KR102656821B1 - Moped and power management systems and management methods - Google Patents

Abstract

The present invention discloses a moped and its power management system and management method. The moped power management system includes a motor controller, drive circuit, battery, MCU and charging power unit; The motor controller drives a motor provided on the moped; The drive circuit drives a motor controller; The battery provides power for the driving circuit and MCU, and includes vehicle batteries and mobile batteries; The MCU determines whether the vehicle-mounted battery/mobile battery supplies power to the driving circuit by sampling the voltages of the vehicle-mounted battery and the mobile battery; The charging power unit charges the vehicle-mounted battery. The present invention provides a vehicle-mounted battery, a mobile battery, and a solar panel for a moped, and since both the vehicle-mounted battery and the mobile battery can supply power, the volume and weight of the mobile battery can be reduced, and it is lighter. , In addition, the solar panel continuously charges the vehicle's on-board battery, further increasing cruising capacity.

Description

Moped and power management systems and management methods

The present invention relates to mopeds and their power management systems and management methods.

Mopeds (power-assisted bicycles) have brought about rapid development by saving energy and reducing power, and the advent of the sharing economy has made the development of mopeds even faster. However, mopeds have some inherent problems, first of all, their range is limited, and the user experience is not good under power outage situations; Second, the battery is heavy, so it is inconvenient for users to take it home and charge it, and charging it outside poses a relatively large risk (electricity safety and theft prevention).

The purpose of the present invention is to provide a moped power management system with a more competitive overall range, a moped using such a power management system, and a management method.

The technical solution for implementing the object of the present invention includes firstly providing a moped power management system, which includes a motor controller, a driving circuit, a battery, an MCU and a charging power unit;

The motor controller drives a motor provided on the moped;

The drive circuit drives a motor controller;

The battery provides power for the driving circuit and MCU, and includes vehicle batteries and mobile batteries;

The MCU determines whether the vehicle-mounted battery/mobile battery supplies power to the driving circuit by sampling the voltages of the vehicle-mounted battery and the mobile battery;

The charging power unit charges the vehicle-mounted battery, and when the amount of electricity in the vehicle-mounted battery is less than or equal to a preset threshold, the MCU controls the mobile battery to supply power to the moped.

The moped power management system also includes a two-stage step-down circuit, wherein the first step step-down circuit steps down the output voltage of the vehicle battery and the mobile battery and supplies it to the drive circuit, and the second step step-down circuit The output voltage of the first-stage step-down circuit is stepped down and supplied to the MCU.

The charging power unit includes a solar panel and a charging module.

The driving circuit consists of two relays, each of which receives signal control from the MCU, the vehicle-mounted battery/mobile battery supplies power, and controls the motor controller to drive the moped's motor.

A driving amplifier circuit is provided between the two relays of the driving circuit and the MCU.

The vehicle-mounted battery includes a solar panel and a storage battery;

the solar panels are tiled on at least one side and bottom of the basket of the moped;

The storage battery is provided at the bottom of the bottom and on one side facing the solar panel;

The solar panel is electrically connected to the storage battery, converts received solar radiation energy into electrical energy, and stores it in the storage battery.

And, in the moped including a motor, a smart lock, and a body, the moped power management system of any one of claims 1 to 6 is included, and the moped power management system configures power for the motor. and; The MCU of the moped power management system communicates with the smart lock and starts power output in response to a signal from the smart lock.

Lastly, in the moped power management method, the condition for the solar panel to charge the vehicle-mounted battery is that the solar panel has power, and the output voltage through the charging module of the solar panel is the vehicle-mounted battery output. It is higher than voltage.

The MCU periodically scans for an unlock command of the smart lock of the moped, and if the unlock command is scanned, outputs electrical energy from the moped power management system to the motor of the moped; The amount of electricity needed for the MCU to regularly scan for unlock commands for the moped's smart lock is provided by the vehicle's on-board battery.

Sets voltage protection values for vehicle on-board batteries and mobile batteries; The MCU continuously samples the vehicle-mounted battery and the mobile battery to obtain two real-time voltage values; If the vehicle-mounted battery voltage sampling value is lower than the vehicle-mounted battery protection value, turning off the relay of the driving circuit connected to the vehicle-mounted battery; If the vehicle-mounted battery voltage sampling value is not lower than the vehicle-mounted battery protection value, the mobile battery outputs at full power.

After using the above technical solution, the present invention has the following positive effects: (1) The present invention is equipped with a vehicle-mounted battery, a mobile battery and a solar panel for a moped, and both the vehicle-mounted battery and the mobile battery provide power. Since the battery can be supplied, the volume and weight of the mobile battery can be reduced and become lighter, and the solar panel continuously charges the vehicle's on-board battery, further increasing cruising ability.

(2) In the present invention, when a mobile battery and a vehicle-mounted battery coexist in a moped, power optimization management is performed, the mobile battery is used first, and the vehicle-mounted battery scans the vehicle lock to obtain an unlock command. By providing a clear division of labor, reasonable management, and greatly increased seaworthiness.

(3) The present invention sets protection values for vehicle-mounted batteries and mobile batteries, making the management method more scientific and reasonable, and also extending the service life of the battery.

In order to provide a clearer understanding of the content of the present invention, a more detailed description of the present invention will be provided with reference to the specific examples and drawings below, among which:
1 is a block diagram of the principle of the present invention.
Figure 2 is a flow block diagram of the present invention.

(Example 1)

The moped of this embodiment includes a motor, a smart lock, a body and a moped power management system, where the moped power management system configures power for the motor; The MCU of the moped power management system communicates with the smart lock and starts power output in response to a signal from the smart lock. Smart Lock uses Brutus Communications' Bluetooth lock.

Referring to Figure 1, the moped power management system of this embodiment includes a motor controller, a driving circuit, a battery, an MCU, a charging power unit and a two-stage step-down circuit. In this embodiment, the charging power unit includes a solar panel and a charging module, and can also use other charging power sources, such as wind energy, where the charging module is mainly an inverter that converts solar energy into electrical energy. am.

The motor controller drives the motor provided on the moped and uses electrical energy to convert it into kinetic energy output by the motor;

The drive circuit drives the motor controller; Specifically, the driving circuit consists of two relays, each of which receives signal control from the MCU, the vehicle-mounted battery/mobile battery supplies power, and controls the motor controller to drive the moped's motor.

Batteries provide power for the driving circuit and MCU, and include vehicle batteries and mobile batteries; The vehicle-mounted battery serves as a normal power supply battery in normal times, providing convenience for users to store electrical energy converted by solar panels at any time and output it to a motor controller when necessary. The mobile battery is a removable battery that is stored and self-charged by the user and is the main source of energy for the motor controller, which in this embodiment only provides power output. By making one setting for the two batteries, the mobile battery is used first, and the mobile battery can be fully used by default. In order to protect the life of the battery, in this embodiment, one protection value is set, such as the electric quantity. 5% is set, and if it is less than 5%, the user is notified to proceed with charging. If the moped still needs to be used, power can be temporarily supplied using the vehicle-mounted battery. Of course, this protection value can also be set lower, even to 0. In order to extend the service life of vehicle-mounted batteries (vehicle-mounted batteries are inconvenient to replace and their service life is shortened if used excessively), a protection value, for example, 80% of the electricity quantity, is set for vehicle-mounted batteries. If it is below 80%, the power output of the vehicle-mounted battery is turned off.

The MCU determines whether the vehicle-mounted battery/mobile battery supplies power for the driving circuit by sampling the voltages for the vehicle-mounted battery and the mobile battery; In this embodiment, the MCU is a Bluetooth control chip, model number 51822, matches with Bluetooth lock, and outputs electric quantity according to the unlock command;

When the amount of electricity in the vehicle-mounted battery is less than or equal to a preset threshold, for example, 10% or less, the MCU controls the mobile battery to replace the vehicle-mounted battery and supply power to the moped. It will be appreciated that the preset thresholds may use system default values, or users may also set their own according to actual needs.

In one preferred embodiment, the vehicle-mounted battery includes two solar panels and a storage battery, and the two solar panels are tiled on the front side and bottom of the moped's basket, allowing the solar panels to fully absorb the sun's rays. It will be appreciated that in order to capture more solar radiation energy, the vehicle-mounted battery can tile solar panels on all four sides and the bottom of the basket. The storage battery is provided at the bottom of the basket, that is, on the other side facing the solar panel, and forms an electrical connection with the solar panel. As a result, the solar panel can convert the received solar radiation energy into electrical energy and store it in the storage battery. In order to further prevent the solar panel from overcharging the storage battery, it will be understood that a charge/discharge control element may be further provided between the solar panel and the storage battery. Solar panels and charging modules charge the vehicle's on-board battery; The solar panel uses relatively large voltage and power input, and its rated voltage is greater than the system battery voltage. In order to protect the vehicle-mounted battery, a reverse connection prevention protection circuit is provided here, and if a reverse connection situation occurs, an alarm can be issued. The quantity of solar panels is selected according to actual demand, and the installation location can be the bottom and side of the basket, or on the car body, and of course, multiple solar panels can be installed at the same time.

The first-stage step-down circuit of the two-stage step-down circuit reduces the output voltage of the vehicle-mounted battery and mobile battery to 15V and supplies it to the driving circuit, and the second-stage step-down circuit steps down the output voltage of the first-step step-down circuit to 3.3 V and supplies it to the MCU. supplies; Both stage step-down circuits can use a linear voltage stabilization chip to achieve voltage-stabilized step-down.

In order to obtain a more stable driving signal, a driving amplifier circuit is provided between the two relays of the driving circuit and the MCU. The driving amplification circuit can be amplified using a relatively simple and highly reliable triode.

Referring to Figures 1 and 2, the moped power management method includes several points below.

1. The conditions for the solar panel to charge the vehicle-mounted battery are that the solar panel has power, and the output voltage through the charging module of the solar panel (point A in Figure 1) is the vehicle-mounted battery output voltage (Figure 1). It is higher than point B in the above).

2. Under the standby state, the MCU scans the unlock command of the smart lock of the moped once every minute; if the unlock command is scanned, it outputs the electrical energy of the moped power management system to the motor of the moped; The amount of electricity needed for the MCU to regularly scan for unlock commands from the moped's smart lock is provided by the vehicle's on-board battery. A scan time interval of 1 minute is relatively suitable. If the time is too long, the user experience will be affected, and if the time is too short, the electricity consumption will be excessive.

3. Set voltage protection values for vehicle on-board batteries and mobile batteries; The MCU continuously samples the vehicle battery and mobile battery to obtain two voltage values in real time; If the vehicle-mounted battery voltage sampling value is lower than the vehicle-mounted battery protection value, turning off the relay of the driving circuit connected to the vehicle-mounted battery; If the vehicle-mounted battery voltage sampling value is not lower than the vehicle-mounted battery protection value, the mobile battery outputs at full power.

In the above specific embodiments, further detailed description of the purpose, technical solution and beneficial effects of the present invention has been provided, but the above contents are only specific embodiments of the present invention and do not limit the present invention. Any modifications, substitutions, improvements, etc. made within the spirit and principles of the present invention will all fall within the scope of protection of the present invention.

Claims (10)

The moped power management system includes a motor controller, driving circuit, battery, MCU, charging power unit, two-stage step-down circuit, and anti-reverse connection protection circuit;
The motor controller drives a motor provided on the moped;
The drive circuit drives a motor controller;
The battery provides power for the driving circuit and MCU, and includes vehicle batteries and mobile batteries;
The MCU determines whether the vehicle-mounted battery/mobile battery supplies power to the driving circuit by sampling the voltages of the vehicle-mounted battery and the mobile battery;
The charging power unit charges the vehicle-mounted battery, and when the amount of electricity in the vehicle-mounted battery is less than or equal to a preset threshold, the MCU controls the mobile battery to supply power to the moped,
The first-stage step-down circuit of the two-step step-down circuit steps down the output voltage of the vehicle-mounted battery and the mobile battery and supplies it to the driving circuit, and the second-step step-down circuit steps down the output voltage of the first-step step-down circuit and supplies it to the MCU, The first-stage step-down circuit and the second-stage step-down circuit use a linear voltage stabilization chip to perform voltage stabilization step-down.
The MCU sets voltage protection values for the vehicle-mounted battery and the mobile battery, respectively, continuously samples the vehicle-mounted battery and the mobile battery to obtain two real-time voltage values, and voltage sampling values of the mobile battery. If the voltage is below the protection value of the mobile battery, the user is notified to charge, and if the moped must be used, power is supplied using the vehicle-mounted battery, and the voltage sampling value of the vehicle-mounted battery is determined by the vehicle-mounted battery. If the voltage sampling value of the vehicle-mounted battery is lower than the protection value of the battery, the relay of the driving circuit connected to the vehicle-mounted battery is turned off, and if the voltage sampling value of the vehicle-mounted battery is not lower than the protection value of the vehicle-mounted battery, the mobile battery outputs at full power,
The moped power management system is characterized in that the reverse connection prevention protection circuit generates an alarm when the vehicle-mounted battery is connected in reverse. delete The moped power management system of claim 1, wherein the charging power unit includes a solar panel and a charging module. The method of claim 3, wherein the driving circuit is two relays, each of the two relays is under signal control of an MCU, a vehicle-mounted battery/mobile battery supplies power, and controls a motor controller to drive the motor of the moped. A moped power management system characterized by: The moped power management system according to claim 4, wherein a driving amplifier circuit is provided between the two relays of the driving circuit and the MCU. According to paragraph 1,
The vehicle-mounted battery includes a solar panel and a storage battery;
the solar panels are tiled on at least one side and bottom of the basket of the moped;
The storage battery is provided at the bottom of the bottom and on one side facing the solar panel;
The moped power management system is characterized in that the solar panel is electrically connected to the storage battery, converts received solar radiation energy into electrical energy, and stores it in the storage battery. In the moped including a motor, a smart lock, and a body, the moped power management system of any one of claims 1, 3 to 6 is included, and the moped power management system is used for the motor. constitutes power; A moped, characterized in that the MCU of the moped power management system communicates with the smart lock and starts power output in response to a signal from the smart lock. In the moped power management method, using the moped power management system of claim 5, the condition for the solar panel to charge the vehicle-mounted battery is that the solar panel has power and the charging module of the solar panel is used. A moped power management method characterized in that the output voltage through the vehicle is higher than the output voltage of the vehicle-mounted battery. The method of claim 8, wherein the MCU periodically scans for an unlock command of the smart lock of the moped, and if the unlock command is scanned, outputs electrical energy from the moped power management system to the motor of the moped; A moped power management method, characterized in that the amount of electricity required for the MCU to regularly scan for unlock commands of the smart lock of the moped is provided by a vehicle-mounted battery. delete