Disclosure of Invention
The invention aims to solve the technical problems that the prior art has the defects of providing a spliced mobile power supply sharing device, and solving the problems of large occupied space, high cost, poor reliability, poor communication capability and the like of the existing shared charging bank renting system.
The invention aims to solve the technical problems that the prior art has the defects of providing a spliced mobile power supply sharing system and solving the problems of large occupied space, high cost, poor reliability, poor communication capability and the like of the existing shared charging bank renting system.
The invention aims to solve the technical problems that the spliced shared mobile power source renting method solves the problems of large occupied space, high cost, poor reliability, poor communication capability and the like of the existing shared charging bank renting system.
The invention aims to solve the technical problems that the spliced shared mobile power return method aims at the defects of the prior art, and solves the problems that the existing shared charging bank renting system is large in occupied space, high in cost, poor in reliability, poor in communication capability and the like.
The technical scheme adopted for solving the technical problems is as follows: the utility model provides a but portable power source sharing device of concatenation formula, portable power source sharing device includes main seat, charging seat and portable power source, the main seat includes first communication module and second communication module, the charging seat includes power input, power output and charges female, portable power source includes a public head and the third communication module of charging; the main seat is in communication connection with the server through the first communication module and is also in electric connection with the mains supply and a charging seat respectively, the power input end of the charging seat is in electric connection with the power output end of the main seat or other charging seats, the mobile power supply is in communication connection with the second communication module through the third communication module and is in electric connection with the charging female head of the charging seat through the charging male head, and charging is achieved.
The technical scheme adopted for solving the technical problems is as follows: the mobile power supply sharing device comprises a main seat, a charging seat and a mobile power supply, wherein the main seat comprises a first communication module and a second communication module, the charging seat comprises a power supply input end, a power supply output end, a charging female head and a first conductive part, and the mobile power supply comprises a charging male head, a second conductive part and a third communication module; the main seat is in communication connection with the server through the first communication module and is also in electric connection with the mains supply and a charging seat respectively, the power input end of the charging seat is in electric connection with the power output end of the main seat or other charging seats, the mobile power source is in communication connection with the second communication module through the third communication module and is in electric connection with the charging female head of the charging seat through the charging male head and is in electric connection with the first conductive part of the charging seat through the second conductive part, and the charging female head, the charging male head, the battery core of the mobile power source, the second conductive part and the first conductive part form a charging loop.
Among them, the preferred scheme is: the first communication module is one of 2G, 3G, 4G, WIFI, NB-iot and lora.
Among them, the preferred scheme is: the second communication module and the third communication module are both one of 2.4G, bluetooth, zigbee, ble, 433 and NFC.
Among them, the preferred scheme is: the mobile power supply further comprises an indicator lamp.
The invention solves the technical problems by adopting the following technical scheme: the utility model provides a but portable power source sharing system of concatenation formula, portable power source sharing system includes portable power source sharing device, server and mobile device, be provided with the two-dimensional code on portable power source sharing device's the master seat, charging seat or the portable power source, portable power source sharing device is connected with the server communication through portable power source sharing device's first communication module, mobile device is connected with the server communication through scanning the two-dimensional code to through server and corresponding portable power source sharing device communication connection.
The invention solves the technical problems by adopting the following technical scheme: providing a split type sharing mobile power supply renting method, wherein the sharing mobile power supply renting method is applied to the mobile power supply sharing system; the shared mobile power source renting method comprises the following steps: the mobile equipment is in communication connection with the server through scanning the two-dimension code; the mobile equipment is in communication connection with the corresponding mobile power sharing device through WeChat, payment bank or special software program, and leases the selected mobile power; the main seat of the mobile power supply sharing device communicates with the selected mobile power supply, and turns on an external discharge mode of the mobile power supply and turns on an indicator lamp of the mobile power supply to flash; and taking off the flashing mobile power supply of the indicator lamp to finish the leasing step.
The preferred scheme is that the step of the shared mobile power source renting method further comprises the following steps: before the mobile power supply is rented, the mobile power supply is communicated with the main seat, parameter information of the mobile power supply is exchanged, and the server is reported through the main seat; wherein the parameter information comprises electric quantity information and temperature information; and the main seat controls whether the mobile power supply can be charged or not according to the parameter information of the mobile power supply, if the electric quantity of the mobile power supply is lower than a first preset threshold value, the charging is preferentially carried out or the charging speed is increased, and if the temperature of the mobile power supply reaches a second preset threshold value, the charging is canceled or the charging speed is slowed down.
The preferred scheme is that the step of the shared mobile power source renting method further comprises the following steps: the master seat obtains whether the mobile power supply in the hosting range meets the rentable requirement or not, and if so, the mobile power supply is set to be rentable; wherein the rentable requirements include the amount of power reaching a rentable threshold and being undamaged.
The invention solves the technical problems by adopting the following technical scheme: providing a split type shared mobile power supply returning method, wherein the shared mobile power supply returning method is applied to the mobile power supply sharing system; the method for returning the shared mobile power supply comprises the following steps: inserting the mobile power supply into a charging seat of the mobile power supply sharing device; the electric base charges the mobile power supply and activates the communication function of the mobile power supply, and the mobile power supply sends self information to the server through the main base; and after the verification of the server is finished, notifying the main seat, closing an external discharging mode of the mobile power supply by the main seat, replying the server, ending the order by the server, and finishing the returning step.
Compared with the prior art, the invention has the beneficial effects that by means of the split type mobile power supply sharing system, the main seat is separated from the mobile power supply, and different remote wireless communication technologies can be used in different places, so that the best network communication quality is achieved, and the cost is low; the charging seats can be spliced, so that different places can be spliced with different numbers of charging seats, and the highest utilization rate of the mobile power supply and the charging seats is achieved; and the defect of complexity and instability of the contact communication mould is overcome, the reliability of communication is increased, and the remote updating of the software program in the mobile power supply is facilitated.
Detailed Description
Preferred embodiments of the present invention will now be described in detail with reference to the accompanying drawings.
As shown in fig. 1 to 3, the present invention provides a preferred embodiment of a portable power source sharing system capable of being spliced.
The utility model provides a portable power source sharing system that can splice, portable power source sharing system includes portable power source sharing device 10, server 20 and mobile device 30, be provided with the two-dimensional code on portable power source sharing device 10's the master batch 300, charging seat 200 or the portable power source 100, portable power source sharing device 10 is connected with server 20 communication through portable power source sharing device 10's first communication module, mobile device 30 is connected with server 20 communication through scanning two-dimensional code to be connected with corresponding portable power source sharing device 10 communication through server 20.
Preferably, the main seat 300 is matched with a user identification mark such as a two-dimensional code and the like, so that the mobile device 30 can conveniently pay and pay attention to the code scanning. The mobile device 30 includes a mobile phone, a tablet, and the like.
The main base 300 is separated from the mobile power supply 100, so that different remote wireless communication technologies can be used in different places, and the best network communication quality and low cost are achieved.
In the present embodiment, the mobile power sharing apparatus 10 includes two schemes.
The first scheme is that the mobile power sharing device 10 includes a main base 300, a charging base 200 and a mobile power source 100, wherein the main base 300 includes a first communication module and a second communication module, the charging base 200 includes a power input end 220, a power output end 270 and a charging female head 240, and the mobile power source 100 includes a charging male head 140 and a third communication module; the main base 300 is in communication connection with the server 20 through a first communication module, and is also electrically connected with the mains supply and a charging base 200 respectively, a power input end 220 of the charging base 200 is electrically connected with a power output end 270 of the main base 300 or other charging bases 200, the mobile power source 100 is in communication connection with a second communication module through a third communication module, and is electrically connected with a charging female head 240 of the charging base 200 through a charging male head 140, so as to realize charging.
The second scheme is that the mobile power sharing device 10 includes a main base 300, a charging base 200, and a mobile power source 100, where the main base 300 includes a first communication module and a second communication module, the charging base 200 includes a power input end 220, a power output end 270, a charging female head 240, and a first conductive portion 250, and the mobile power source 100 includes a charging male head 140, a second conductive portion 250, and a third communication module; the main base 300 is in communication connection with the server 20 through a first communication module, and is also in electric connection with the mains supply and a charging base 200 respectively, a power input end 220 of the charging base 200 is in electric connection with a power output end 270 of the main base 300 or other charging bases 200, the mobile power source 100 is in communication connection with a second communication module through a third communication module, is in electric connection with a charging female head 240 of the charging base 200 through a charging male head 140, and is in electric connection with a first conductive portion 250 of the charging base 200 through a second conductive portion 250, and the charging female head 240, the charging male head 140, a battery core 120 of the mobile power source 100, the second conductive portion 250 and the first conductive portion 250 form a charging loop.
Specifically, the power input end 220 is a power plug, and the charging stand 200 further includes a power socket head matched with the power plug, and the power plug is electrically connected with the power socket head. Specifically, the first power management unit 230 includes a circuit board 231 and an adapter 232, the circuit board 231 is respectively connected with a power plug, the adapter 232 and a power socket, and mains supply is transmitted in through the power plug and is transmitted out from the power socket through the circuit board 231, and the power plug of the latter charging stand 200 is inserted into the former power socket to form a spliced connection. Preferably, the power plug and the power socket are provided on both front and rear end surfaces of the cradle 200, and the charging socket 240 and the second conductive part 250 are provided on the upper end surface, respectively.
And, the main base 300 further includes a mains plug 310, a mains outlet 320 and a USB charging port 330, and the mains plug 310 is inserted into a conventional socket to input mains and output through the mains outlet 320, and the power input end 220 of the charging base 200 is matched with the mains outlet 320 to obtain the mains. Further, the main base 300 further includes an adapter for converting the commercial power into charging power and outputting the charging power from the USB charging port 330, such as 5V charging power.
Wherein, the commercial power plug 310 of the main seat 300 is a three-hole plug (strong electricity, 110-250V), and can be electrified by being inserted into a three-hole socket. And, the neutral and hot wires output strong electricity from the utility outlet 320 into the cradle 200.
In this embodiment, the first communication module is one of 2G, 3G, 4G, WIFI, nb-iot and lora, so as to implement global data exchange and behavior control from the server 20 to the master base 300 and then from the master base 300 to the mobile power supply 100. Of course, the above only discloses each preferred remote communication module, and other communication modules capable of implementing remote communication functions are also included in the protection scope of the present invention.
In this embodiment, the second communication module and the third communication module are both one of 2.4G, bluetooth, zigbee, and ble. Of course, the above only discloses each preferred near field communication module, and if other communication modules can realize the near field communication function, the invention also belongs to the protection scope of the invention.
In this embodiment, the portable power source 100 further includes an indicator light 180. The indicator light 180 has the functions of electric quantity state, flashing reminding during lease, whether to turn on or not, etc.
For example, a green light is turned on when the state of charge is above 80%, a yellow light is turned on when the state of charge is between 30% and 80%, and a red light is turned on when the state of charge is below 30%.
As shown in fig. 4, 5 and 6, the present invention provides a mobile power sharing device according to a preferred embodiment.
Referring to fig. 4, a mobile power supply 100 includes a mobile power supply main body 110, a battery core 120 and a second power supply management unit 130 disposed in the mobile power supply main body 110, and a charging male terminal 140 and a second conductive part 150 disposed on the mobile power supply main body 110, wherein the second power supply management unit 130 is electrically connected with the battery core 120, the charging male terminal 140 and the second conductive part 150, respectively, the second power supply management unit 130 outputs the electric energy of the battery core 120 through the charging male terminal 140, and the charging male terminal 140, the second power supply management unit 130 and the second conductive part 150 form a charging circuit.
When the mobile power supply 100 discharges, the electric energy of the battery core 120 is output through the charging plug 140 according to the control of the second power management unit 130, so as to charge the charged device, such as a mobile phone, a tablet, and the like.
Further, the second conductive portion 150 and the charging male 140 are both disposed at the same end surface, and the second conductive portion 150 includes a first groove and a second conductive sheet disposed inside the first groove. And, the portable power source 100 includes a second magnet 160, the second magnet 160 is disposed at the end surface where the charging male 140 is disposed, and the second magnet 160 may be preferably disposed at the bottom of the first recess.
Referring to fig. 5, the charging male 140 includes a conductive housing 141, pins 142 disposed on the conductive housing 141, and contact pieces 143 connected to the conductive housing 141, and the mobile power supply 100 further includes an FPC170 disposed between the charging male 140 and the second power management unit 130, the conductive wires of the FPC170 being electrically connected to the contact pieces 143. And, the second conductive part 150 is also connected to the first power management through an FPC (not shown). The charging loop is specifically: the conductive housing 141, the contact piece 143, the FPC170, the second power management unit 130, the battery cell 120, the second power management unit 130, the FPC (not shown), the second conductive part 150. The flexible printed circuit board 231 (Flexible Printed Circuit abbreviated as FPC) is a flexible printed circuit board which is made of polyimide or polyester film as a base material and has high reliability and excellent flexibility. The wiring density is high, the weight is light, the thickness is thin, the flexibility is good.
Referring to fig. 6, a charging stand 200, wherein the mobile power supply 100 of the charging stand 200 is charged, the charging stand 200 includes a charging stand main body 210, a first power management unit 230 disposed in the charging stand main body 210, a power input end 220 disposed on the charging stand main body 210, at least one charging female head 240 matching with the charging male head 140 of the mobile power supply 100, and a second conductive portion 250 matching with the second conductive portion 150 of the mobile power supply 100; the first power management unit 230 is electrically connected to the power input terminal 220, the charging female terminal 240 and the second conductive portion 250, and converts the commercial power input by the power input terminal 220 into charging electric energy output from the charging female terminal 240 or the second conductive portion 250, the charging female terminal 240 is electrically connected to the charging male terminal 140 inserted therein, the second conductive portion 250 is electrically connected to the second conductive portion 150, and the charging female terminal 240, the charging male terminal 140, the battery core 120 of the mobile power supply 100, the second conductive portion 150, the second conductive portion 250 and the first power management unit 230 form a charging circuit. Wherein the first power management unit 230 includes a circuit board 231 and an adapter 232 disposed on the circuit board 231, the circuit board 231 is electrically connected with the adapter 232 and the power input terminal 220, respectively, and the adapter 232 is also electrically connected with the charging female 240 and the second conductive part 250, respectively.
In this embodiment, a plurality of charging areas are disposed on the end surface of the charging stand 200, and each charging area is provided with a charging female head 240 and a corresponding second conductive portion 250; the charging female 240 includes a second groove and a charging female 240 conductive sheet disposed inside the second groove, and the charging female 240 conductive sheet is electrically connected with the first power management unit 230. Preferably, each of the charging areas is provided with a charging female 240 and second conductive parts 250 disposed at both sides of the charging female 240. Further, the second conductive part 250 includes a boss that mates with the first recess of the mobile power supply 100, and a first conductive sheet disposed at the boss. The first conductive sheet is disposed on the surface of the boss, when the mobile power supply 100 charges, the charging male head 140 is aligned with the first groove and inserted, the charging male head 140 is inserted into the charging female head 240, the first groove is sleeved into the boss, and meanwhile, the second conductive sheet of the first groove is electrically connected with the first conductive sheet of the boss. And, a third conductive sheet is disposed in the charging female head 240, and the conductive housing 141 of the charging male head 140 is connected to the third conductive sheet of the charging female head 240.
In this embodiment, the charging areas are each provided with a first magnet 260 that cooperates with the second magnet 160 of the mobile power supply 100. Preferably, the first magnet 260 may be disposed at the top of the inner side of the boss, and stably attached by the magnetic attraction of the first magnet 260 and the second magnet 160 after the boss is inserted into the first groove.
As shown in fig. 7, the present invention provides a preferred embodiment of a split type shared mobile power source leasing method.
The spliced sharing mobile power supply renting method is applied to the mobile power supply sharing system; the shared mobile power source renting method comprises the following steps:
Step S11, the mobile device 30 is in communication connection with the server 20 by scanning the two-dimensional code;
Step S12, the mobile device 30 is communicatively connected with the corresponding mobile power sharing device 10 through a WeChat, a payment device or a dedicated software program, and leases the selected mobile power 100;
step S13, the main base 300 of the mobile power sharing device 10 communicates with the selected mobile power 100, and turns on the external discharge mode of the mobile power 100, and turns on the indicator light of the mobile power 100 to flash;
step S14, the portable power source 100 flashing the indicator light is taken away, and the leasing step is completed.
In step S12, the mobile device 30 is communicatively connected to the corresponding mobile power sharing device 10 through a WeChat, a payment device or a dedicated software program, so as to verify user information, pay deposit, etc., and check whether there is a borrowable mobile power supply 100 within the hosting range (the electric quantity reaches a threshold value, is not damaged, and the charging head is a user' S choice, etc.). Specifically, the step of the shared mobile power source leasing method further includes: the master 300 obtains whether the mobile power supply 100 in the hosting range meets the rentable requirement, and if so, the mobile power supply 100 is set to be rentable; wherein the rentable requirements include the amount of power reaching a rentable threshold and being undamaged.
And, the mobile device 30 selects the type of the mobile power supply 100 through a letter, a payment instrument, or a dedicated software program, clicks lease.
In this embodiment, the step of the shared mobile power source leasing method further includes: before the mobile power supply 100 is rented, the mobile power supply 100 is communicated with the master base 300, and parameter information of the mobile power supply 100 is exchanged and reported to the server 20 through the master base 300; wherein the parameter information comprises electric quantity information and temperature information; and, the master base 300 controls whether the mobile power supply 100 can be charged according to the parameter information of the mobile power supply 100, if the electric quantity of the mobile power supply 100 is lower than the first preset threshold, the charging is preferentially performed or the charging speed is increased, and if the temperature of the mobile power supply 100 reaches the second preset threshold, the charging is canceled or the charging speed is slowed down.
Wherein, thereby coordinating the charging speed of the mobile power supply 100, and achieving the maximum utilization efficiency of the mobile power supply 100. And a switch for discharging the mobile power supply 100 is utilized to realize that the mobile power supply 100 which is not leased can not be used by being directly taken out, thereby eliminating criminal motivation for stealing the mobile power supply 100 and avoiding the loss of the mobile power supply 100.
As shown in fig. 8, the present invention provides a preferred embodiment of a method for returning a split type shared mobile power source.
The method for returning the shared mobile power supply capable of being spliced is applied to the mobile power supply sharing system; the method for returning the shared mobile power supply comprises the following steps:
Step S21, inserting the mobile power supply 100 into the charging stand 200 of the mobile power supply sharing device 10;
Step S22, the electric base charges the mobile power supply 100 and activates the communication function of the mobile power supply 100, and the mobile power supply 100 sends the information to the server 20 through the main base 300;
In step S23, and after the verification, the server 20 notifies the master base 300, the master base 300 turns off the external discharging mode of the mobile power supply 100, replies to the server, and the server ends the order, thereby completing the return step.
In the present invention, the main base 300 communicates with the mobile power supply 100 through the short-range wireless communication technology, which has the following advantages:
1. the near field wireless communication technology enables the arbitrary splicing of the mobile power supply 100 base to be possible, and the mobile power supply 100 base does not need a communication module; the charging base is simple in structure and low in cost;
2. The defect of complexity and instability of a contact type communication mould is overcome, and the reliability of communication is improved;
3. And facilitate remote updating of software programs within the mobile power supply 100;
4. The wireless communication capability of the mobile power supply 100 makes the mobile power supply 100 show huge commercial value in inventory management and daily maintenance (such as inventory count without unpacking, where the mobile power supply 100 is located and can be communicated with the main seat 300 by recording circulation paths, etc.);
5. To some extent, the mobile power supply 100 may be separated from the main stand 300; that is, the user can take up the portable power source 100 (at a short distance from the main seat 300) and can perform the lease as well.
The foregoing description of the preferred embodiments of the present invention is not intended to limit the scope of the invention, but rather is intended to cover all modifications and variations within the scope of the present invention as defined in the appended claims.