CN106961139A - The continuation of the journey method for improving and Intelligent worn device of a kind of Intelligent worn device - Google Patents

Abstract

The invention discloses a method for improving battery life of a smart wearable device, comprising the following steps: S10, acquiring the current working mode of the smart wearable device; S20, acquiring the remaining battery capacity of a rechargeable battery on the smart wearable device; S30, according to each According to the preset battery remaining quantity corresponding to each of the working modes, it is judged whether the battery remaining quantity is lower than the preset battery remaining quantity; S40, when the battery remaining quantity is lower than the preset battery remaining quantity, then select the charging mode of the rechargeable battery; S50 . The smart wearable device charges the rechargeable battery in the selected charging mode. The present invention converts kinetic energy generated during exercise, solar energy, and thermal energy generated by temperature difference into electric energy and stores it in a lithium battery without increasing the battery capacity, prolonging the battery life of the smart watch; significantly improving the battery life of the smart wearable device , so that users no longer worry about the battery life of smart wearable devices.

Description

A battery life improvement method of a smart wearable device and the smart wearable device

technical field

The invention belongs to the technical field of smart wearable devices, and in particular relates to a method for improving battery life of a smart wearable device and the smart wearable device.

Background technique

With the continuous development of science and technology, after the functions of smart wearable devices have been gradually improved, a large number of smart wearable devices have flooded into the market rapidly, and their smart watches and smart bracelets are more representative, especially smart watches.

Its smart watches are mainly divided into the following categories: (1) Smart watches without call function: relying on the connection to a smart phone to achieve multi-function, and can synchronously operate phone calls, text messages, emails, photos, music, etc. in the phone. (2) Smart watch with calling function: it supports the insertion of SIM card, which is essentially a smart phone in the form of a watch.

As the functions of smart wearable devices are gradually enriched, their power consumption is also gradually increasing, which shortens the battery life. Rechargeable lithium batteries on smart wearable devices rely on large capacity to prolong the battery life of smart wearable devices. However, the shape of the smart wearable device itself limits the size of the body, which in turn restricts the capacity of the battery, which makes the battery life of the smart wearable device worrying for users.

Therefore, the battery life of smart wearable devices is difficult for users to accept, resulting in embarrassing situations for smart wearable devices in the market. On the premise of not increasing the battery capacity, how to break through the battery life limit of smart wearable devices has become an urgent problem to be solved.

Contents of the invention

The technical scheme provided by the invention is as follows:

The present invention provides a method for improving battery life of a smart wearable device, comprising the following steps: S10, acquiring the current working mode of the smart wearable device, the working mode includes a daytime working mode and a nighttime working mode; S20, acquiring the smart The battery remaining amount of the rechargeable battery on the wearable device; S30, according to the preset battery remaining amount corresponding to each working mode, determine whether the battery remaining amount is lower than the preset battery remaining amount; S40, when the battery When the remaining amount is lower than the preset battery remaining amount, select the charging mode of the rechargeable battery; the charging mode includes temperature difference charging mode, sports charging mode, and solar charging mode; S50, the smart wearable device is in the In the selected charging mode, the rechargeable battery is charged.

Further, the step S30 further includes: S31, according to the first preset battery remaining amount corresponding to the daytime working mode, judging whether the battery remaining amount is lower than the first preset battery remaining amount; the step S40 further includes: S411, when the battery remaining amount is lower than the first preset battery remaining amount, judging whether the smart wearable device is currently in a motion state; S412, when the smart wearable device is currently in a motion state , then prompt the user to select the charging mode of the rechargeable battery as the sports charging mode; S413. When the smart wearable device is not currently in a sports state, prompt the user to select the charging mode of the rechargeable battery as the solar charging mode.

Further, the step S30 further includes: S32, according to the second preset battery remaining amount corresponding to the daytime working mode, judging whether the battery remaining amount is lower than the second preset battery remaining amount; the step S40 further includes: S414, when the battery remaining amount is lower than the second preset battery remaining amount, judging whether the smart wearable device is currently in a motion state; S415, when the smart wearable device is currently in a motion state , then automatically select the charging mode of the rechargeable battery as motion charging mode, solar charging mode, and/or temperature difference charging mode; S416, when the smart wearable device is not currently in a motion state, automatically select the rechargeable battery The charging modes are solar charging mode and temperature difference charging mode.

Further, the step S30 further includes: S33, according to the third preset battery remaining amount corresponding to the night working mode, judging whether the battery remaining amount is lower than the third preset battery remaining amount; the step S40 The method further includes: S421. When the remaining amount of the battery is lower than the third preset remaining amount of the battery, judging whether the smart wearable device is currently in an exercise state; S422. When the smart wearable device is currently in an exercise state, Prompt the user to select the charging mode of the rechargeable battery as the sports charging mode; S423. When the smart wearable device is not currently in motion, prompt the user to select the charging mode of the rechargeable battery as the temperature difference charging mode.

Further, the step S30 further includes: S34, according to the fourth preset battery remaining amount corresponding to the night working mode, judging whether the battery remaining amount is lower than the fourth preset battery remaining amount; the step S40 The method further includes: S424. When the remaining amount of the battery is lower than the fourth preset remaining amount of the battery, judging whether the smart wearable device is currently in a motion state; S425. When the smart wearable device is currently in a motion state, Then automatically select the charging mode of the rechargeable battery as the motion charging mode and the temperature difference charging mode; S426. When the smart wearable device is not currently in a motion state, automatically select the charging mode of the rechargeable battery as the temperature difference charging mode .

The present invention also provides a smart wearable device, including: a mode acquisition module, used to acquire the current working mode of the smart wearable device, and the working mode includes a daytime work mode and a nighttime work mode; The battery remaining amount of the rechargeable battery on the smart wearable device; a judging module, configured to judge whether the remaining battery amount is lower than the preset battery remaining amount according to the preset battery remaining amount corresponding to each working mode; A selection module, configured to select a charging mode of the rechargeable battery when the remaining battery capacity is lower than the preset battery remaining capacity; the charging mode includes a temperature difference charging mode, a sports charging mode, and a solar charging mode; The charging control module is used for the smart wearable device to charge the rechargeable battery in the selected charging mode.

Further, it also includes a prompt module: the judging module, configured to judge whether the battery remaining capacity is lower than the first preset battery remaining capacity according to the first preset battery remaining capacity corresponding to the daytime working mode; The judging module is also used for judging whether the smart wearable device is currently in a motion state when the battery remaining amount is lower than the first preset battery remaining amount; the prompting module is used for when the When the smart wearable device is currently in motion, the user is prompted to select the charging mode of the rechargeable battery as the sports charging mode; the prompt module is also used to prompt the user to select the charging mode when the smart wearable device is not currently in motion. The charging mode of the rechargeable battery is solar charging mode.

Further, the judging module is also used to judge whether the remaining battery power is lower than the second preset battery remaining power according to the second preset battery remaining power corresponding to the daytime working mode; the judging module is also used to determine whether the smart wearable device is currently in a motion state when the remaining battery level is lower than the second preset battery remaining level; the selection module is also used to determine whether the smart wearable device is currently in motion Currently in a state of motion, the charging mode of the rechargeable battery is automatically selected as motion charging mode, solar charging mode, and/or temperature difference charging mode; the selection module is also used when the smart wearable device is not currently in motion state, the charging mode of the rechargeable battery is automatically selected as the solar charging mode and the temperature difference charging mode.

Further, the judging module is also used to judge whether the remaining battery power is lower than the third preset battery remaining power according to the third preset battery remaining power corresponding to the night working mode; the judging module, It is also used for judging whether the smart wearable device is currently in a motion state when the battery remaining amount is lower than the third preset battery remaining amount; the prompt module is also used for when the smart wearable device is currently In the exercise state, the user is prompted to select the charging mode of the rechargeable battery as the exercise charging mode; the prompt module is also used to prompt the user to select the rechargeable battery when the smart wearable device is not currently in the exercise state. The charging mode is the temperature difference charging mode.

Further, the judging module is also used to judge whether the remaining battery power is lower than the fourth preset battery remaining power according to the fourth preset battery remaining power corresponding to the night working mode; the judging module, It is also used for judging whether the smart wearable device is currently in a motion state when the battery remaining amount is lower than the fourth preset battery remaining amount; the selection module is also used for when the smart wearable device is currently In the state of motion, the charging mode of the rechargeable battery is automatically selected as the motion charging mode and the temperature difference charging mode; the selection module is also used to automatically select the charging mode when the smart wearable device is not currently in motion. The charging mode of the rechargeable battery is the temperature difference charging mode.

Compared with the prior art, the battery life improvement method of the smart wearable device and the smart wearable device provided by the present invention have the following beneficial effects:

1), the present invention converts kinetic energy generated during exercise, solar energy, and thermal energy generated by temperature difference into electrical energy and stores it in a lithium battery without increasing the battery capacity, prolonging the battery life of the smart watch; significantly improving the smart wearable device The battery life of the smart wearable device makes users no longer worry about the battery life of smart wearable devices.

2) In the daytime working mode, the present invention sets the first preset remaining battery level to remind the user to charge, and the user can choose to charge or not to charge according to the actual situation, which improves the user experience. In the daytime working mode, the second preset battery remaining amount for automatic charging can be set, and the corresponding charging mode can be automatically selected to charge the rechargeable battery, so as to prevent the smart wearable device from being unable to work due to lack of power.

3) The present invention sets a third preset remaining battery level to remind the user to charge in the night work mode, and the user can choose to charge or not to charge according to the actual situation, which improves the user experience. In the night work mode, the fourth preset battery remaining amount for automatic charging can be set, and the corresponding charging mode can be automatically selected to charge the rechargeable battery, so as to prevent the smart wearable device from being unable to work due to lack of power. Wherein, the preset remaining battery capacity in the daytime working mode and the nighttime working mode is set to different parameters, so as to satisfy different restrictions on energy acquisition during the daytime and at nighttime.

Description of drawings

In the following, a preferred implementation mode will be described in a clear and understandable manner with reference to the accompanying drawings, and a method for improving battery life of a smart wearable device, as well as the above-mentioned characteristics, technical features, advantages and implementation methods of the smart wearable device will be further described.

Fig. 1 is a schematic flow chart of a method for improving battery life of a smart wearable device according to the present invention;

Fig. 2 is a schematic flow chart of another battery life improvement method of a smart wearable device according to the present invention;

Fig. 3 is a schematic flow chart of another battery life improvement method of a smart wearable device according to the present invention;

Fig. 4 is a schematic diagram of the composition and structure of a smart wearable device according to the present invention.

Explanation of reference numbers:

11. Mode acquisition module, 12. Power acquisition module, 13. Judgment module, 14. Prompt module, 15. Selection module, 16. Charging control module.

detailed description

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the specific implementation manners of the present invention will be described below with reference to the accompanying drawings. Obviously, the accompanying drawings in the following description are only some embodiments of the present invention, and those skilled in the art can obtain other accompanying drawings based on these drawings and obtain other implementations.

In order to make the drawing concise, each drawing only schematically shows the parts related to the present invention, and they do not represent the actual structure of the product. In addition, to make the drawings concise and easy to understand, in some drawings, only one of the components having the same structure or function is schematically shown, or only one of them is marked. Herein, "a" not only means "only one", but also means "more than one".

As shown in FIG. 1, according to an embodiment of the present invention, a method for improving battery life of a smart wearable device includes the following steps: S10. Obtain the current working mode of the smart wearable device, and the working mode includes a daytime working mode , Night work mode.

S20. Obtain the remaining battery capacity of the rechargeable battery on the smart wearable device, for example, the remaining battery capacity is 70% or 50% of the rated capacity of the rechargeable battery.

S30. According to the preset battery remaining quantity corresponding to each working mode, determine whether the battery remaining quantity is lower than the preset battery remaining quantity.

S40. When the remaining amount of the battery is lower than the preset remaining amount of the battery, select the charging mode of the rechargeable battery on the smart wearable device; the charging mode includes a temperature difference charging mode, a sports charging mode, and a solar charging mode . Otherwise, jump to step S10.

S50. The smart wearable device charges the rechargeable battery in the selected charging mode.

Specifically, smart wearable devices include smart watches and smart bracelets, and the working mode of the smart wearable device can be set as daytime or nighttime according to the time on the smart wearable device, for example: 7:00-16:59 for daytime work mode, 17:00～6:59 is the night work mode. On the smart wearable device, when the current time reaches 7:00, it will automatically switch from night mode to daytime working mode; when the current time reaches 17:00, it will automatically switch from daytime mode to nighttime working mode. Different preset remaining battery levels can be set in the daytime working mode and nighttime working mode to meet the difference in energy obtained during the day and night.

As shown in FIG. 2, according to another embodiment of the present invention, a method for improving battery life of a smart wearable device includes the following steps: S10. Obtain the current working mode of the smart wearable device, and the working mode includes daytime work mode, night work mode.

S20. Obtain the remaining battery capacity of the rechargeable battery on the smart wearable device.

S31. According to the first preset battery remaining amount corresponding to the daytime working mode, determine whether the battery remaining amount is lower than the first preset battery remaining amount.

S411. When the battery remaining amount is lower than the first preset battery remaining amount, determine whether the smart wearable device is currently in a motion state. Otherwise, jump to step S10.

S412. When the smart wearable device is currently in a motion state, prompt the user to select the charging mode of the rechargeable battery on the smart wearable device as a sports charging mode.

S413. When the smart wearable device is not currently in motion, prompt the user to select the solar charging mode as the charging mode of the rechargeable battery on the smart wearable device.

Preferably, the method further includes: S32. According to the second preset battery remaining amount corresponding to the daytime working mode, further judging whether the battery remaining amount is lower than the second preset battery remaining amount.

S414. When the battery remaining amount is lower than the second preset battery remaining amount, determine whether the smart wearable device is currently in a motion state. Otherwise, jump to step S10.

S415. When the smart wearable device is currently in a motion state, automatically select the charging mode of the rechargeable battery on the smart wearable device as a sports charging mode, a solar charging mode, and/or a temperature difference charging mode.

S416. When the smart wearable device is not currently in motion, automatically select the charging mode of the rechargeable battery on the smart wearable device as a solar charging mode and a temperature difference charging mode.

S50. The smart wearable device charges the rechargeable battery in the charging mode selected by the user or automatically.

Specifically, set the first preset battery remaining amount and the second preset battery remaining amount in the daytime working mode, for example: the first preset battery remaining amount is 50% of the rated power of the rechargeable battery on the smart wearable device, and the second preset battery remaining amount is The preset remaining battery level is 20% of the rated capacity of the rechargeable battery on the smart wearable device.

When the remaining battery capacity of the smart wearable device (40% of the rated power of the rechargeable battery) is lower than 50% of the rated power of the rechargeable battery, the user is reminded to select a corresponding charging mode. When the user is in a state of exercise while wearing a smart wearable device, the user is reminded to prefer the sports charging mode, which converts kinetic energy into electrical energy and charges the rechargeable battery; otherwise, reminds the user to select the solar charging mode, which converts solar energy into electrical energy and recharges The battery is charged. When reminding the user to select the charging mode, the user can choose the corresponding reminder charging mode to charge; the user can also skip the reminder and give up charging; the user can also choose a charging mode other than the reminder. Choose Reminder's Sport Charging mode, and instead opt for Solar Charging mode. Since the user is more likely to exercise indoors, the sports charging mode is the best choice.

When the remaining battery capacity of the smart wearable device (19% of the rated power of the rechargeable battery) is lower than 20% of the rated power of the rechargeable battery, the corresponding charging mode is automatically selected to charge the smart wearable device to prevent the smart wearable device from No power, not working properly. When the smart wearable device is in motion, you can choose two charging modes: sports charging mode, solar charging mode (or temperature difference charging mode), or you can choose three charging modes: sports charging mode, solar charging mode, and temperature difference charging mode. It is possible to charge the rechargeable battery on the smart wearable device, and the rechargeable battery can be charged quickly.

As shown in FIG. 3, according to yet another embodiment of the present invention, a method for improving battery life of a smart wearable device includes the following steps: S10. Obtain the current working mode of the smart wearable device, and the working mode includes daytime work mode, night work mode.

S20. Obtain the remaining battery capacity of the rechargeable battery on the smart wearable device.

S33. According to the third preset battery remaining amount corresponding to the night working mode, determine whether the battery remaining amount is lower than the third preset battery remaining amount. Otherwise, jump to step S10.

S421. When the battery remaining amount is lower than the third preset battery remaining amount, determine whether the smart wearable device is currently in a motion state.

S422. When the smart wearable device is currently in a motion state, prompt the user to select the charging mode of the rechargeable battery on the smart wearable device as a sports charging mode.

S423. When the smart wearable device is not currently in motion, prompt the user to select the charging mode of the rechargeable battery on the smart wearable device as the temperature difference charging mode.

Preferably, the method further includes: S34. According to the fourth preset remaining battery level corresponding to the night working mode, judging whether the remaining battery level is lower than the fourth preset remaining battery level.

S424. When the battery remaining amount is lower than the fourth preset battery remaining amount, further determine whether the smart wearable device is currently in a motion state. Otherwise, jump to step S10.

S425. When the smart wearable device is currently in a motion state, automatically select the charging mode of the rechargeable battery on the smart wearable device as a sports charging mode and a temperature difference charging mode.

S426. When the smart wearable device is not currently in motion, automatically select the charging mode of the rechargeable battery on the smart wearable device as the temperature difference charging mode.

S50. The smart wearable device charges the rechargeable battery in the charging mode selected by the user or automatically.

Specifically, set the third preset battery remaining amount and the fourth preset battery remaining amount in the night work mode, for example: the third preset battery remaining amount is 60% of the rated power of the rechargeable battery on the smart wearable device, the second preset battery remaining amount is 60% of the rated power of the rechargeable battery on the smart wearable device, the second preset Let the remaining battery capacity be 30% of the rated capacity of the rechargeable battery on the smart wearable device.

When the remaining battery capacity of the smart wearable device (59% of the rated power of the rechargeable battery) is lower than 60% of the rated power of the rechargeable battery, the user is reminded to select the corresponding charging mode, and when the smart wearable device is in motion, the user is reminded The preferred sports charging mode converts kinetic energy into electrical energy to charge the rechargeable battery; otherwise, reminds the user to select the temperature difference charging mode to convert the temperature difference into electrical energy to charge the rechargeable battery. When reminding the user to select the charging mode, the user can choose the corresponding reminder charging mode to charge; the user can also skip the reminder and give up charging; the user can also choose a charging mode other than the reminder, for example: when the user only exercises for a short time, Do not choose the sports charging mode that reminds you, but choose the temperature difference charging mode.

When the remaining battery capacity of the smart wearable device (29% of the rated power of the rechargeable battery) is lower than 30% of the rated power of the rechargeable battery, the corresponding charging mode is automatically selected to charge the smart wearable device to prevent the smart wearable device from No power, not working properly. When the smart wearable device is in motion, you can choose two charging modes: sports charging mode and temperature difference charging mode, to charge the rechargeable battery on the smart wearable device as much as possible, and to charge the rechargeable battery quickly. Since it is easier for smart wearable devices to obtain motion energy and solar energy during the day than at night, different preset battery remaining levels can be set during the day and night to meet the different restrictions on obtaining energy during the day and night.

As shown in FIG. 4 , according to an embodiment of the present invention, a smart wearable device includes: a mode acquisition module 11, configured to acquire the current working mode of the smart wearable device, and the working mode includes daytime work mode, Night work mode.

The power acquisition module 12 is configured to acquire the remaining battery capacity of the rechargeable battery on the smart wearable device.

The judging module 13 is configured to judge whether the remaining battery power is lower than the first preset remaining battery power according to the first preset remaining battery power corresponding to the daytime working mode.

The judging module 13 is further configured to judge whether the smart wearable device is currently in a motion state when the remaining battery level is lower than the first preset battery remaining level.

The prompt module 14 is configured to prompt the user to select the charging mode of the rechargeable battery on the smart wearable device as the sports charging mode when the smart wearable device is currently in a motion state.

The prompt module 14 is also used to prompt the user to select the solar charging mode as the charging mode of the rechargeable battery on the smart wearable device when the smart wearable device is not currently in motion.

Preferably, it also includes: the judging module 13, further configured to judge whether the battery remaining quantity is lower than the second preset battery remaining quantity according to the second preset battery remaining quantity corresponding to the daytime working mode .

The judging module 13 is further configured to judge whether the smart wearable device is currently in a motion state when the remaining battery level is lower than the second preset battery remaining level.

The selection module 15 is configured to automatically select the charging mode of the rechargeable battery on the smart wearable device as a sports charging mode, a solar charging mode, and/or a temperature difference charging mode when the smart wearable device is currently in motion.

The selection module 15 is also used to automatically select the charging mode of the rechargeable battery on the smart wearable device as solar charging mode and temperature difference charging mode when the smart wearable device is not currently in a motion state.

Preferably, it further includes: the judging module 13, further configured to judge whether the remaining battery power is lower than the third preset battery remaining power according to the third preset battery remaining power corresponding to the night working mode.

The judging module 13 is further configured to judge whether the smart wearable device is currently in an exercise state when the remaining battery level is lower than the third preset battery remaining level.

The prompt module 14 is also used to prompt the user to select the charging mode of the rechargeable battery on the smart wearable device as the sports charging mode when the smart wearable device is currently in a motion state.

The prompt module 14 is also used to prompt the user to select the charging mode of the rechargeable battery on the smart wearable device as the temperature difference charging mode when the smart wearable device is not currently in motion.

Preferably, it further includes: the judging module 13, further configured to judge whether the remaining battery level is lower than the fourth preset battery remaining level according to the fourth preset battery remaining level corresponding to the night working mode.

The judging module 13 is further configured to judge whether the smart wearable device is currently in an exercise state when the remaining battery level is lower than the fourth preset battery remaining level.

The selection module 15 is also used to automatically select and select the charging mode of the rechargeable battery on the smart wearable device as a motion charging mode and a temperature difference charging mode when the smart wearable device is currently in motion.

The selection module 15 is also used to automatically select the charging mode of the rechargeable battery on the smart wearable device as the temperature difference charging mode when the smart wearable device is not currently in motion.

The charging control module 16 is used for the smart wearable device to charge the rechargeable battery in the charging mode selected by the user or automatically.

Specifically, a solar power generation layer (embedded with a solar power generation film) is installed on the strap of the smart wearable device for solar charging, and a thermoelectric energy converter (using a high conversion rate thermoelectric material to convert the temperature difference between the human body temperature and the ambient temperature, becomes Potential difference) for temperature difference charging; set a vibration energy harvesting module on the smart wearable device for motion charging. By detecting whether the motion direction, angular velocity, and acceleration of the smart wearable device change, it is determined whether the smart wearable device is in motion. The solar power generation layer converts light energy into electrical energy during the day; the thermoelectric energy converter senses the temperature difference between the human body temperature and the ambient temperature and converts it into a potential difference; electrical energy.

According to yet another embodiment of the present invention, a battery life improvement method of a smart wearable device includes the following steps:

A two-layer structure is added to the strap of the smart wearable device (such as a watch strap). One layer is a solar power generation layer, and a suitable solar power generation film is embedded in the strap to ensure sufficient light-receiving surface to maximize solar energy collection; The layer is a thermoelectric energy converter, which converts the temperature difference between the human body temperature and the ambient temperature by using high-conversion rate thermoelectric materials to become a potential difference; the core of the smart wearable device is the vibration energy collection module, which mainly includes the main control sub-module, human Motor energy conversion sub-module, kinetic energy conversion sub-module;

Detect and judge the power threshold of smart wearable devices (such as smart watches). If it is less than the set threshold, the three structures will be directly turned on for comprehensive energy conversion to maximize the energy collected and converted into electrical energy to prolong the battery life; if it is greater than the set threshold If the threshold is set, then the logic judgment of the next level is carried out.

Furthermore, the threshold is set for the actual power of the smart watch, and real-time monitoring and judgment are carried out through the main control module; if the actual power is less than the set threshold, the master command control is performed through the main control module, and all three structures are turned on , to collect all the current kinetic energy, thermal energy, and solar energy, convert them into electric energy to the maximum extent, collect and store them, so as to prolong the battery life; if the actual electric power is greater than the set threshold, priority will be given to judging the sports mode.

Judging the sports mode and daily activity mode of the smart watch, if the user enters the sports mode, the vibration energy collection module is turned on to realize the collection and conversion of kinetic energy. In the case of user activities, the battery of the smart watch is charged. The main realization principle is: the main control sub-module detects whether it is currently in the sports mode, and if so, the man-machine energy conversion sub-module is turned on to rotate the core component magnet device and start the kinetic energy conversion. The sub-module inputs the generated energy into the metal ring around the magnet device, and transmits the generated electric energy to the lithium battery. If it is not in sports mode but in daily activity mode, the mechanical energy is very weak, so another level of judgment is made.

Further, the main control sub-module detects changes in the current user's motion direction, angular velocity, and acceleration through Compass, G-sensor, and Gyroscope to determine whether the user is in motion mode. If the user enters the sports mode, the main control module sends an instruction to the man-machine energy conversion sub-module to start working, that is, the core component magnet device rotates to generate enough kinetic energy, and then starts the kinetic energy conversion sub-module according to the instruction to realize the rapid conversion of kinetic energy and electric energy. Transformation and energy collection, the generated electric energy enters the metal ring around the magnet device and is introduced into the lithium battery in the device to achieve electric energy storage. If the user does not enter the sports mode, but the daily activity mode, the above-mentioned mode is not activated, and the solar energy conversion mode is entered for determination.

Set the time interval between day and night. If it is daytime, the solar power generation belt in the strap will be activated to maximize the use of solar energy during the day. If it is dark, activate the thermoelectric energy converter in the strap to maximize the use of human body heat in the dark.

In the daily activity mode, the judgment is made according to the daytime and nighttime modes set by the software on the watch. If it is daytime, after the time information reaches the standard, the main control sub-module will issue an instruction to start the solar power generation belt in the strap to maximize the energy storage capacity and convert solar energy into electrical energy for real-time storage. If it is at night, after the time information reaches the standard, the main control sub-module will send an instruction to turn on the thermoelectric converter in the strap to maximize the use of the heat energy emitted by the human body at night, and convert the human body heat energy into electrical energy for maximum storage.

Specifically, the solar power generation layer and thermoelectric energy converter in the strap, as well as the vibration energy harvesting module. Fully collect solar energy, mechanical energy and thermal energy when the smart watch is worn on the wrist, convert it into electrical energy, and connect it to a lithium battery to provide power to extend the battery life of the smart watch. The energy harvesting and conversion of solar energy, thermal energy, and mechanical energy are realized by combining solar battery belts, thermoelectric energy converters, and vibration energy harvesting modules. By intelligently judging the start-up of the three major structures of the solar cell belt, the thermoelectric energy converter, and the vibration energy harvesting module, the solar energy, thermal energy, and mechanical energy can be used more efficiently. In the vibration energy collection module, the user's motion pattern is monitored through the man-machine energy conversion sub-module, and the main control module performs real-time startup control on the kinetic energy collection sub-module to collect all kinetic energy. In the vibration energy acquisition module, the conversion of kinetic energy and electric energy is realized through the kinetic energy collection sub-module and the energy conversion sub-module, and the energy is stored, and the collected power is controlled by the main control sub-module and adaptively transmitted to the smart watch.

The present invention realizes efficient collection and conversion of solar energy, thermal energy and mechanical energy by setting solar power generation belts and thermoelectric energy converters in the watchband, and vibration energy collection modules, and configuring intelligent pattern recognition, and starting different structural modules according to the patterns. Maximize the battery life of your smartwatch. At the same time, the operation is simple, the principle is concise, easy to implement, and the battery life is significantly enhanced.

It should be noted that the above embodiments can be freely combined as required. The above is only a preferred embodiment of the present invention, it should be pointed out that, for those of ordinary skill in the art, without departing from the principle of the present invention, some improvements and modifications can also be made, and these improvements and modifications can also be made. It should be regarded as the protection scope of the present invention.

Claims (10)

1. the continuation of the journey method for improving of a kind of Intelligent worn device, it is characterised in that comprise the following steps：

The mode of operation that S10, acquisition Intelligent worn device are presently in, the mode of operation includes mode of operation, night in the daytime Mode of operation；

S20, the residual capacity of battery for obtaining rechargeable battery in the Intelligent worn device；

S30, according to each self-corresponding default residual capacity of battery of every kind of mode of operation, judge the residual capacity of battery whether be less than institute State default residual capacity of battery；

S40, when the residual capacity of battery be less than the default residual capacity of battery when, then select the charging mould of the rechargeable battery Formula；The charge mode includes temperature difference charge mode, motion charge mode, solar charging power mode；

S50, the Intelligent worn device charge under the selected charge mode to the rechargeable battery.

2. the continuation of the journey method for improving of Intelligent worn device as claimed in claim 1, it is characterised in that：

The step S30 further comprises：

Mode of operation corresponding first presets residual capacity of battery in the daytime described in S31, basis, judges whether the residual capacity of battery is low In the described first default residual capacity of battery；

The step S40 further comprises：

S411, when the residual capacity of battery is less than the described first default residual capacity of battery, then judge the Intelligent worn device Currently whether it is kept in motion；

S412, it is currently at motion state when the Intelligent worn device, then points out user to select filling for the rechargeable battery Power mode is motion charge mode；

S413, it is not presently within motion state when the Intelligent worn device, then points out user to select the rechargeable battery Charge mode is solar charging power mode.

3. the continuation of the journey method for improving of Intelligent worn device as claimed in claim 1, it is characterised in that：

The step S30 further comprises：

Mode of operation corresponding second presets residual capacity of battery in the daytime described in S32, basis, judges whether the residual capacity of battery is low In the described second default residual capacity of battery；

The step S40 further comprises：

S414, when the residual capacity of battery is less than the described second default residual capacity of battery, then judge the Intelligent worn device Currently whether it is kept in motion；

S415, when the Intelligent worn device is currently at motion state, then automatically select the charging mould of the rechargeable battery Formula is motion charge mode, solar charging power mode, and/or temperature difference charge mode；

S416, when the Intelligent worn device is not presently within motion state, then automatically select the charging of the rechargeable battery Pattern is solar charging power mode and temperature difference charge mode.

4. the continuation of the journey method for improving of Intelligent worn device as claimed in claim 1, it is characterised in that：

The step S30 further comprises：

S33, the corresponding 3rd default residual capacity of battery of pattern of being worked at night according to, judge whether the residual capacity of battery is low In the described 3rd default residual capacity of battery；

The step S40 further comprises：

S421, when the residual capacity of battery is less than the described 3rd default residual capacity of battery, then judge the Intelligent worn device Currently whether it is kept in motion；

S422, it is currently at motion state when the Intelligent worn device, then points out user to select filling for the rechargeable battery Power mode is motion charge mode；

S423, it is not presently within motion state when the Intelligent worn device, then points out user to select the rechargeable battery Charge mode is temperature difference charge mode.

5. the continuation of the journey method for improving of the Intelligent worn device as described in any one in Claims 1 to 4, it is characterised in that：

The step S30 further comprises：

S34, the corresponding 4th default residual capacity of battery of pattern of being worked at night according to, judge whether the residual capacity of battery is low In the described 4th default residual capacity of battery；

The step S40 further comprises：

S424, when the residual capacity of battery is less than the described 4th default residual capacity of battery, then judge the Intelligent worn device Currently whether it is kept in motion；

S425, when the Intelligent worn device is currently at motion state, then automatically select and select filling for the rechargeable battery Power mode is motion charge mode and temperature difference charge mode；

S426, when the Intelligent worn device is not presently within motion state, then automatically select the charging of the rechargeable battery Pattern is temperature difference charge mode.

6. a kind of Intelligent worn device, it is characterised in that including：

Pattern acquiring module, for obtaining the mode of operation that Intelligent worn device is presently in, the mode of operation is included in the daytime Mode of operation, pattern of working at night；

Electricity acquisition module, the residual capacity of battery for obtaining rechargeable battery in the Intelligent worn device；

Judge module, for according to each self-corresponding default residual capacity of battery of every kind of mode of operation, judging the residual capacity of battery Whether the default residual capacity of battery is less than；

Selecting module, for when the residual capacity of battery is less than the default residual capacity of battery, then selecting the chargeable electricity The charge mode in pond；The charge mode includes temperature difference charge mode, motion charge mode, solar charging power mode；

Charge control module, for the Intelligent worn device under the selected charge mode, to the chargeable electricity Charged in pond.

7. Intelligent worn device as claimed in claim 6, it is characterised in that also including reminding module：

The judge module, for mode of operation corresponding first to preset residual capacity of battery in the daytime according to, judges the electricity Whether pond surplus is less than the described first default residual capacity of battery；

The judge module, is additionally operable to when the residual capacity of battery is less than the described first default residual capacity of battery, then judge institute State whether Intelligent worn device is currently kept in motion；

The reminding module, for being currently at motion state when the Intelligent worn device, then pointing out can described in user's selection The charge mode of rechargeable battery is motion charge mode；

The reminding module, is additionally operable to when the Intelligent worn device is not presently within motion state, then point out user's selection institute The charge mode for stating rechargeable battery is solar charging power mode.

8. Intelligent worn device as claimed in claim 6, it is characterised in that：

The judge module, is additionally operable to according to the corresponding second default residual capacity of battery of the mode of operation in the daytime, judge described in Whether residual capacity of battery is less than the described second default residual capacity of battery；

The judge module, is additionally operable to when the residual capacity of battery is less than the described second default residual capacity of battery, then judge institute State whether Intelligent worn device is currently kept in motion；

The selecting module, is additionally operable to when the Intelligent worn device is currently at motion state, then automatically selecting described can fill The charge mode of battery is motion charge mode, solar charging power mode, and/or temperature difference charge mode；

The selecting module, is additionally operable to when the Intelligent worn device is not presently within motion state, then automatically select it is described can The charge mode of rechargeable battery is solar charging power mode and temperature difference charge mode.

9. Intelligent worn device as claimed in claim 6, it is characterised in that：

The judge module, is additionally operable to the corresponding 3rd default residual capacity of battery of pattern of being worked at night according to, judges described Whether residual capacity of battery is less than the described 3rd default residual capacity of battery；

The judge module, is additionally operable to when the residual capacity of battery is less than the described 3rd default residual capacity of battery, then judge institute State whether Intelligent worn device is currently kept in motion；

The reminding module, is additionally operable to when the Intelligent worn device is currently at motion state, then point out user's selection described The charge mode of rechargeable battery is motion charge mode；

The reminding module, is additionally operable to when the Intelligent worn device is not presently within motion state, then point out user's selection institute The charge mode for stating rechargeable battery is temperature difference charge mode.

10. the Intelligent worn device as described in any one in claim 6~9, it is characterised in that：

The judge module, is additionally operable to the corresponding 4th default residual capacity of battery of pattern of being worked at night according to, judges described Whether residual capacity of battery is less than the described 4th default residual capacity of battery；

The judge module, is additionally operable to when the residual capacity of battery is less than the described 4th default residual capacity of battery, then judge institute State whether Intelligent worn device is currently kept in motion；

The selecting module, is additionally operable to when the Intelligent worn device is currently at motion state, then automatically select selection described The charge mode of rechargeable battery is motion charge mode and temperature difference charge mode；

The selecting module, is additionally operable to when the Intelligent worn device is not presently within motion state, then automatically select it is described can The charge mode of rechargeable battery is temperature difference charge mode.