CN207398924U - A kind of bicycle power supply management device and management system - Google Patents

Abstract

The utility model discloses a kind of bicycle power supply management device and management systems.Wherein bicycle power supply management device includes：Electric power detection module is electrically connected with the controller, and for detecting the second voltage value of main power supply module the first voltage value and stand-by power supply module, and the first voltage value and second voltage value is sent to controller；Controller, it is electrically connected with electric power detection module, be additionally operable to the first voltage value and/or second voltage value be in can supply district when, power supply instruction is sent to main power supply module or stand-by power supply module, wherein power supply priority of the power supply priority of main power supply module more than stand-by power supply module；Main power supply module and stand-by power supply module, are electrically connected respectively with controller and function module, for powering when receiving power supply instruction to function module；Function module is electrically connected with controller, and the dormancy instruction for being sent according to controller enters holding state.The utility model realizes main power supply module and the interleaved power of stand-by power supply module.

Description

Bicycle power supply management device and management system

Technical Field

The embodiment of the utility model provides a bicycle power supply technique especially relates to a bicycle power supply management device and management system is related to.

Background

With the continuous development of the sharing economy, the sharing device such as a pile-free bicycle can effectively solve the problem of short-distance travel, has the advantages of relieving traffic pressure, saving energy, protecting environment, reducing carbon emission, promoting the user to exercise the body and the like, and is being accepted by more and more users.

The existing non-pile bicycle has the functions of positioning, communication and the like, and the functions of the non-pile bicycle can normally work only by supplying power to a power supply module. However, the self-discharge rate of the existing power supply battery for the non-pile single vehicle is high, so that the situation of insufficient electric quantity is easy to occur after the non-pile single vehicle such as the non-pile single vehicle is put on the market for a period of time, and the normal use of the non-pile single vehicle is seriously influenced.

SUMMERY OF THE UTILITY MODEL

The utility model provides a bicycle power supply management device and management equipment to the realization switches power supply battery according to the battery power condition.

In a first aspect, an embodiment of the present invention provides a bicycle power supply management device, which includes a power detection module, a main power supply module, a standby power supply module, a controller, and a function module; wherein,

the electric quantity detection module is electrically connected with the controller and is used for detecting a first voltage value of the main power supply module and a second voltage value of the standby power supply module and sending the first voltage value and the second voltage value to the controller;

the controller is electrically connected with the electric quantity detection module and is used for controlling the main power supply module or the standby power supply module to supply power to the functional module when the first voltage value and/or the second voltage value are within a power supply range, wherein the power supply priority of the main power supply module is greater than that of the standby power supply module;

the main power supply module is electrically connected with the controller and the functional module and used for supplying power to the functional module according to a power supply instruction of the controller;

the standby power supply module is electrically connected with the controller and the functional module and used for supplying power to the functional module according to a power supply instruction of the controller;

the functional module is electrically connected with the controller.

Further, the controller is configured to send a sleep instruction to the functional module when it is recognized that both the first voltage value and the second voltage value are in a power supply suspension range, so that the functional module enters a standby state according to the sleep instruction.

Further, the controller is specifically configured to determine that the first voltage value is in a power supply suspension range when it is recognized that the first voltage value is less than or equal to a first threshold, determine that the first voltage value is in a power supply available range when it is recognized that the first voltage value is greater than the first threshold, and control the main power supply module to supply power to the function module;

the controller is further specifically configured to determine that the second voltage value is in a power supply suspension range when it is identified that the second voltage value is less than or equal to a second threshold, and determine that the second voltage value is in a power supply available range when it is identified that the second voltage value is greater than the second threshold, and control the standby power supply module to supply power to the functional module.

Further, the controller is specifically configured to determine that the first voltage value is smaller than the first threshold when recognizing that the first voltage value is smaller than or equal to a voltage value corresponding to 10% of the total battery capacity in the main power supply module, where the first voltage value is in a power supply suspension range;

the controller is further specifically configured to determine that the second voltage value is smaller than the second threshold when it is identified that the second voltage value is smaller than or equal to a voltage value corresponding to 10% of a total capacity of a battery in the backup power supply module, where the second voltage value is in a power supply suspension range.

Further, the controller is further configured to control the functional module to switch from the standby state to the operating state when the functional module is in the standby state and when the first voltage value of the main power supply module is identified to be in the power supply available range.

Further, the main power supply module comprises at least one rechargeable battery, and the standby power supply module comprises at least one dry battery.

In a second aspect, an embodiment of the present invention further provides a bicycle power supply management system, including a bicycle management server and a bicycle power supply management apparatus provided in any embodiment of the present invention; wherein,

the bicycle power supply management device sends first low-power information to the bicycle management server when recognizing that the first voltage value of the main power supply module is smaller than a third threshold value, and sends second low-power information to the bicycle management server when recognizing that the second voltage value of the standby power supply module is smaller than a fourth threshold value;

the bicycle management server is in communication connection with the bicycle power supply management device and is used for receiving and storing the first low-power information or the second low-power information sent by the bicycle power supply management device.

Further, the controller of the bicycle power supply management device is specifically configured to, when it is identified that the first voltage value is a voltage value corresponding to 10% -25% of the total medium battery capacity of the main power supply module, determine that the first voltage value is smaller than the third threshold, and send the first low battery information to the bicycle management server;

the controller of the bicycle power supply management device is further specifically configured to determine that the second voltage value is smaller than the fourth threshold value and send the second low power information to the bicycle management server when it is identified that the second voltage value is a voltage value corresponding to 10% -60% of the total medium battery capacity of the standby power supply module.

The utility model discloses a set up main power module and reserve power module, and detect each power module's magnitude of voltage, the controller is according to each power module's magnitude of voltage and predetermine power supply priority and confirm main power module or reserve power module and supply power to the functional module, it frequently appears the electric quantity and crosses lowly can't supply power to the functional module to have solved single power module, the unable normal use's of functional module problem that leads to, main power module and reserve power module's power supply in turn has been realized, single power module's electric quantity consumption has been slowed down, the normal life of power module and functional module has been prolonged.

Drawings

Fig. 1 is a schematic structural diagram of a bicycle power supply management device according to a first embodiment of the present invention;

fig. 2 is a schematic structural view of a non-pile bicycle provided in an embodiment of the present invention;

fig. 3 is a schematic structural diagram of a bicycle power supply management system according to a second embodiment of the present invention;

fig. 4 is a flowchart illustrating a bicycle power supply management provided in the second embodiment of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples. It is to be understood that the specific embodiments described herein are merely illustrative of the invention and are not limiting of the invention. It should be further noted that, for the convenience of description, only some of the structures related to the present invention are shown in the drawings, not all of the structures.

Example one

Fig. 1 is a schematic structural diagram of a bicycle power supply management device according to a first embodiment of the present invention, which includes a power detection module 110, a main power supply module 120, a standby power supply module 130, a controller 140, and a function module 150; wherein:

the electric quantity detection module 110 is electrically connected with the controller 140, and is configured to detect a first voltage value of the main power supply module 120 and a second voltage value of the standby power supply module 130, and send the first voltage value and the second voltage value to the controller 140;

the controller 140 is electrically connected to the power detection module 110, and configured to control the main power supply module 120 or the standby power supply module 130 to supply power to the function module 150 when the first voltage value and/or the second voltage value are within a power supply available range, where a power supply priority of the main power supply module 120 is greater than a power supply priority of the standby power supply module 130;

the main power supply module 120 is electrically connected with the controller 140 and the functional module 150, and is used for supplying power to the functional module 150 according to a power supply instruction of the controller 140;

the standby power supply module 130 is connected with the controller 140 and the functional module 150 through wires and is used for supplying power to the functional module 150 according to a power supply instruction of the controller 140;

and a function module 150 electrically connected to the controller 140.

In this embodiment, the bicycle power supply management device includes a main power supply module 120 and a standby power supply module 130, both of which have the capability of supplying power to the function module 150. The power detection module 110 may detect the power supply voltage values of the main power supply module 120 and the standby power supply module 130 at the same time, and send the detected first voltage value and the detected second voltage value to the controller 140, so that the controller 140 may determine whether the first voltage value and the second voltage value are in the power supply range at the same time.

The power detection module 110 may also preferentially detect the first voltage value of the main power supply module 120 and send the first voltage value to the controller 140, so that the controller 140 determines whether the first voltage value is in the power supply available range, and if the first voltage value is in the power supply suspension range, the power detection module 110 further detects the second voltage value of the standby power supply module 130.

In this embodiment, if the first voltage value of the main power supply module 120 is in the power supply available range and the second voltage value of the standby power supply module 130 is in the power supply suspension range, the controller 140 sends a power supply instruction to the main power supply module 120, so that the main power supply module 120 supplies power to the function module 150 when receiving the power supply instruction. If the first voltage value of the main power supply module 120 is in the power suspension range and the second voltage value of the standby power supply module 130 is in the power suppliable range, the controller 140 sends a power supply instruction to the standby battery module 130, so that the standby battery module 130 supplies power to the function module 150 when receiving the power supply instruction. If the first voltage value and the second voltage value are both in the power supply available range, based on that the power supply priority of the main power supply module 120 is greater than the power supply priority of the standby power supply module 130, the controller 140 sends a power supply instruction to the main power supply module 120, so that the main power supply module 120 supplies power to the function module 150 when receiving the power supply instruction. That is, the controller 140 is specifically configured to control the main power supply module 120 to supply power to the function module 150 when recognizing that the first voltage value is in the power supply available range; when recognizing that the first voltage value is in the power supply suspension range and the second voltage value is in the power supply available range, the controller 140 sends a power supply instruction to the standby power supply module 130, and controls the standby power supply module 130 to supply power to the function module 150.

Optionally, if the controller 140 recognizes that the first voltage value and the second voltage value are both in the power supply suspension range, which indicates that neither the main power supply module 120 nor the standby power supply module 130 has the power supply capability, the controller 140 sends a sleep instruction to the functional module 150, so that the functional module 150 enters a standby state according to the sleep instruction, where the functional module 150 entering the standby state cannot execute any instruction.

The technical scheme of this embodiment, through setting up main power module and reserve power module, and detect each power module's magnitude of voltage, the controller is according to each power module's magnitude of voltage and predetermine power supply priority and confirm main power module or reserve power module and supply power to the functional module, the problem of the unable normal use of functional module that the electric quantity frequently appears in single power module and crosses lowly and can't supply power to the functional module has been solved, the power supply in turn of main power module and reserve power module has been realized, the electric quantity consumption of single power module has been slowed down, the normal life of power module and functional module has been improved.

Optionally, the controller 140 is specifically configured to determine that the first voltage value is in the power supply suspension range when it is identified that the first voltage value is less than or equal to the first threshold; when the first voltage value is identified to be greater than the first threshold value, determining that the first voltage value is in a power supply range, and controlling the main power supply module 120 to supply power to the function module 150;

the controller 140 is further specifically configured to determine that the second voltage value is in the power supply suspension range when it is identified that the second voltage value is less than or equal to the second threshold; when it is recognized that the second voltage value is greater than the second threshold, it is determined that the second voltage value is in the power suppliable range, and the standby power module 130 is controlled to supply power to the function module 150.

In this embodiment, the first threshold corresponding to the first voltage value and the second threshold corresponding to the second voltage value may be the same or different. For example, the first threshold may be a voltage value corresponding to 10% of the total battery capacity in the main power supply module, and the second threshold may be a voltage value corresponding to 10% of the total battery capacity in the backup power supply module. That is, the power supply available range corresponding to the first voltage value may be a voltage value range corresponding to 10% -100% of the total capacity of the battery in the main power supply module, and correspondingly, the power supply suspension range corresponding to the first voltage value is a voltage value range corresponding to the battery capacity in the main power supply module being less than 10% of the total capacity of the battery; for example, the available power range corresponding to the second voltage value may be a voltage value range corresponding to 10% -100% of the total capacity of the battery in the backup power module, and correspondingly, the power suspension range corresponding to the second voltage value is a voltage value range corresponding to less than 10% of the total capacity of the battery in the backup power module. That is, the controller 140 is specifically configured to determine that the first voltage value is smaller than a first threshold value when recognizing that the first voltage value is smaller than or equal to a voltage value corresponding to 10% of the total battery capacity in the main power supply module, where the first voltage value is in the power supply suspension range; the controller is further specifically configured to determine that the second voltage value is smaller than a second threshold value when it is identified that the second voltage value is smaller than or equal to a voltage value corresponding to 10% of the total capacity of the battery in the backup power supply module, where the second voltage value is in the power supply suspension range.

Optionally, the main power module 120 includes at least one rechargeable battery. The rechargeable battery of the main power supply module can be charged by arranging the solar power supply board or the electromagnetic induction power generation equipment, and the rechargeable battery of the main power supply module can also be charged by the staff according to the reminding information sent by the server. In the embodiment, the rechargeable main power supply module is arranged, so that the power supply service life of the main power supply module is prolonged when the main power supply module is continuously charged, and the problem that the main power supply module is frequently replaced or cannot be normally used in a main power supply simulation mode is solved.

Optionally, the backup battery module 130 includes at least one dry cell battery. Among them, dry batteries have a characteristic of weak self-discharge capacity compared with rechargeable batteries, and power consumption is relatively slow in the use process.

In this embodiment, through the dry battery that self discharge ability is weak as reserve power module, can be used to solve rechargeable battery among the main power module from the discharge rate height, frequently appear the problem that the electric quantity is low excessively.

Optionally, the controller 140 is further configured to control the functional module 150 to switch from the standby state to the operating state when the functional module 150 is in the standby state and recognizes that the main power supply module 120 or the battery backup module 130 is in the power suppliable range.

Based on the chargeable characteristic of the main power supply module 120 or the standby power supply module 130, when the functional module 150 is in the standby state, the main power supply module 120 is charged through one or more forms of a solar power supply panel, an electromagnetic induction power generation device, or manual charging, so that the voltage of the main power supply module 120 is increased to a range where power can be supplied, that is, the main power supply module 120 has power supply capability, the controller 140 controls the functional module 150 to be switched from the standby state to the working state, and the functional module 150 is restarted.

Fig. 2 is a schematic structural diagram of a non-pile bicycle provided in the embodiment of the present invention, and this non-pile bicycle 200 may include bicycle power supply management device 100 and bicycle body 210, where bicycle power supply management device 100 provides power supply management for the non-pile bicycle, so as to ensure normal use of the non-pile bicycle and increase the service life of the non-pile bicycle.

For the non-stake bicycle, the functional module may include a communication unit, a GPS (Global positioning system) unit and a lock control unit, the communication unit is configured to implement information transceiving between the non-stake bicycle and the bicycle management server, the GPS unit is configured to determine positioning information of the bicycle, and the lock control unit is configured to implement opening and closing of the lock under the control of the controller.

In this embodiment, set up main power module and reserve power module in bicycle power supply management device, through when main power module electric quantity is lower, supply power to functional module through reserve power module, realized when main power module electric quantity is lower, the normal use of no stake bicycle, provide the charge time for main power module simultaneously, solved single power module frequently appear the electric quantity and cross lowly can't supply power to functional module, the unable normal use problem of functional module that leads to.

Example two

Fig. 3 is a schematic structural diagram of a bicycle power supply management system according to a second embodiment of the present invention. Specifically, the bicycle power supply management system includes a bicycle management server 310 and a bicycle power supply management device 320 provided by any embodiment of the present invention.

The controller of the bicycle power supply management device 320 is further configured to send first low power information to the bicycle management server 310 when recognizing that the first voltage value of the main power supply module is smaller than a third threshold, and send second low power information to the bicycle management server 310 when recognizing that the second voltage value of the standby power supply module is smaller than a fourth threshold;

the bicycle management server 310 is in communication connection with the bicycle power supply management device 320, and is configured to receive and store the first low power information or the second low power information sent by the bicycle power supply management device 320.

Optionally, the controller of the bicycle power supply management device 320 is specifically configured to, when it is identified that the first voltage value is a voltage value corresponding to 10% -25% of the total medium battery capacity of the main power supply module, determine that the first voltage value is smaller than the third threshold, and send the first low battery information to the bicycle management server 310;

the controller of the bicycle power supply management device 320 is further specifically configured to determine that the second voltage value is smaller than the fourth threshold value and send the second low battery information to the bicycle management server 310 when it is identified that the second voltage value is smaller than a voltage value corresponding to 10% -60% of the total medium battery capacity of the standby power supply module.

In this embodiment, the controller 140 may periodically detect the first voltage value of the main power supply module 120 and the second voltage value of the standby power supply module 130 through the power detection module 110, and if it is recognized that the first voltage value is smaller than the third threshold or the second voltage value is smaller than the fourth threshold, the controller 140 sends low power information to the bicycle management server based on the communication unit, where the low power information carries an equipment identifier and equipment location information, where the equipment identifier may include an identifier of the bicycle power supply management device and an identifier of the power supply module, for example, the identifier of the bicycle power supply management device may be a serial number of a bicycle, the identifier of the main power supply module may be 1, and the identifier of the standby power supply module may be 0. The bicycle management server receives and stores the low-power information, and counts the use condition of the non-pile bicycle according to the low-power information, so that unified management and statistical analysis of a large number of non-pile bicycles are facilitated.

Optionally, the bicycle management server generates reminding information to corresponding staff according to the equipment identification and the equipment positioning information, so that the staff can conveniently charge and manage the equipment.

The bicycle management server can be a server for processing single-line services, is only used for providing a management strategy for power supply management of the non-pile bicycle, and can also be a server for processing comprehensive services, for example, a service terminal for providing a decision for unlocking the non-pile bicycle, providing a decision for triggering events such as alarm and the like, providing a strategy for allocation of the non-pile bicycle, managing geographical position information of the non-pile bicycle, performing data management on advertisement information of the non-pile bicycle, and performing charging data management on use of a user can be provided. A bicycle management server is to be understood as a service point providing processing, databases, communication facilities. By way of example, a bicycle management server may refer to a single physical processor with associated communications and data storage and database facilities, or it may refer to an aggregation of networked or clustered processors, associated networks and storage devices, and operating on software and one or more database systems and application software supporting the services provided by the server. The bicycle management servers may vary widely in configuration or performance, but generally may include one or more central processing units and memory. The bicycle management Server also includes one or more mass storage devices, one or more power supplies, one or more wired or wireless network interfaces, one or more input/output interfaces, or one or more operating systems, such as Windows Server, MacOS X, Unix, Linux, FreeBSD, etc.

In some embodiments, the bicycle management server may include hardware, software, or embedded logic components or a combination of two or more such components for performing the appropriate functions supported or implemented by the bicycle management server.

In this embodiment, for example, referring to fig. 4, fig. 4 is a flowchart of a bicycle power supply management provided in the second embodiment of the present invention, and it should be noted that the following description is only an example of an achievable flow of the bicycle power supply management device 100, and not only has the following achievable flow.

The controller receives a first voltage value of the main power supply module and a second voltage value of the standby power supply module which are sent by the electric quantity detection module.

The main power supply module comprises at least one rechargeable battery, and the standby battery module comprises at least one dry battery.

The controller identifies whether the first voltage value is smaller than a third threshold value, and if not, a power supply instruction is sent to the main power supply module so that the main power supply module supplies power to the functional module; if the first voltage value is not within the power supply range, a power supply instruction is sent to the main power supply module, so that the main power supply module supplies power to the function module; if yes, the first voltage value is determined to be in the power supply suspension range, and the second voltage value is further identified.

The controller identifies whether the second voltage value is smaller than a second threshold value, and if not, the controller determines that the second voltage value is in a power supply range, and sends a power supply instruction to the standby power supply module so that the standby power supply module supplies power to the functional module; if yes, determining that the second voltage value is in the power supply suspension range, and sending a sleep instruction to the functional module to enable the functional module to enter a standby state.

After the functional module enters the standby state, the controller periodically identifies whether the first voltage value is in a power supply range, if so, the functional module is controlled to be switched from the standby state to the working state and is supplied with power by the main power supply module, and if not, the standby state of the functional module is maintained.

According to the technical scheme, the bicycle management server receives low-power information sent by the bicycle power supply management device in the non-pile bicycle, and power supply management information of a large number of non-pile bicycles is conveniently and uniformly stored and managed.

It should be noted that the foregoing is only a preferred embodiment of the present invention and the technical principles applied. It will be understood by those skilled in the art that the present invention is not limited to the particular embodiments illustrated herein, but is capable of various obvious modifications, rearrangements and substitutions without departing from the scope of the invention. Therefore, although the present invention has been described in greater detail with reference to the above embodiments, the present invention is not limited to the above embodiments, and may include other equivalent embodiments without departing from the scope of the present invention.

Claims (8)

1. A bicycle power supply management device is characterized by comprising an electric quantity detection module, a main power supply module, a standby power supply module, a controller and a functional module; wherein,

the electric quantity detection module is electrically connected with the controller and is used for detecting a first voltage value of the main power supply module and a second voltage value of the standby power supply module and sending the first voltage value and the second voltage value to the controller;

the controller is electrically connected with the electric quantity detection module and is used for controlling the main power supply module or the standby power supply module to supply power to the functional module when the first voltage value and/or the second voltage value are within a power supply range, wherein the power supply priority of the main power supply module is greater than that of the standby power supply module;

the main power supply module is electrically connected with the controller and the functional module and used for supplying power to the functional module according to a power supply instruction of the controller;

the standby power supply module is electrically connected with the controller and the functional module and used for supplying power to the functional module according to a power supply instruction of the controller;

the functional module is electrically connected with the controller.

2. The power supply management device for the bicycle according to claim 1, wherein the controller is configured to send a sleep command to the functional module when recognizing that the first voltage value and the second voltage value are both in a power supply suspension range, so that the functional module enters a standby state according to the sleep command.

3. The bicycle power supply management device according to claim 1, wherein the controller is specifically configured to determine that the first voltage value is in a power supply suspension range when recognizing that the first voltage value is equal to or less than a first threshold value, determine that the first voltage value is in a power supply available range when recognizing that the first voltage value is greater than the first threshold value, and control the main power supply module to supply power to the function module;

the controller is further specifically configured to determine that the second voltage value is in a power supply suspension range when it is identified that the second voltage value is less than or equal to a second threshold, and determine that the second voltage value is in a power supply available range when it is identified that the second voltage value is greater than the second threshold, and control the standby power supply module to supply power to the functional module.

4. The bicycle power supply management device according to claim 3, wherein the controller is specifically configured to determine that the first voltage value is smaller than the first threshold value when recognizing that the first voltage value is smaller than or equal to a voltage value corresponding to 10% of a total battery capacity in the main power supply module, and the first voltage value is in a power supply suspension range;

the controller is further specifically configured to determine that the second voltage value is smaller than the second threshold when it is identified that the second voltage value is smaller than or equal to a voltage value corresponding to 10% of a total capacity of a battery in the backup power supply module, where the second voltage value is in a power supply suspension range.

5. The bicycle power supply management device according to claim 2, wherein the controller is further configured to control the functional module to switch from the standby state to the operating state when the functional module is in the standby state and the first voltage value of the main power supply module is identified to be in the power supply available range.

6. A bicycle power supply management device according to any one of claims 1 to 5, wherein the primary power supply module comprises at least one rechargeable battery and the backup power supply module comprises at least one dry battery.

7. A bicycle power supply management system comprising a bicycle management server and a bicycle power supply management apparatus according to any one of claims 1 to 6; wherein,

the controller of the bicycle power supply management device is further used for sending first low-power information to the bicycle management server when recognizing that the first voltage value of the main power supply module is smaller than a third threshold value, and sending second low-power information to the bicycle management server when recognizing that the second voltage value of the standby power supply module is smaller than a fourth threshold value;

the bicycle management server is in communication connection with the bicycle power supply management device and is used for receiving and storing the first low-power information or the second low-power information sent by the bicycle power supply management device.

8. The bicycle power supply management system according to claim 7, wherein the controller of the bicycle power supply management device is specifically configured to, when recognizing that the first voltage value is a voltage value corresponding to less than 10% -25% of a total medium battery capacity of the main power supply module, determine that the first voltage value is less than the third threshold, and send the first low battery information to the bicycle management server;

the controller of the bicycle power supply management device is further specifically configured to determine that the second voltage value is smaller than the fourth threshold value and send the second low power information to the bicycle management server when it is identified that the second voltage value is a voltage value corresponding to 10% -60% of the total medium battery capacity of the standby power supply module.