upon rotation of the movable hand 221, the rotation gear 2212 is rotated around the rotation shaft 2211, different teeth of the rotation gear 2212 are engaged with the blocking portion 2232, and the elastic portion 2231 of the unlocking switch 223 restricts close contact of the blocking portion 2232.

According to the present preferred embodiment, the blocking portion 2232 is shaped like a hook, which restricts the rotation gear 2212 of the movable hand 221 from rotating upward about the rotation axis 2211. The rotation gear 2212 cannot rotate relative to the hook portion of the blocking portion 2232 by the elastic force of the elastic portion 2231.

The elastic portion 2231 is preferably made of a piece of bent metal to restrict the movement of the blocking portion 2232 without being disengaged from the rotary gear 2212.

When the pressing portion 2234 is not pressed down, the blocking portion 2232 is pressed by the elastic portion 2231 to be forced into engagement with the rotary gear 2212. The rotation gear 2212 of the movable hand 221 is rotated to increase the holding angle between the movable hand 221 and the hand 222, and the position of the rotation gear 2212 is relatively fixedly supported to the blocking portion 2232. The movable finger 221 cannot be rotated downward, and the holding arm 12 is supported in position. The user can adjust the retaining arm 12 to a desired level with a suitable retaining arm and the retaining surface 120 is relatively fixed to support the user's chin. If the pressing portion 2234 of the unlocking switch 223 is not operated, the rotating gear 2212 of the movable fulcrum 221 of the holding arm 12 is mutually fixed in position against the blocking portion 2232 so as to be stably held on the supporting leg 11 with the fulcrum 222.

When the pressing portion 2234 is pressed, the blocking portion 2232 is separated from the rotary gear 2212, so that the rotary gear 2212 can be freely rotated about the rotary shaft 2211 to be lifted upward. Due to the weight of the holding arm 12, the movable leg 221 is released to descend and fold toward the leg 222. Therefore, by pressing the unlock switch 223, the holding arm 12 is folded by the position adjustment mechanism 22 and the support arm 11.

More importantly, the housing 2222 of the hand support 222 has an opening such that the pressing portion 2234 is coupled from the science 2221 to the rotation shaft 2211 of the movable hand support 221 received therein.

More, the neck wearable device further comprises the hardware unit 30, as shown in fig. 13A and 17. The hardware unit 30 is mounted on the support stand 10 and connected with an intelligent system to transmit signals between a user and the intelligent system. The signal can be sound signal, image signal, physiological signal, etc., and the data information mutually needed between the user and the intelligent system. The hardware unit 30 comprises a processor 31 and at least one electronic device connected to and controlled by the processor 31. According to an embodiment, the processor 31 is preferably mounted to the pivot axis 110 of the support stand 10.

In a more feasible embodiment, the hardware unit 30 is detachably connected to the support frame 10, and the support frame 10 provides an interface for connecting with the hardware unit 30 with different functions, so that the user can individually use different functions through external connection.

In other words, the hardware unit 30 preferably carries the neck wearable system. In particular, the interaction control module 100, the audiovisual module 200, the matching module 300 and the acquisition module 400 are implemented in the hardware unit 300 to acquire the usage data 800 at the time of the user.

The electronics of the hardware unit 30 may be removed for connection to additional electronics. As shown in fig. 13A and 13B, the hardware unit 30 includes a cosmetic device 14A, and the cosmetic device 13A is supported by the support stand 10. The beauty device 13A is detachably attached to the holding arm 12. The two beauty devices 13A are respectively mounted on the first end 121 and the second end 122 of the holding arm 12 and rotatably connected so that the positions of the beauty devices 13A with respect to the head of the user can be respectively adjusted.

The hardware unit 30 further includes a data glasses 14B, and the data glasses 14B are supported by the support frame 10. The data glasses 14B are removably mounted to the retaining arms 12. The ends of the data glasses 14B are mounted to the first and second ends 121 and 122, respectively, of the holder arm 12 and are rotatably connected such that the position of the data glasses 14B relative to the user's head can be adjusted, respectively.

Furthermore, the beauty device 13A can be removed from the external interface 130 and replaced with the data glasses 14B, thereby enjoying the functions of different electronic devices. The external interface 130 may further be implemented on the support frame 10, such as by means of a snap, magnetic attraction, or friction fit, to provide the access function of the hardware unit 30.

As illustrated in fig. 14, the hardware unit 30 includes at least one sensor, in the preferred embodiment, a heartbeat sensor 341 and at least one neck rotation sensor 342, by way of example. The heartbeat sensor 341 is mounted on the pivot axis 110 of the support stand 10. Since the support legs 11 are closely supported on the chest of the user, the heartbeat sensor 341 is in close proximity to the heart of the user, and heartbeat data can be detected with high accuracy. The neck rotation sensor 342 is mounted on the position adjusting mechanism 22 to detect the holding angle, which is a parameter for measuring and recording the health of the cervical vertebrae.

In particular, the neck state in the usage data 800 is acquired by the neck rotation sensor 341 for the height, angle and rotation of the neck.

Other electrical components of the hardware unit 30 are a microphone 32 and an earphone 33. As shown in fig. 15, the microphone 32 is mounted on the holding arm 12, and the microphone 32 is connected to the processor 31 to receive a user's voice signal. The earpiece 33 is mounted at the end of the holding arm 12, the earpiece 33 being connected to the processor 31 for providing audible signal feedback to the user.

Preferably, the microphone 32 is mounted near the user's mouth. Since the holding surface 120 of the holding arm 12 is located under the chin of the user, the microphone 32 is easily close to the mouth of the user. The microphone 32 is capable of receiving the user's voice with high accuracy over a relatively short physical distance. The sound signals received by the microphone 32 are used for control instructions of the intelligent system via the processor 31. Thus, the user does not need to speak loudly in order to be received by the intelligent system, and the intelligent system can be placed anywhere regardless of the voice transmission distance.

Preferably, the earphone 33 employs bone conduction technology. The ear piece 33 extends upwardly from the ends 121, 122 of the holding arm 12. Thus, the earphone 33 is adapted to allow the earphone 33 to reach the ear of the user while wearing the holding arm 12. Furthermore, the headset 33 is preferably made of an elastic material to accommodate different users' ears. As shown in fig. 15, the usage data 800 obtained by the neck rotation sensor 342 is displayed on the external control device 900 by the interactive control module 100. The external control device 900 provides an interface for the interactive control module 100 and user control instructions. By mounting the interactive control module 100 on the external control device 900, the user can know the neck rotation data in real time through the interactive control module 100, and can control and operate the audiovisual module 200, the matching module 300, and the acquisition module 400. In a preferred case, the user can view the information of the neck rotation sensor 342 displayed on the display unit 210 from the external control apparatus 900, and listen to the information of the audio unit 220 from the earphone 33 of the neck wearable apparatus. In addition, the data of the angle acquisition unit 410, the height acquisition unit 420 and the rotation degree acquisition unit 430 of the acquisition module 400 are also displayed, so that the user can obtain whether the neck state is normal from the feedback of the external control device 900 without the intervention of the matching module 300.

As shown in fig. 16, the electronics of the hardware unit 30 are implemented as a low frequency massager 35. Wherein the low frequency massager 35 is mounted to the fastener 13. When the neck wearable device is worn by the user, the fastener 13 is tightened to the back of the user's neck. The low frequency massager 35 is controllable to deliver a low frequency massage, preferably the processor 31 is connected to the low frequency massager 35. It is worth mentioning that the fastening member 13 is preferably provided with two width adjustment mechanisms 21 for adjusting the length of the fastening member 13. That is, the position of the low frequency massager 35 may vary with the position of the fastener 13. In addition, in a possible embodiment, the low-frequency massage device 35 is connected to the processor 31 in a patch manner at the position adjusting mechanism 22. With the fasteners 13 removed, the low frequency massager 35 may also be removed.

It is worth mentioning that the battery 37, which is used to power the low frequency massage unit 35, is also mounted on the support frame 10. The weight of the battery 37 is borne on the trunk or the shoulders of the user by the support frame 10, so that the low-frequency massager 35 can be used by being provided with the battery 37 with larger capacity.

Preferably, the electrical connection 300 of the low frequency massager 35 and the processor 31 is embedded in the support frame 10 for stable connection and reducing the risk of abrasion of the connection.

More specifically, a preferred schematic of the battery 37 and electrical connection 300 is shown in fig. 17. The electronics of the hardware unit 30 are implemented requiring the battery 37. For example, the earphone 33 is a noise reduction earphone, or the low frequency massager 35. For the headset 33 requiring a battery 37, the battery 37 is also mounted to the support frame 10, and the headset 33 is used without dropping the battery 37. In other possible embodiments the battery 37 is mounted to the fastener 13. The electrical wiring 300 runs along the support leg 11. That is, the electrical wiring 300 is installed by means of the support stand 10 such that the hardware unit 30 is closely mounted to the support stand 10 and the weight of the hardware unit 30 can be carried by the support stand 10. It is worth mentioning that, in the state that the support frame 10 is worn, the weight of the hardware unit 30 is borne by the shoulder or the trunk of the user. It is worth mentioning that the battery 37, which is used to power the low frequency massage unit 35, is also mounted on the support frame 10. The weight of the battery 37 is borne on the trunk or the shoulders of the user by the support frame 10, so that the low-frequency massager 35 can be used by being provided with the battery 37 with larger capacity.

Preferably, the electrical wiring 300 is embedded inside the support leg 11. The support legs 11 protect the electrical connection 300 from external influences, reducing the probability of damage.

More, the hardware unit 30 further comprises a switch 36, the switch 36 being controllably connected to the processor 31. The switch 36 can be used to input control instructions to the processor 31, and the processor 31 is accordingly controlled to perform corresponding processing. In the preferred embodiment, the switch 36 is located at the pivot 110 at the end of the support leg 11. For example, by clicking the switch 36, the processor 31 passes the sound signal collected by the microphone 32 to the selected intelligent system.

It will be appreciated by persons skilled in the art that the embodiments of the invention described above and shown in the drawings are given by way of example only and are not limiting of the invention. The objects of the invention have been fully and effectively accomplished. The functional and structural principles of the present invention have been shown and described in the examples, and any variations or modifications of the embodiments of the present invention may be made without departing from the principles.

Claims (10)

1. A neck wearable system, comprising:

an interactive control module, an audio-visual module and an acquisition module.

2. The neck wearable system of claim 1, wherein the interactive control module is controllably connected to the audiovisual module, wherein the capture module captures usage data related to the neck of the user, and wherein the interactive control module is controlled to issue control commands to the audiovisual module according to the usage data for the usage data to be fed back through the audiovisual module.

3. The neck wearable system of claim 2, wherein the neck wearable system further comprises a matching module, wherein audiovisual module, the matching module, and the acquisition module are cooperatively connected under control of the interactive control module, wherein the matching module obtains an assessment of neck status based on the usage data.

4. The neck wearable system of claim 3, wherein the matching module evaluates according to preset criteria data.

5. The neck wearable system of claim 3, wherein the matching module evaluates against a history of the usage data.

6. The neck wearable system of claim 3, wherein the matching module obtains user neck bow data from the usage data.

7. A neck wearable platform adapted to provide neck status to at least one user, comprising:

at least one neck wearable system and a processing center.

8. The neck wearable platform of claim 8, wherein the processing center manages and stores a usage data related to a user's neck, wherein the processing center is selectively configured to provide a base data to the neck wearable system, wherein the processing center provides for uploading and downloading of personal login data of at least one user.

9. A neck wearable device, comprising:

a support frame and at least one hardware unit.

10. The neck wearable device of claim 9, wherein the hardware unit is mounted to the support frame to communicate signals with a user around the support frame.

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