Influence of Braking Strategies for Electric Trike Energy Consumption

Islameka, Metha; Kusuma, Christopher Fernaldy; Budiman, Bentang Arief

doi:10.31427/ijstt.2020.3.1.4

Cited by 6 publications

(6 citation statements)

References 17 publications

(19 reference statements)

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“…For example, one study has successfully developed a kind of regenerative braking strategy for three-wheel EVs, and gained a satisfying result to extend mileage to about 20 km/kWh compared to three different braking strategies: full mechanical braking (19.2 km/kWh), serial regenerative braking (19.3 km/kWh), and parallel regenerative braking (19.5 km/kWh). This modified braking strategy could increase the mileage by about 4.16% km/kWh higher than the full mechanical braking [19]. Enlarging the capacity of the battery pack is also a possible solution to extend the range of BEVs.…”

Section: Battery Electric Vehicles (Bevs)mentioning

confidence: 99%

A Review on Drive Train Technologies for Passenger Electric Vehicles

et al. 2021

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Transportation is the second-largest sector contributing to greenhouse gas emissions due to CO2 gas generation from the combustion of fossil fuels. Electric vehicles (EVs) are believed to be a great solution to overcome this issue. EVs can reduce CO2 emissions because the vehicles use an electric motor as a propeller instead of an internal combustion engine. Combined with sustainable energy resources, EVs may become zero-emission transportation. This paper presents an overview of the EV drive train types, including their architecture with the benefits and drawbacks of each type. The aim is to summarize the recent progress of EV technology that always continues to be updated. Furthermore, a comparative investigation on energy density and efficiency, specific energy and power, cost, and application is carried out for batteries as the main energy storage. This discussion provides an understanding of the current development of battery technology, especially the batteries used in EVs. Moreover, the electric motor efficiency, power density, fault tolerance, reliability, and cost are also presented, including the most effective electric motor to use in EVs. The challenges and opportunities of EV deployment in the future are then discussed comprehensively. The government regulation for EVs is still a major non-technical challenge, whereas the charging time and battery performance are the challenges for the technical aspect.

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Section: Battery Electric Vehicles (Bevs)mentioning

confidence: 99%

A Review on Drive Train Technologies for Passenger Electric Vehicles

et al. 2021

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“…The maximum available torque (T mmax ) is calculated using Equation 12: Figure 6. Schematic of the braking force distribution of serial and parallel configuration for a rear-wheeled vehicle [19].…”

Section: Braking Systemmentioning

confidence: 99%

“…The power which goes out of the battery can be calculated using Equation 15 [19]. The first term is for power, which is due to the voltage (U b ) and current that goes out of the battery (I b ), and the latter is the power dissipated due to the internal resistance of the battery (R b ).…”

Section: Batterymentioning

confidence: 99%

“…To calculate the battery state-of-charge, the amount of charge (Q) in the battery at each time step (t) needs to be known. Using Equations (19) and 20, the battery's state-of-charge can be calculated:…”

Section: Batterymentioning

confidence: 99%

“…For example, Hmidi et al were modeling the system and implementing the New European Driving Cycle (NEDC), which aims to minimize fuel consumption in hybrid vehicles [18]. Another study was performed by Islameka et al in which they compare the full mechanical, serial, and parallel braking strategies simulated on the WLTC Class 2 driving cycle [19]. The result indicates that the use of serial braking systems produces the greatest efficiency compared to parallel and full mechanics braking systems.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Energy Management System Design for Good Delivery Electric Trike Equipped with Different Powertrain Configurations

Reksowardojo

Arya

Budiman

et al. 2020

WEVJ

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This paper demonstrates the design of an electric trike’s energy management system for a goods delivery service via various possible component configurations. A model of the energy management system was first developed based on general engineering vehicles’ equations using Matlab software. Various component configurations, such as the usage of two battery types (lithium iron phosphate (LFP) and lithium nickel cobalt aluminum oxide (NCA)), implementation of three braking strategies (full mechanical, parallel, and series strategies), the presence of a range extender (RE), and various masses of range extenders were simulated by using the model. The driving cycle of the e-trike as input data in the simulation was obtained by driving the vehicle around Bandung City. Speed, distance, and elevation were obtained by using GPS-based software. The simulation results showed that the most efficient and effective component configuration was to use the serial regenerative braking strategy with no RE equipped. This configuration achieved an efficiency of 18.07 km/kWh. However, for a longer route, the usage of a 20-kg RE was required to prevent the state of charge drop below 30%. The NCA with serial regenerative braking and 20-kg RE had an efficiency of 17.47 km/kWh for the complete route.

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