Modeling of Working Machines Synergy in the Process of the Hybrid Electric Vehicle Acceleration
Abstract
:1. Introduction
- ➢
- specification of the components assembled in the tests (experimental part);
- ➢
- creating a mathematical model of a power-split hybrid vehicle;
- ➢
- presentation of the results;
- ➢
- discussion of the results and conclusions.
2. Experimental Part
3. Model of a Power-Split Hybrid Drive System
3.1. Torque Transmission Dynamics and Vehicle Movement
- ➢
- all shaft connections are rigid so there is no slippage between the drive components (no power loss);
- ➢
- the moments of inertia of the internal combustion engine and electric machines are related to the moments of inertia of the yokes of satellites, sun wheels and crown gear;
- ➢
- the moment of inertia of the main gear pinion is not taken into account;
- ➢
- only longitudinal forces acting on the vehicle during travel are taken into account.
- (a)
- Angular velocities:
- (b)
- Mass moments of inertia and torques of the system:
- (c)
- Vehicle inertia:
- (d)
- Vehicle speed:
- (a)
- Angular velocities:
- (b)
- Mass moments of inertia and torques of the system (JE = 0, TE = 0):
3.2. High Voltage Battery Level
3.3. Energy Management Strategy
- (a)
- Internal combustion engine torque:
- (b)
- Angular velocity of internal combustion engine:
- (c)
- Torque of the MG1 electric machine:
- (d)
- Angular speed of the MG1 electric machine:
- (e)
- Torque of the MG2 electric machine:
- (f)
- Angular speed of the MG2 electric machine:
- (g)
- High voltage battery power:
- (h)
- Battery state of charge:
4. Results
5. Discussion
6. Conclusions
Author Contributions
Funding
Conflicts of Interest
Nomenclatures
Af | [m2] | frontal area of vehicle |
[kg/Ws] | specific fuel consumption | |
Cd | [-] | air drag resistance coefficient |
C1 | [m] | number of teeth of the first set satellites |
C2 | [m] | number of teeth of the second set of satellites |
fd | [-] | total gear ratio |
fr | [-] | rolling resistance coefficient |
fuels | [g] | fuel consumption |
Fp | [N] | propelling force |
F1 | [N] | internal between teeth force of the first gear |
F2 | [N] | internal between teeth force of the second gear |
g | [ms−2] | gravitational acceleration |
Ibat | [A] | battery charging/discharging current |
J | [g] | cost function |
JE | [kgm2] | mass moment of inertia of the internal combustion engine |
JG | [kgm2] | mass moment of inertia of the generator MG1 |
JR | [kgm2] | mass moment of inertia of the planetary gear ring wheel |
JM | [kgm2] | mass moment of inertia of the electric motor MG2 |
m | [kg] | total mass of vehicle |
[kg/s] | actual fuel consumption | |
[kg/s] | equivalent fuel consumption (high voltage battery flow) | |
N | [-] | number of steps |
Pbat | [W] | power of battery |
PE | [W] | internal combustion engine power |
Qmax | [Ah] | maximum battery capacity |
Qused | [Ah] | battery capacity used |
rbat | [Ω] | internal battery resistance |
rd | [m] | dynamic wheel radius |
R | [m] | number of teeth of the ring gear |
R1 | [m] | number of crown wheel teeth |
R2 | [m] | number of ring wheel teeth on the electric motor side |
s | [-] | step |
SOC | [%] | state of charge |
SOCd | [%] | desired state of charge |
S1 | [m] | number of teeth of the first sun gear |
S2 | [m] | number of teeth of the second sun gear |
t | [s] | time |
td | [-] | jump (step level) |
Tbrk | [Nm] | brake torque |
Tdes | [Nm] | desired torque |
TEdes | [Nm] | desired torque of the internal combustion engine |
TGdes | [Nm] | desired torque of the generator |
TMdes | [Nm] | desired torque of the electric motor |
Tpre | [Nm] | expected system torque |
Tresis | [Nm] | resistance torque |
TE | [Nm] | torque of the internal combustion engine |
TG | [Nm] | generator torque |
TM | [Nm] | electric engine torque |
TR | [Nm] | torque of the ring gear of the planetary gear |
Ubus | [V] | voltage in the battery circuit |
vveh | [ms−1] | vehicle speed |
VOC | [V] | open-circuit voltage of the battery |
Wu | [J/kg] | calorific value of fuel |
α | [°] | slope of elevation |
αE | [-] | penalty factor |
ωC1 | [1/s] | angular velocity of the satellite yoke C1 |
ωE | [1/s] | angular speed of the internal combustion engine, |
ωG | [1/s] | angular speed of the generator |
ωM | [1/s] | angular velocity of the electric motor |
ωR | [1/s] | angular velocity of the crown wheel R (ring) |
ωs1 | [1/s] | angular velocity of the sun wheel S1 |
ωs2 | [1/s] | angular velocity of the sun wheel S2 |
ρ | [-] | coefficient occurring between the tracking error and the equivalent fuel consumption |
ρA | [kgm−3] | air density |
ηcoulomb | [-] | Coulomb efficiency |
ηE | [-] | overall engine efficiency |
[s] | internal combustion engine operation time | |
[s] | generator operation time | |
[s] | electric motor operation time |
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(a) | |
Total mass | 1630 kg (1445 kg + 185 kg—driver and passenger) |
Dynamic wheel radius | 0.29 m |
Frontal area | 1.62 m2 |
Rolling resistance coefficient | 0.0084—tire energy class C |
Air drag coefficient | 0.25 |
Drive system type HEV | power-split hybrid |
Internal Combustion Engine Specification | |
Ignition type | spark ignition |
Capacity | 1.8 dm3 |
Number of cylinders | 4 |
Max. power | 73 kW |
Max. power rotational speed | 5200 rpm |
Max. torque | 142 Nm |
(b) | |
Max. torque rotational speed | 4000 rpm |
Mass moment of inertia | 0.18 kg m2 |
Generator (MG1) Specification | |
Type | three-phase synchronous alternating current (AC) |
Function | generator, internal combustion engine (ICE) starter |
Rated voltage | 500 V |
Maximum output power | 42 kW |
Max torque | 45 Nm |
Current at max torque | 75 A |
Max. rotational speed | 10,000 rpm |
Mass moment of inertia | 0.023 kg m2 |
Electric Motor (MG2) Specification | |
Type | three-phase synchronous AC |
Function | generator, wheel drive |
Rated voltage | 500 V |
Maximum output power | 60 kW |
Maximum torque | 207 Nm |
Current at max torque | 230 A |
Max. rotational speed | 13,000 rpm |
Mass moment of inertia | 0.012 kg m2 |
High Voltage Battery and Inverter Specification | |
Battery type | NiMH |
Nom. voltage | 201.6 V |
Capacity | 6.5 Ah |
Item | Parameter | Value |
---|---|---|
Vehicle | Mass | 1630 kg |
Engine | Start delay | 0.5 s |
Time constant | 1 s | |
Max torque | 142 Nm | |
Power output | 73 kW | |
Motor | Max torque | 207 Nm |
Power output | 60 kW | |
Battery | SOC upper bound | 0.75 |
SOC lower bound | 0.45 | |
SOC target | 0.60 |
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Prajwowski, K.; Golebiewski, W.; Lisowski, M.; Abramek, K.F.; Galdynski, D. Modeling of Working Machines Synergy in the Process of the Hybrid Electric Vehicle Acceleration. Energies 2020, 13, 5818. https://doi.org/10.3390/en13215818
Prajwowski K, Golebiewski W, Lisowski M, Abramek KF, Galdynski D. Modeling of Working Machines Synergy in the Process of the Hybrid Electric Vehicle Acceleration. Energies. 2020; 13(21):5818. https://doi.org/10.3390/en13215818
Chicago/Turabian StylePrajwowski, Konrad, Wawrzyniec Golebiewski, Maciej Lisowski, Karol F. Abramek, and Dominik Galdynski. 2020. "Modeling of Working Machines Synergy in the Process of the Hybrid Electric Vehicle Acceleration" Energies 13, no. 21: 5818. https://doi.org/10.3390/en13215818
APA StylePrajwowski, K., Golebiewski, W., Lisowski, M., Abramek, K. F., & Galdynski, D. (2020). Modeling of Working Machines Synergy in the Process of the Hybrid Electric Vehicle Acceleration. Energies, 13(21), 5818. https://doi.org/10.3390/en13215818