Analysis of the regenerative braking process for the urban traffic conditions

SEARCH

Current issue

Online first

Archive

Editorial and Scientific Board

Current issue

Online first

Archive

About the Journal Aims and scope Publisher and Editorial Advertising policy

For Authors Paper review procedures Procedures protecting authentic authorship of papers Paper preparation manual Plagiarism check Publication ethics Reviewers APC

Editorial and Scientific Board

Contact

Reviewers

3/2019 vol. 178

Analysis of the regenerative braking process for the urban traffic conditions

Jacek KROPIWNICKI ¹

,

Mariusz FURMANEK ¹

1

Faculty of Mechanical Engineering, Gdańsk University of Technology.

Publication date: 2019-07-01

Combustion Engines 2019,178(3), 203-207

DOI: https://doi.org/10.19206/CE-2019-335

References (20) Citations (10)

KEYWORDS

regenerative braking

real traffic conditions

hybrid and electric vehicles

energy consumption

ABSTRACT

In a regular drive system, with an internal combustion engine, vehicle braking is connected with the unproductive dissipation of ki-netic and potential energy accumulated in the mass of the vehicle into the environment. This energy can constitute up to 70% of the energy used to drive a vehicle under urban conditions. Its recovery and reuse is one of the basic advantages of hybrid and electric vehi-cles. Modern traffic management systems as well as navigation systems should take into account the possibility of the energy recovery in the process of regenerative braking. For this purpose, a model of a regenerative braking process may be helpful, which on the one hand will enable to provide information on how traffic conditions will affect the amount of energy dissipated (wasted) into the atmosphere, on the other hand will help to optimize the route of vehicles with regenerative braking systems. This work contains an analysis of the pro-cess of the regenerative braking for the urban traffic conditions registered in Gdańsk. A model was also presented that allows calculat-ing the amount of energy available from the braking process depending on the proposed variables characterizing the vehicle traffic conditions.

REFERENCES (20)

1.

BIRRELL, S., et al. Analysis of three independent realworld driving studies: A data driven and expert analysis approach to determining parameters affecting fuel economy. Transportation Research Part D. 2014, 33, 74-86.

2.

CIEŚLIK, W., PIELECHA, I., SZAŁEK, A. Indexes of performance of combustion engines in hybrid vehicles during the UDC test. Combustion Engines. 2015, 160, 11-25.

3.

DAMIANI, L. et al. Improvement of powertrain efficiency through energy breakdown analysis. Applied Energy. 2014, 121, 252-263.

4.

EEA Annual European Union greenhouse gas inventory 1990–2014 and inventory report 2016. Copenhagen 2016.

5.

FIORI, C. et al. Power-based electric vehicle energy consumption model: Model development and validation. Applied Energy. 2016, 168, 257-268.

6.

Goole Maps, https://www.google.com/maps (visited: 28.04.2019).

7.

JEFFREYS, I. et al. Evaluation of eco-driving training for vehicle fuel use and emission reduction: A case study in Australia. Transportation Research Part D. 2018, 60, 85-91.

8.

KALOCIŃSKI, T., RYMANIAK, Ł., FUĆ, P. Powertrain technology transfer between F1 and the Automotive industry based on Mercedes-Benz. Combustion Engines. 2018, 172, 3-13.

9.

KROPIWNICKI, J., KNEBA, Z., ZIÓŁKOWSKI, M. Test for assessing the energy efficiency of vehicles with internal combustion engines. International Journal of Automotive Technology. 2013, 14, 479-487.

10.

KROPIWNICKI, J., KNEBA, Z. Phenomenological correction of height above ground level of vehicle derived from GPS system. 6th International Conference Mechatronic Systems and Materials. 2010, 1-7.

11.

KROPIWNICKI, J. Identification of real vehicle operating conditions with using of specific energy consumption. The Archives of Automotive Engineering. 2010, 3, 153-166.

12.

KULKARNI, A.V., SAPRE, R.R., SONCHAL, CH.P. GPSbased methodology for drive cycle determination. SAE Technical Paper 2005-01-1060, 2005.

13.

MERSKY, A.C., SAMARAS, C. Fuel economy testing of autonomous vehicles. Transportation Research Part C. 2016, 65, 31-48.

14.

PIELECHA, I., CIEŚLIK, W., FLUDER, K. Analysis of energy management strategies for hybrid electric vehicles in urban driving conditions. Combustion Engines. 2018, 173, 14-18.

15.

PIELECHA, I., CIEŚLIK, W., SZAŁEK, A. The use of electric drive in urban driving conditions using a hydrogen powered vehicle –Toyota Mirai. Combustion Engines. 2018, 172, 51-58.

16.

STĘPIEŃ, Z. A new generation of F1 race engines – hybrid power units. Combustion Engines. 2016, 167, 22-37.

17.

TRIANTAFYLLOPOULOS, G. et al. Experimental assessment of the potential to decrease diesel NOx emissions beyond minimum requirements for Euro 6 Real Drive Emissions (RDE) compliance. Science of the Total Environment. 2018, 618, 1400-1407.

18.

Yanosik, https://yanosik.pl (visited: 28.04.2019).

19.

ZAHABI, S.A.H. et al. Fuel economy of hybrid-electric versus conventional gasoline vehicles in real-world conditions: A case study of cold cities in Quebec, Canada. Transportation Research Part D. 2014, 32, 184-192.

20.

ZHANG, R., YAO, E. Electric vehicles’ energy consumption estimation with real driving condition data. Transportation Research Part D. 2015, 41, 177-187.

CITATIONS (10):

1.

Impact of the acceleration intensity of a passenger car in a road test on energy consumption
M. Graba, J. Mamala, A. Bieniek, Z. Sroka
Energy

2.

Analysis of the Total Unit Energy Consumption of a Car with a Hybrid Drive System in Real Operating Conditions
Jarosław Mamala, Michał Śmieja, Krzysztof Prażnowski
Energies

3.

Study of energy consumption of a hybrid vehicle in real-world conditions
Jarosław Mamala, Mariusz Graba, Andrzej Bieniek, Krzysztof Prażnowski, Andrzej Augustynowicz, Michał Śmieja
Eksploatacja i Niezawodnosc - Maintenance and Reliability

4.

Evaluation of energy consumption in the acceleration process of a passenger car
Jarosław Mamala, Mariusz Graba, Andrzej Bieniek, Krzysztof Prażnowski, Krystian Hennek, Szymon Kołodziej, Bartosz Mazurek, Maciej Sproch
Combustion Engines

5.

Case study of accelerated wear of brake discs made of grey cast iron characterized by increased thermal stability
Martyna Zemlik, Mateusz Dziubek, Dariusz Pyka, Łukasz Konat, Dominika Grygier
Combustion Engines

6.

Tendencies in development of energy assistance systems in an electric car
Andrzej Augustynowicz
Combustion Engines

7.

Energy consumption of a passenger car with a hybrid powertrain in real traffic conditions
Andrzej Bieniek, Mariusz Graba, Jarosław Mamala, Krzysztof Prażnowski, Krystian Hennek
Combustion Engines

8.

The Analysis of Energy Recovered during the Braking of an Electric Vehicle in Different Driving Conditions
Emilia Szumska, Rafał Jurecki
Energies

9.

Analysis of the operating parameters of electric, hybrid, and conventional vehicles on different types of roads
Adriana Skuza, Rafał Jurecki, Emilia Szumska
Open Engineering

10.

Analysis of speed limit and energy consumption in electric vehicles
Jarosław Mamala, Mariusz Graba, Jovan Mitrovic, Krzysztof Prażnowski, Patryk Stasiak
Combustion Engines

Submit your paper

Share

RELATED ARTICLE

Evaluation of the energy efficiency of electric vehicle drivetrains under urban operating conditions

Analysis of speed limit and energy consumption in electric vehicles

Composition, features, problems, and treatment related to cooling fluid – a review

Modeling the fuel consumption by a HEV vehicle – a case study

Evaluation of energy consumption in the acceleration process of a passenger car

Indexes

eISSN:	2658-1442
ISSN:	2300-9896

The scientific journal is financed under the Agreement 185/WCN/2019/1 from the funds of the Minister of Science and Higher Education

© 2006-2024 Journal hosting platform by Bentus

Scroll to top