WO2017206348A1 - Multifunctional intelligent suitcase - Google Patents

Abstract

A multifunctional intelligent suitcase, comprising a suitcase body (1) and a mobile control terminal (3). The suitcase body (1) is provided with an electronic combination lock (11), a microprocessor (12), a weight sensor (15), an electronic switch (23), a power supply module (26), an LED strip (24), and an air quality monitoring module (25). The weight sensor (15), the electronic combination lock (11), a control end of the electronic switch (23), and the air quality monitoring module (25) are all connected to the microprocessor (12). An input end and an output end of the electronic switch (23) are connected to the power supply module (26) and the LED strip (24), respectively. The air quality monitoring module (25) is used for acquiring current air quality information and transferring the current air quality information to the microprocessor (12). The microprocessor (12) is used for controlling the electronic switch (23) to be turned on when determining that the current air quality information does not reach a healthy air index. The mobile control terminal (3) comprises a controller (32) and a touch liquid crystal screen (35). The controller (32) and the microprocessor (12) are wirelessly connected to each other. The touch liquid crystal screen (35) is used for inputting operating information. The controller (32) is used for controlling, according to the input operating information, the microprocessor (12) to perform a corresponding action.

Description

Multifunctional smart luggage Technical field

The invention relates to the technical field of luggage, and in particular to a multifunctional smart luggage.

Background technique

When people travel, various suitcases become the first choice for people, and valuables are placed in the trunk. However, most of the existing luggage boxes are only provided with a combination lock to protect the inward items of the luggage, so as to prevent the items in the luggage from being stolen and have a single function.

Summary of the invention

It is an object of the present invention to provide a multifunctional smart case to solve the above technical problems.

The embodiment of the invention provides a multifunctional smart luggage package, comprising a luggage body and a mobile control terminal; wherein the luggage body is provided with an electronic code lock, a microprocessor, a first Bluetooth communication module, and a first remote wireless communication module. a weight sensor, an electronic switch, a power module, an LED strip, and an air quality monitoring module, the electronic code lock, the first Bluetooth communication module, the first remote wireless communication module, and the weight sensor are all related to the micro a processor connection; the mobile control terminal includes a controller, a second Bluetooth communication module, a second remote wireless communication module, and a touch screen, the second Bluetooth communication module, the second remote wireless communication module, and the The touch screens are all connected to the controller, the second Bluetooth communication module is wirelessly connected with the first Bluetooth communication module, the first remote wireless communication module and the second remote wireless communication module. One-to-one wireless connection, the microprocessor and the controller are connected to the second Bluetooth communication module at the first Bluetooth communication module , The data transmission by means of Bluetooth communication; liquid crystal panel of the touch input operation for a user channel The operation information includes an unlock password setting command, a set unlock password, an unlock command, an unlock password, and a weight information acquisition instruction, and the controller is configured to control the microprocessor to the electronic according to the operation information. Setting an unlock password of the password lock, or controlling the microprocessor to open the electronic password lock or displaying weight information sensed by the weight sensor on the touch screen; the input end of the electronic switch The control terminal and the output end are respectively connected to the power module, the microprocessor and the LED strip; the air quality monitoring module is connected to the microprocessor for collecting current air quality information and collecting The current air quality information is transmitted to the microprocessor, and the microprocessor stores a healthy air index and is used to output the control signal to control the electronic switch guide when it is determined that the current air quality information does not reach the healthy air index Passing, the LED light strip is illuminated.

Further, the controller includes a password setting module and a control module connected to the password setting module, the microprocessor includes a processing module and a storage module connected to the processing module, and the password setting module The control module is configured to generate the unlock password setting command and the set unlock password, and the control module receives the unlock password setting command and the set unlock password and controls the processing module to store the set unlock password In the storage module.

Further, the controller further includes an unlocking module connected to the control module, the unlocking module is configured to generate the unlocking instruction and the unlocking password, and the control module receives the unlocking instruction and the unlocking password And transmitting the unlocking command and the unlocking password to the processing module, the processing module determining whether the unlocking password matches a set unlocking password stored in the storage module, and matching the two The processing module turns on the electronic code lock.

Further, the mobile control terminal further includes a sound collector, the sound collector is connected to the controller, and the touch screen is used for a user to input a voice collection instruction to the controller, the controller Turning on the sound collector after receiving the voice collection instruction, the sound collector is configured to collect a sound signal of the user and transmit the sound signal to the controller, where the controller The voice signal is sent to the microprocessor.

Further, the multifunctional smart phone bag further includes a battery case including a box body, a flip cover and a slider assembly that are open on one side, and the box body is configured to receive a battery in the power module and is installed in the bag On the upper casing of the main body, one end of the flip cover is hinged to the casing, the other end of the flip cover is mounted with the slider assembly, and the slider is rotated when the flip cover is rotated to cover the casing The assembly is snap-fitted to the case.

Further, the slider assembly includes a sliding cavity, a sliding buckle and at least one elastic component, wherein the sliding cavity is detachably mounted on the flip cover, and the sliding buckle is located in the sliding cavity and can be along The slider is slid, the top end of the slider is provided with a buckle, and the top end of the box body is correspondingly provided with a card hole that cooperates with the buckle opening, and the elastic element is clamped at the bottom end of the slider Between the sliding chamber and the cover, when the flip is rotated to cover the casing, the restoring force of the elastic member urges the slider to move toward the hole.

Further, the cover plate is provided with an operation port extending through opposite sides of the cover plate. After the slider assembly is mounted on the cover plate, the operation port is opposite to the slider.

Further, a bottom of the bag body is provided with a roller, and the body of the bag is further provided with a hub motor and a radio frequency signal transmitter for driving the roller to rotate, and the wheel motor and the radio frequency signal transmitter are both a microprocessor connection, the mobile control terminal further comprising a radio frequency signal feedback device, the radio frequency signal transmitter is wirelessly connected to the radio frequency signal feedback device and configured to calculate an actual between the radio frequency signal transmitter and the radio frequency signal feedback device a distance, the microprocessor stores a set following distance, the microprocessor receives the actual distance and is used to determine whether the actual distance is greater than the following distance, and the actual distance is greater than the following distance The microprocessor turns on the hub motor.

Further, the radio frequency signal transmitter includes a first signal transceiving module and a distance calculating module connected to the first signal transceiving module, wherein the first signal transceiving module is configured to send the radio frequency The signal feedback device sends an electromagnetic wave signal and receives a feedback signal of the RF signal feedback device; the distance calculation module is configured to calculate an actual distance between the RF signal transmitter and the RF signal feedback device according to the feedback signal, and The actual distance is sent to the microprocessor.

Further, the radio frequency signal feedback device includes a second signal transceiving module and a feedback signal generating module connected to the second signal transceiving module, wherein the second signal transceiving module is configured to receive the radio frequency signal transmitter The electromagnetic wave signal and the feedback signal are sent to the radio frequency signal transmitter; the feedback signal generating module is configured to generate a feedback signal.

Compared with the prior art, the multifunctional smart bag of the invention has remote unlocking, remote setting password, self weighing, air quality monitoring, battery detachable and automatic following functions, which are convenient for people to use.

DRAWINGS

FIG. 1 is a schematic structural view of a multifunctional smart case of the present invention.

2 is a schematic block diagram of a multifunctional smart case of the present invention.

3 is a schematic block diagram of the microprocessor of FIG. 2.

4 is a schematic block diagram of the controller of FIG. 2.

FIG. 5 is a schematic block diagram of the RF signal transmitter of FIG.

6 is a schematic block diagram of the RF signal feedback device of FIG. 2.

Figure 7 is an exploded view of the flip cover and slider assembly of Figure 1.

The invention will be further illustrated by the following detailed description in conjunction with the accompanying drawings.

detailed description

The technical solutions provided by the present invention will be further described below with reference to the accompanying drawings.

Referring to FIG. 1 and FIG. 2, an embodiment of the present invention provides a multifunctional smart luggage package, including a luggage owner. Body 1 and mobile control terminal 3.

The luggage main body 1 is provided with an electronic code lock 11, a microprocessor 12, a first Bluetooth communication module 13, a first remote wireless communication module 14, a weight sensor 15, and a handle connected to the weight sensor 15 (not shown) ). The electronic code lock 11, the first Bluetooth communication module 13, the first remote wireless communication module 14, and the weight sensor 15 are all connected to the microprocessor 12.

The mobile control terminal 3 is, for example, a personal mobile smart phone, and includes a controller 32, a second Bluetooth communication module 33, a second remote wireless communication module 34, and a touch LCD panel 35, a second Bluetooth communication module 33, and a second remote wireless communication module. Both the 34 and the touch panel 35 are connected to the controller 32. The second Bluetooth communication module 33 is wirelessly connected to the first Bluetooth communication module 13 one-to-one, and the first remote wireless communication module 14 is wirelessly connected to the second remote wireless communication module 34 one-to-one.

It can be understood that the wireless connection is implemented between the controller 32 and the microprocessor 12 through two Bluetooth communication modules and two remote wireless communication modules, and the luggage main body 1 and the mobile control terminal 3 are respectively provided with a network communication selection module. When two Bluetooth communication modules can be normally connected, the mode of Bluetooth communication is preferentially selected for data transmission; when two Bluetooth communication modules cannot be normally connected, data transmission is performed by two remote wireless communication modules. It should be noted that the data transmission using the Bluetooth communication module is generally applied to short-distance data transmission. The so-called close-range data transmission means that the distance between the luggage main body 1 and the mobile control terminal 3 is 0-100 meters. The distance is the effective connection distance between the two Bluetooth modules. In the case of short-distance data transmission, the data transmission using the Bluetooth communication module can ensure the data transmission speed between the luggage main body 1 and the mobile control terminal 3 is fast, and the network resources can be saved.

The touch screen 35 is used for the user to input operation information, and the controller 32 controls the microprocessor 12 to perform corresponding operations according to the operation command input by the user. In this embodiment, the user inputs the unlock password setting command and the input unlock password by, for example, touching the liquid crystal panel 35, and the controller 32 controls the micro processing. The device 12 sets the unlock password of the electronic code lock 11; the user inputs the unlock command and the input unlock password through the touch panel 35, for example, and the controller 32 controls the microprocessor 12 to turn on the electronic code lock 11.

The weight sensor 15 is configured to sense the weight information of the luggage body 1 and is sent to the controller 32 through the microprocessor 12. The operation information input by the user further includes a weight information acquisition command, and the controller 32 inputs the weight information through the touch liquid crystal panel 35. The weight information is displayed on the touch liquid crystal panel 35 when the command is acquired, so that the user can know the weight of the luggage body 1. Specifically, the user senses the weight sensor 15 to sense the weight information of the luggage body 1 by operating the handle.

Specifically, in conjunction with FIG. 3 and FIG. 4, in the embodiment, the controller 32 includes a password setting module 320 and a control module 321 connected to the password setting module 320. The microprocessor 12 includes a processing module 120 and The storage module 121 connected to the processing module 120, the password setting module 320 is displayed on the touch screen 35 in the form of an identifier, and when the user inputs the unlock password setting command through the liquid crystal touch screen 35 and inputs the set unlock password. The password setting module 320 is configured to generate an unlock password setting command and a set unlock password, the control module 321 receives the unlock password setting command and the set unlock password, and the control processing module 120 stores the set unlock password in the storage. In module 121. It should be noted that the password setting module 320 is configured to generate an unlock password setting command and a set unlock password, and refers to generating digital information corresponding to the unlock password setting command and the set unlock password.

The specific principle of the user setting the unlock password is as follows: the user first clicks on the identifier of the password setting module 320 on the touch screen 35, and generates an unlock password setting command after the password setting module 320 is clicked, and the control module 321 receives the After the unlocking password setting command is executed, the control password setting module 320 is further displayed on the touch liquid crystal panel 35 in the form of an input interface, and the control module 321 sends the unlocking password setting command to the processing module 120, and the user passes the touch liquid crystal panel 35. Entering the set unlock password on the input interface, the password setting module 320 generates the set unlock password, the control module 321 receives the set unlock password and sends the set unlock password to the processing module 120, and the processing module 120 sets Fixed The unlocking password is stored in the storage module 121. It can be understood that the processing module 120 overwrites the unlocking password previously stored in the storage module 121.

In this embodiment, the controller 32 further includes an unlocking module 323 connected to the control module 321 . The unlocking module 323 is displayed on the touch liquid crystal screen 35 in the form of an identifier, and the user inputs an unlocking command through the touch liquid crystal panel 35 . When the password is unlocked, the unlocking module 323 generates an unlocking command and an unlocking password, and the control module 321 receives the unlocking command and the unlocking password and controls the processing module 120 to turn on the electronic password lock 11. It should be noted that the unlocking module 323 generates an unlocking command and an unlocking password, and refers to generating digital information corresponding to the unlocking command and the unlocking password.

Specifically, the specific principle of the user turning on the electronic code lock 11 is as follows: the user first clicks on the identifier of the unlocking module 323 on the touch liquid crystal panel 35. After the unlocking module 323 is clicked, the unlocking module 323 generates an unlocking command, and the control module 321 receives After the unlocking command, the control unlocking module 323 is further displayed on the touch liquid crystal panel 35 in the form of an input interface, and the control module 321 sends the unlocking command to the processing module 120, and the user inputs the unlocking password on the input interface through the touch liquid crystal panel 35. The unlocking module 323 further generates an unlocking password, and the control module 321 receives the unlocking password and sends the unlocking password to the processing module 120. The processing module 120 determines whether the received unlocking password is the same as the unlocking password stored in the storage module 121. When the same is the case, the processing module 120 turns on the electronic code lock 11.

The controller 32 further includes a weight information acquiring module 324 connected to the control module 321 . The weight information of the bag body 1 sensed by the weight sensor 15 stores the weight information in the storage module 121 through the processing module 120, and the weight information acquiring module 324 identifies The form of the symbol is displayed on the touch panel 35. When the user inputs the command to obtain the weight information through the touch panel 35, the weight information acquiring module 324 is configured to generate a weight information acquisition instruction, and the control module 321 receives the weight information acquisition instruction. The post-control processing module 120 operates, and the processing module 120 stores the weight stored in the storage module 121. The information is fed back to the control module 321 , and the control module 321 displays the feedback back weight information in the touch liquid crystal panel 35 . The weight information acquisition module 324 is configured to generate a weight information acquisition instruction, which is to generate digital information corresponding to the weight information acquisition instruction. It can be understood that when the processing module 120 stores the weight information in the storage module 121, the weight information stored in the storage module 121 is overwritten.

The specific principle of the user obtaining the weight information of the bag body 1 is as follows: the user first clicks on the identifier of the weight information acquiring module 324 on the touch screen 35, and after the weight information acquiring module 324 is clicked, the weight information acquiring module 324 generates the weight information. After the control module 321 receives the weight information acquisition command, the control weight information acquisition module 324 further displays on the touch liquid crystal panel 35 in the form of a weight information display interface, and the control module 321 controls the weight of the processing module 120 in the storage module 121. After the information is fed back, the control module 321 displays the weight information in the touch liquid crystal panel 35.

In the embodiment, the radio frequency signal transmitter 21 and the alarm 22 are both connected to the microprocessor 12, and the mobile control terminal 3 is further provided with a radio frequency signal feedback device 36. The radio frequency signal transmitter 21 is used. The microprocessor 12 stores the set anti-drop distance and is used to transmit the electromagnetic wave signal and receive the feedback signal of the RF signal feedback device 36 and calculate the actual distance between the RF signal transmitter 21 and the RF signal feedback device 36 according to the feedback signal. When it is judged that the actual distance is greater than the set anti-lost distance, the alarm device 22 is turned on to remind the user that the luggage main body 1 has exceeded the set anti-lost distance. Specifically, the storage module 121 of the microprocessor 12 stores the set anti-lost distance, and the processing module 120 is configured to receive the actual distance and determine whether the actual distance is greater than the set anti-lost distance, and the processing module 120 determines that the actual distance is greater than When the set anti-lost distance is set, the alarm 22 is turned on.

In the embodiment, the controller 32 further includes a distance setting module 325 connected to the control module 321 , and the operation information input by the user through the touch liquid crystal panel 35 further includes an anti-lost distance setting command and a set anti-lost distance. When the user inputs the anti-lost distance setting command and the set anti-lost through the touch LCD panel 35 When the distance is set, the distance setting module 325 is configured to generate an anti-lost distance setting command and the set anti-lost distance, and the control module 321 receives the anti-lost distance setting command and the set anti-lost distance and the control processing module 120 sets the distance. The anti-lost distance is stored in the storage module 121. It should be noted that the distance setting module 325 generates the anti-lost distance setting command and the set anti-lost distance, and refers to the digital information corresponding to the anti-lost distance setting command and the set anti-lost distance.

Specifically, the specific principle of the user setting the anti-lost distance is as follows: the user first clicks the identifier of the representative distance setting module 325 on the touch screen 35, and generates an anti-lost distance setting command after the distance setting module 325 is clicked. After the control module 321 receives the anti-lost distance setting command, the control distance setting module 325 further displays on the touch liquid crystal panel 35 in the form of an input interface, and the control module 321 sends the anti-lost distance setting command to the processing module 120. The user inputs the set anti-lost distance on the input interface through the touch screen 35, the distance setting module 325 generates the set anti-lost distance, and the control module 321 receives the set anti-lost distance and sets the anti-lost distance. The processing module 120 sends the set anti-drop distance to the storage module 121. It can be understood that the processing module 120 will overwrite the previously stored set anti-lost distance.

Further, in the embodiment, the luggage body 1 is further provided with a GPS locator 16 connected to the microprocessor 12. When the microprocessor 12 determines that the actual distance is greater than the anti-lost distance, the microprocessor 12 turns on the GPS positioning. And acquiring the position information of the bag body 1 through the GPS locator 16 and transmitting the acquired position information of the bag body 1 to the controller 32, and the controller 32 indicates the position of the bag body 1 on the touch liquid crystal panel 35. Out so that the user can accurately know the location of the bag. Specifically, the GPS locator 16 is connected to the processing module 120. The processing module 120 first stores the location information acquired by the GPS locator 16 in the storage module 121. The controller 32 further includes a location information acquiring module 326 connected to the control module 321 . The location information obtaining module 326 is shown on the touch liquid crystal panel 35. The operation information input by the user through the touch panel 35 further includes a location information acquisition instruction, and the location information is obtained. The module 326 is configured to generate a location information acquisition command. After the control module 321 receives the location information acquisition command, the control processing module 120 feeds back the location information in the storage module 121 to the touch liquid crystal panel 35 for display. It should be noted that the location information acquisition module 326 is configured to generate a location information acquisition instruction, which is the digital information corresponding to the location information acquisition instruction. The processing module 120 stores the location information in the storage module 121 when the location information is stored in the storage module 121. The location information stored first is overwritten.

The principle of the user obtaining the location information of the main body 1 of the luggage is as follows:

After the user finds that the main body 1 of the luggage bag is lost, the user first clicks the identifier of the location information acquiring module 326 on the touch panel 35, generates a location information obtaining instruction after the location information acquiring module 326 is clicked, and the control module 321 receives the location information. After the command, the control signal is output to the processing module 120, and the processing module 120 transmits the location information stored in the storage module 121 to the control module 321, and then the control module 321 displays the location information transmitted by the processing module 120 on the touch liquid crystal panel 35. .

Specifically, in the embodiment, the main body 1 of the bag is further provided with a power module 26 for setting the main body of the bag for the microprocessor 12, the radio frequency signal transmitter 21, the GPS locator 16, and the wireless communication module. 1 is powered by the electrical device, wherein an electronic switch is connected between the power module 26 and the GPS locator 16, and the control end of the electronic switch is connected to the microprocessor 12, and the microprocessor 12 determines that the actual distance is greater than the anti-lost distance. Closing the electronic switch causes the GPS locator 16 to determine the position information of the luggage body 1 and transmit the position information of the luggage body 1 to the microprocessor 12 for energy saving purposes. Of course, in other embodiments, the GPS locator 16 can continuously obtain the location information of the luggage body 1, that is, the location information of the luggage body 1 is sent to the mobile control terminal 3 in real time, and the user can operate when searching for the location of the luggage body 1. The position information acquisition module 326 in the controller 32 acquires the position information of the luggage body 1.

It should be noted that, in the above embodiment, the first Bluetooth communication module 13 and the first remote wireless communication module 14 are all connected to the processing module 120, and the second Bluetooth communication module 33 and the second remote wireless communication The letter modules 34 are all connected to the control module 321 . The control module 321 and the processing module 120 transmit data through Bluetooth when the first Bluetooth communication module 13 and the second Bluetooth communication module 33 are normally connected; the control module 321 and the processing module 120 are in the first Bluetooth communication module 13 and the second Bluetooth communication module. 33 When it is unable to connect, data transmission is performed through two remote wireless communication modules.

Referring to FIG. 5, the RF signal transmitter 21 includes a first signal transceiver module 210 and a distance calculation module 212 connected to the signal receiving module 210. The first signal transceiver module 210 is configured to send electromagnetic waves to the RF signal feedback device 36. The signal and the feedback signal sent by the RF signal feedback device 36 are used; the distance calculation module 212 is configured to calculate the actual distance between the RF signal transmitter 21 and the RF signal feedback device 36 according to the feedback signal and send the actual distance to the microprocessor 12. The calculation module 212 calculates the actual distance. The specific principle is that the RF signal transmitter 21 sends an electromagnetic wave signal to the RF signal feedback device 36. After receiving the electromagnetic wave signal, the RF signal feedback device 36 transmits a feedback signal to the RF signal transmitter 21, and the calculation module 212 is The actual distance is calculated by the time difference between the electromagnetic wave signal transmitter 21 and the received feedback signal.

Referring to FIG. 6, in the embodiment, the RF signal feedback device 36 includes a second signal transceiver module 361 and a feedback signal generation module 362 connected to the second signal transceiver module 361. The second signal transceiver module 361 is configured to receive The electromagnetic wave signal sent by the RF signal transmitter 21 and the feedback signal are sent to the RF signal transmitter 21; the feedback signal generating module 362 is configured to generate a feedback signal and transmit the feedback information to the second signal transceiver module 361.

In this embodiment, the first Bluetooth communication module 13 and the second Bluetooth communication module 33 both adopt a 4.0 Bluetooth unit to ensure that signals can be transmitted between the two Bluetooth communication modules in a low-power Bluetooth penetration manner.

In this embodiment, the first remote wireless communication module 14 and the second remote wireless communication module 34 are one of a wifi wireless communication module, a zigbee communication module, and a GPRS communication module, so as to facilitate moving. The mobile control terminal 3 is capable of remotely controlling the luggage main body 1.

In the present embodiment, the top end and the bottom end of the main body 1 of the luggage body 1 are respectively provided with a tie rod 17 and a roller 18 to facilitate the user to pull the main body 1 of the luggage.

In the present embodiment, the alarm 22 is a buzzer alarm, and the alarm 22 can beep to raise the owner of the package when the alarm is issued.

In the embodiment, the main body 1 of the bag is further provided with an electronic switch 23, an LED strip 24 and an air quality monitoring module 25. The input end, the control end and the output end of the electronic switch 23 are respectively connected to the power module 26 and the microprocessor 12. And LED lights with 24 connections. The air quality monitoring module 25 is configured to collect current air quality information and transmit the collected current air quality information to the processing module 120 of the microprocessor 12. The storage module 121 of the microprocessor 12 stores a healthy air index, and the microprocessor When receiving the current air quality information collected by the air quality monitoring module 25, the processing module 120 of 12 determines whether the current air quality information reaches the healthy air index, and outputs a control signal when the current air quality information does not reach the healthy air index. The control electronic switch 23 is turned on to cause the LED strip 24 to emit light. The LED strip 24 is disposed, for example, outside the bag body 1 and disposed around the bag body 1.

In the present embodiment, the air quality monitoring module 25 includes, for example, a PM2.5 sensor, a smoke sensor, a carbon monoxide sensor, a carbon dioxide sensor, a formaldehyde sensor, and the like.

In this embodiment, the electronic switch 23 is a triode, and the input end, the output end and the control end of the electronic switch 23 respectively correspond to the collector, the emitter and the base of the triode, and the triode is set to be turned on at a high level.

The mobile control terminal 3 also includes a sound collector 37, each of which is coupled to the controller 32. The user inputs a voice collection command to the controller 32 through the touch screen 35, and the controller 32 turns on the sound collector 37 after receiving the voice collection instruction. The sound collector 37 is configured to collect the sound signal of the user and transmit the sound signal to the control module 321 of the controller 32, and the control module 321 of the controller 32. The sound signal is sent to the processing module 120 of the microprocessor 12, which controls the processing module 120 of the microprocessor 12 to perform the corresponding actions.

Specifically, the controller 32 further includes a voice input module 327 connected to the control module 321 . The voice input module 327 is shown on the touch liquid crystal screen 35 in the form of an identifier such as a voice input button, and the user presses the voice input module. The voice input button inputs the voice collection command to the control module 321 . At this time, the control module 321 turns on the sound collector 37. The sound collector 37 collects the voice signal of the user and sends the sound signal to the control module 321 , and the control module 321 sends the voice information to the micro The processing module 120 of the processor 12, the storage module 121 of the microprocessor 12 stores a sound signal model, the sound signal model including, for example, a model representing a "display air quality" command, which the processing module 120 of the microprocessor 12 will receive. The sound signal is compared to the sound signal model. When the processing module 120 of the microprocessor 12 determines that the received sound signal matches the model representing the "display air quality" command, the processing module 120 of the microprocessor 12 will receive The air quality information is transmitted to the controller 32, and the control module 321 of the controller 32 displays the air quality On the touch screen 35, so that people can accurately understand the specific conditions of the current environment.

A voice broadcaster 28 is further disposed on the main body 1 of the luggage. The voice broadcaster 28 is connected to the microprocessor 12. The processing module 120 of the microprocessor 12 transmits the received current air quality information to the voice broadcaster 28, and the voice broadcaster 28 The current air quality information received by the processing module 120 of the microprocessor 12 is broadcast. In particular, the sound signal model, for example, also includes a model representative of the "cast air quality" command, when the processing module 120 of the microprocessor 12 determines that the received sound signal matches the model representing the "cast air quality" command, The processing module 120 of the processor 12 transmits the received air quality information to the voice broadcaster 28, which broadcasts the current air quality information received by the processing module 120 of the microprocessor 12 so that people can accurately understand the current environment. Air specifics. It should be noted that the working principle of the voice broadcaster 28 is prior art, and details are not described herein again.

The principle of the multifunctional smart luggage of the present invention for detecting the air quality of the surrounding environment is as follows:

The air quality monitoring module 25 intermittently collects air quality information in the surrounding environment, and the air quality monitoring module 25 can collect PM2.5 information, smoke information, carbon monoxide information, carbon dioxide information, and formaldehyde information in the ambient air according to the type of the contained sensor. The PM2.5 information, the smoke information, the carbon monoxide information, the carbon dioxide information and the formaldehyde information in the collected air are transmitted to the microprocessor 12 through the A/D conversion corresponding digital information, and the microprocessor 12 determines the air quality monitoring module. 25 Whether the current air quality information collected is consistent with the healthy air index, and when any air quality information in the current air quality information does not reach the healthy air index, the microprocessor 12 determines that the current air quality information does not meet the healthy air index. At this time, the microprocessor 12 outputs a control signal (high level signal) to the electronic switch 23, so that the electronic switch 23 is turned on, at which time the LED strip 24 is electrically illuminated to remind people that the current air quality does not reach the healthy air index.

Further, one can also control the microprocessor 12 to perform corresponding actions through the mobile control terminal 3. For example, when the LED strip 24 emits light, people only know that the current ambient air is not up to standard, but the current situation of the ambient air is not It is understood that at this time, one can operate the voice input button shown on the touch panel 35 to open the sound collector 37, so that the sound collector 37 collects the voice of the operator, for example, the operator sends the current air quality information to the touch liquid crystal. At the command of the screen 35, the sound collector 37 collects the sound information and transmits it to the controller 32 through A/D conversion. The controller 32 transmits the sound information to the microprocessor 12, and the microprocessor 12 will receive the sound signal. In contrast to the sound signal model, when the microprocessor 12 determines that the received sound signal matches the model representing the "display air quality" command, the microprocessor 12 transmits the received air quality information to the controller 32. The controller 32 displays the air quality on the touch screen 35 to facilitate accurate understanding of the air conditions of the current environment.

Of course, when the microprocessor 12 determines the received sound signal and represents the "broadcast air quality" When the models are matched, the microprocessor 12 transmits the received air quality information to the voice broadcaster 28, which broadcasts the current air quality information received by the microprocessor 12 so that people can accurately understand the current environment. Air specifics.

The mobile control terminal 3 has, for example, an APP software installed therein, and the APP software has a password setting function, an unlocking function, a weight information acquiring function, a distance setting function, and a position information acquiring function, so that the mobile control terminal 3 has a password setting function, an unlocking function, and The weight information acquisition function, the distance setting function, the position information acquisition function, and the voice input function, in other words, the password setting module 320 of the controller 32, the unlocking module 323, the weight information acquiring module 324, and the distance setting module 325 The location information obtaining module 326 and the voice input module 327 are formed by, for example, APP software. The password setting module 320, the unlocking module 323, the weight information acquiring module 324, the distance setting module 325, the location information acquiring module 326, and the voice input module 327 are formed. The specific identifier is displayed on the operation interface of the APP software. When the user inputs the operation information through the touch LCD 35, the user can first open the APP software, and the operation interface of the APP software is displayed on the touch LCD 35, and then The user can input various operational information by clicking on a specific identifier.

Further, referring to FIG. 1 and FIG. 7 , the multifunctional smart case of the present invention further includes a battery case, and the battery case includes a box body 41, a flip cover 42 and a slider assembly 43 that are open on one side, and the box body 41 is used for receiving the power module. The battery of 26 is mounted on the housing of the body 1 of the case. In the present embodiment, the casing 41 is mounted on the upper casing of the luggage main body 1, and the upper casing is provided, for example, with an opening, and the casing 41 is accommodated in the luggage main body 1 through the opening and fixedly mounted by a fixing member such as a screw or the like. On the upper casing. One end of the flip cover 42 is hinged to the case body 41, and the other end of the flip cover 42 is attached with the slider assembly 43, and when the flip cover 42 is rotated to cover the case body 41, the slider assembly 43 is snap-connected to the case body 41.

In the present embodiment, the slider assembly 43 includes a sliding cavity 45, a slider 46 and at least one elastic element. Wherein, the sliding cavity 45 and the flip cover 42 are detachably mounted together, for example, by screws, and the sliding buckle 46 is located on the sliding The two sides of the sliding sleeve 46 are in contact with the sliding chamber 45 to slide along the sliding chamber 45. The top end of the sliding sleeve 46 is provided with a buckle 460. The top end of the box body 41 is correspondingly provided with a card that is snap-fitted with the buckle 460. a hole (not shown), the elastic member is interposed between the bottom end of the slider 46 and the sliding cavity 45. When the flip cover 42 is rotated to cover the case 41, the restoring force of the elastic member pushes the slider 46 toward the card hole. The direction of movement causes the buckle 460 to snap into the card hole to engage with the card hole snap.

In this embodiment, the flip cover 42 has an L shape, and includes a connecting plate 420 and a cover plate 422 connected to the connecting plate 420. The cover plate 422 is used for the cover and the box body 41. The two sides of the connecting plate 420 are respectively provided with pivots ( Not shown), the casing 41 is correspondingly provided with a pivot hole (not shown), and the pivot shaft is pivotally connected with the pivot hole to hinge the flip cover 42 to the casing 41.

In this embodiment, the sliding cavity 45 is a square box open on one side, the top end of the sliding cavity 45 is provided with a first opening 450 through which the buckle 460 passes; the top end of the cover plate 422 is provided with a second opening 424. After the sliding chamber 45 is mounted on the cover 422, the first opening 450 is aligned with the second opening 424 and encloses a perforation through which the buckle 460 passes to facilitate sliding of the slider 46 along the sliding chamber 45.

Further, the cover 422 is provided with a cavity (not shown) on the side of the casing 41. The slider assembly 43 is located in the cavity to prevent the cover 422 from interfering with the slider 46 and affecting the sliding of the slider 46.

Further, in the embodiment, the cover 422 is provided with an operation port 425 extending through opposite sides of the cover plate 422. After the slider assembly 43 is mounted on the cover plate 422, the operation port 425 is opposite to the slider 46, so as to facilitate Pull the slider 46.

Further, the slider 46 faces the face of the operation port 425, for example, with an operation slot for facilitating the operation of the slider 46.

The operation principle of the battery detachable structure of the multifunctional smart luggage of the present invention is as follows:

In the security check at the airport, if the battery in the bag needs to be removed, the user can insert the finger into the operation port 425, pull the slider 46 downward, and slide the slider 46 down the sliding cavity 45. , Thereby, the buckle 460 is disengaged from the card hole, so that the flip cover 42 can be rotated, so that the battery case is opened, and then the battery in the case 41 is taken out. Finally, when the flip cover 42 is rotated, the flip cover 42 covers the case body 41, and the buckle 460 on the slide buckle 46 comes into contact with the case body 41, and the buckle 460 is pressed by the case body 41, so that the slide button 46 moves downward, and When the buckle 460 is aligned with the card hole, the elastic member provides an upward action on the slider 46, so that the slider 46 moves upward, and the buckle 460 on the slider 46 snaps into the card hole to make the slider The assembly 43 is snap-fitted to the case 41 such that the flip cover 42 is fixed to the case 41.

In the present embodiment, the buckle 460 has a wedge shape so that the casing 41 presses the buckle 460.

In the present embodiment, the elastic member is, for example, a spring.

Further, the multifunctional smart case of the present invention further includes a hub motor 27 for driving the roller 18 to rotate, and the hub motor 27 is coupled to the microprocessor 12.

The RF signal transmitter 21 also calculates a transmission path of the feedback signal based on the feedback signal of the RF signal feedback unit 36, and transmits the calculated transmission path of the feedback signal to the microprocessor 12, and the microprocessor 12 stores the set follow-up. When the distance is used to determine that the actual distance is greater than the set following distance, the microprocessor 12 turns on the hub motor 27 and controls the hub motor 27 to drive the roller 18 to rotate according to the transmission path of the received feedback signal, so that the bag body 1 faces the radio frequency signal. The direction in which the feedback device 36 is located, that is, the direction in which the owner of the luggage is moved, enables the luggage to travel by itself. It can be understood that the following distance is set, for example, in the storage module 121 of the microprocessor 12. The operation of the hub motor 27 is specifically controlled by the processing module 120 in the microprocessor 12; the calculation module 212 calculates feedback based on the received feedback signal. The transmission path of the signal, and the method by which the calculation module 22 calculates the transmission path of the feedback signal, for example, may employ a method of calculating a transmission path of the feedback signal in the missile tracking technique.

The multifunctional smart bag of the invention has the functions of remote unlocking, remote setting password, self weighing, air quality monitoring, battery detachable and automatic following function, which is convenient for people to use.

The above description of the embodiments is merely to assist in understanding the method of the present invention and its core idea. Should refer It will be apparent to those skilled in the art that the present invention may be modified and modified without departing from the spirit and scope of the invention.

The above description of the disclosed embodiments enables those skilled in the art to make or use the invention. Various modifications to these embodiments are obvious to those skilled in the art, and the general principles defined herein may be implemented in other embodiments without departing from the spirit or scope of the invention. Therefore, the present invention is not to be limited to the embodiments shown herein, but the scope of the invention is to be accorded

Claims (10)

1. A multifunctional smart luggage bag, comprising: a luggage body (1) and a mobile control terminal (3); wherein the luggage body (1) is provided with an electronic code lock (11) and a microprocessor (12) a first Bluetooth communication module (13), a first remote wireless communication module (14), a weight sensor (15), an electronic switch (23), a power module (26), an LED strip (24), and an air quality monitoring module ( 25) the electronic code lock (11), the first Bluetooth communication module (13), the first remote wireless communication module (14), and the weight sensor (15) are both associated with the microprocessor ( 12) The mobile control terminal (3) includes a controller (32), a second Bluetooth communication module (33), a second remote wireless communication module (34), and a touch LCD panel (35), the second The Bluetooth communication module (33), the second remote wireless communication module (34), and the touch liquid crystal panel (35) are all connected to the controller (32), and the second Bluetooth communication module (33) is The first Bluetooth communication module (13) is wirelessly connected one-to-one, and the first remote wireless communication module (14) and the second remote wireless communication module (34) are wirelessly connected one-to-one. The microprocessor (12) and the controller (32) implement data transmission by means of Bluetooth communication when the first Bluetooth communication module (13) is connected to the second Bluetooth communication module (33) The touch screen (35) is configured to input operation information by the user, and the operation information includes an unlock password setting command, a set unlock password, an unlock command, an unlock password, and a weight information acquisition instruction, and the controller (32) for controlling the microprocessor (12) to set an unlock password of the electronic code lock (11) according to the operation information, or controlling the microprocessor (12) to enable the electronic password The lock (11) or the weight information sensed by the weight sensor (15) is displayed on the touch liquid crystal screen (35); the input end, the control end and the output end of the electronic switch (23) are respectively The power module (26), the microprocessor (12) and the LED strip (24) are connected; the air quality monitoring module (25) is connected to the microprocessor (12) for collecting current Air quality information and transmitting the collected current air quality information to the microprocessor (12), The processor (12) stores and health index for air is determined that the current air quality information does not reach the air health index The output control signal controls the electronic switch (23) to conduct, causing the LED strip (24) to illuminate.
2. The multifunctional smart bag according to claim 1, wherein the controller (32) comprises a password setting module (320) and a control module (321) connected to the password setting module (320), The microprocessor (12) includes a processing module (120) and a storage module (121) connected to the processing module (120), and the password setting module (320) is configured to generate the unlock password setting instruction And setting the unlock password, the control module (321) receiving the unlock password setting command and the set unlock password and controlling the processing module (120) to store the set unlock password in the storage In module (121).
3. The multifunctional smart case according to claim 2, wherein the controller (32) further comprises an unlocking module (323) connected to the control module (321), the unlocking module (323) being used for Generating the unlocking command and the unlocking password, the control module (321) receiving the unlocking command and the unlocking password, and transmitting the unlocking command and the unlocking password to the processing module (120), The processing module (120) determines whether the unlock password matches the set unlock password stored in the storage module (121), and when the two match, the processing module (120) turns on the electronic password lock (11).
4. The multifunctional smart case according to claim 1, wherein the mobile control terminal (3) further comprises a sound collector (37), and the sound collector (37) is connected to the controller (32) The touch screen (35) is configured to allow a user to input a voice collection instruction to the controller (32), and the controller (32) turns on the sound collector after receiving the voice collection instruction ( 37) The sound collector (37) is configured to collect a sound signal of a user and transmit the sound signal to the controller (32), and the controller (32) transmits the sound signal to the Microprocessor (12).
5. The multifunctional smart case according to claim 1, wherein the multifunctional smart case further comprises a battery case, wherein the battery case comprises a box body (41), a flip cover (42) and a slide buckle which are open on one side. An assembly (43) for accommodating a battery in the power module and mounted on an upper casing of the luggage body (1), one end of the flip cover (42) and the casing ( 41) hinged, the other end of the flip cover (42) mounting the slider assembly (43), and the slider assembly (43) when the flip cover (42) is rotated to cover the case (41) ) is snap-fitted to the case (41).
6. The multifunctional smart case according to claim 5, wherein the slider assembly (43) comprises a sliding cavity (45), a slider (46) and at least one elastic component, wherein the sliding cavity (45) Removably mounted on the flip cover (42), the slider (46) is located in the sliding chamber (45) and slidable along the sliding chamber (45), the slider (46) The top end of the box body (41) is provided with a card hole corresponding to the opening of the buckle (460), and the elastic element is clamped on the slider (46). Between the bottom end and the sliding chamber (45), when the flip cover (42) is rotated to cover the casing (41), the restoring force of the elastic member pushes the slider (46) toward the vicinity The direction of the card hole moves.
7. The multifunctional smart case according to claim 1, wherein the cover plate (422) is provided with an operation port (425) penetrating through opposite faces of the cover plate (422), and the slider assembly (43) After being installed on the cover plate (422), the operation port (425) is opposite to the slider (46).
8. The multifunctional smart case according to claim 1, characterized in that the bottom of the bag body (1) is provided with a roller (18), and the bag body (1) is further provided with the roller (18). a rotating hub motor (27) and a radio frequency signal transmitter (21), the wheel motor and the radio frequency signal transmitter (21) are both connected to the microprocessor (12), the mobile control terminal (3) A radio frequency signal transmitter (36) is also included, the radio frequency signal transmitter (21) is wirelessly coupled to the radio frequency signal feedback device (36) and is used to calculate the radio frequency signal transmitter (21) and the radio frequency signal feedback device (36). The actual distance between the microprocessors (12) stores a set follow distance, the microprocessor (12) receives the actual distance and is used to determine whether the actual distance is greater than the following distance, And at the actual distance The microprocessor (12) turns on the hub motor (27) when it is greater than the following distance.
9. The multifunctional smart phone bag according to claim 8, wherein the radio frequency signal transmitter (21) comprises a first signal transceiving module (210) and a distance calculation connected to the first signal transceiving module (210) Module (212), wherein the first signal transceiver module (210) is configured to send an electromagnetic wave signal to the radio frequency signal feedback device (36) and receive a feedback signal of the radio frequency signal feedback device (36); a calculation module (212) for calculating an actual distance between the radio frequency signal transmitter (21) and the radio frequency signal feedback device (36) according to the feedback signal and transmitting the actual distance to the microprocessor (12).
10. The multifunctional smart phone bag according to claim 9, wherein the radio frequency signal feedback device (36) comprises a second signal transceiving module (361) and a feedback signal connected to the second signal transceiving module (361) a generating module (362), wherein the second signal transceiver module (361) is configured to receive an electromagnetic wave signal emitted by the radio frequency signal transmitter (21) and send a feedback signal to the radio frequency signal transmitter (21); The feedback signal generating module (362) is configured to generate a feedback signal.

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