At the same time, the number of cars is increasing, and emissions pollution has become one of the most concerned issues in the world. At present, regulations on restricting CO2 emissions have been introduced in Europe. According to regulations, from 2012 to 2015, the CO2 emissions of automobiles must be reduced from 160g/km to 120-125g/km. It is estimated that by 2020, the CO2 emissions of automobiles will not exceed 95g/km. This regulation will require automakers to consider reducing CO2 emissions in future car designs, or face high fines. Therefore, we urgently need to find solutions to reduce CO2 emissions and save energy.
Battery state detection and charge and discharge optimization
Using an electronic energy management system, battery status monitoring algorithms integrated in battery sensors enable timely monitoring of battery status. Correspondingly, the battery and sensor working strategies can be set in the control system of the main control unit, and the working range of the battery can be set. According to the current battery charging state, the battery temperature and the driving condition of the vehicle, the corresponding strategy can be used to control the generator. Charge the battery in time. In this process, the vehicle energy supply is in a completely closed-loop control state, thus ensuring the energy supply of the whole vehicle, optimizing the vehicle energy management, ensuring the minimum current required for the engine to start again, and avoiding the battery collapse. The vehicle cannot start the problem again.
Dynamic control of generator operating voltage
At the same time, the electronic energy management system can also use the controllable alternator to dynamically change the generator's operating voltage setting to optimize engine torque distribution and vehicle energy management.
Conventional generator control does not utilize excess mechanical energy and the operating voltage is not controllable. When the car needs higher torque during the acceleration operation, the traditional generator still consumes a large engine torque, and the electronic energy management system can adjust the torque demand of the generator by dynamically controlling the working voltage of the generator to optimize the car. Torque requirements during operation. When the car is in an accelerating state, the system reduces the operating voltage of the generator, thereby reducing the torque demand of the generator torque, thereby ensuring that more energy is provided to the car to accelerate. Conversely, when the car is in a decelerating state, the generator voltage can be increased so that the system can use the excess mechanical energy during deceleration to charge the battery.
In the case of normal battery charging and discharging, if the sensor detects that the battery is under-charged, the main control unit will increase the generator operating voltage accordingly, improve the charging efficiency of the generator, and perform fast charging. When the battery is in a saturated state, the generator voltage is turned down accordingly, so that the generator is idling to avoid unnecessary overcharging of the battery, thereby reducing the torque consumed. This reduces fuel consumption and keeps the state of charge within a safe level, ensuring that the battery operates in a benign range and extends battery life.
Conclusion
In summary, the electronic energy management system improves the starting performance of the vehicle to a certain extent, ensures the reliable supply of the vehicle power, improves the reliability of the electronic system, reduces fuel consumption and reduces CO2 emissions. The more you apply to the development of new cars.
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