- Open Access
- Total Downloads : 905
- Authors : K.Janardhan, G.Hemavathi
- Paper ID : IJERTV2IS100553
- Volume & Issue : Volume 02, Issue 10 (October 2013)
- Published (First Online): 16-10-2013
- ISSN (Online) : 2278-0181
- Publisher Name : IJERT
- License: This work is licensed under a Creative Commons Attribution 4.0 International License
Simulation of Hybrid Vehicle System Using Multi boost and Full Bridge Converter Topology
K.Janardhan 1 G.Hemavathi 2
1 Assistant Professor , Department Of EEE, Sri Venkateswara College Of Engg.& Technology , Chittoor, A.P, India
2 PG student, Department Of EEE, Sri Venkateswara College of Engg.& Technology, Chittoor, A.P, India
Abstract: This paper deals with Battery Association Methodology for hybrid vehicle system using planetary gear system is control by DC motor drive with generator set, The energy provides by two super capacitor each super capacitor module is made of 108 cells with a maximum voltage of 270V. The multi boost and multi full bridge converter topologies are studied to define the best topology for the embarked power management. A good power management strategy by using the multi boost and the multi full bridge converter topologies. The simulation results of the two converter topologies are implemented. This module is further extended with planetary gear sub system using battery association. In this model hybrid vehicle system is modulated with DC motor drive with generator set. It is connected to the main vehicle hybrid system to rotate rotor wheel without any speed assumption and jerking. It is easier to modulate at different speeds in hybrid vehicle system ,this system is more accurate than existing vehicle system and it is also applicable for renewable energy sources vehicle system, therefore the cost of the hybrid vehicle is least and most advantageous.
Keywords: Boost converter, Full Bridge converter, Power management, Multi level boost converter.
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INTRODUCTION
In the last few years the pollution problems and the increase of the cost of fossil energy (oil, gas) have become planetary problems. The car manufacturers started to react to the urban pollution problems in nineties by commercializing the electric vehicle. But the battery weight and cost problems were not solved. The batteries must provide energy and peaks power during the transient states. These conditions are severe for the batteries. To decrease these severe conditions, the super capacitors and batteries associate with a good power management present a promising solution.
Super capacitors are storage devices which enable to supply the peaks of power to hybrid vehicle during the transient states. During the steady states, batteries will provide the energy requested. This methodology enables to decrease the weight and increases the lifespan of the batteries. Hybridization using batteries and super capacitors [1] for transport applications is needed when energy and power management are requested during the transient sates and steady states. The multi boost and multi full bridge converters will be investigated because of the high power. For range problems, traction batteries used until now cannot satisfy the energy needed for future vehicles. To ensure a good power management in hybrid vehicle, the multi boost andmulti full bridge converters topologies and their control are developed. Two topologies proposed for the power management in ECCE Hybrid Vehicle are presented in Fig.1.
1(a) First solution
1(b) second solution
Figure 1. Converter topologies for ECCE Hybrid Vehicle
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DC/DC Converters Topologies and Modeling
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Multi boost and Multi full bridge converters modeling
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Figure 2a shows the multi boost converter topology. The general model for this topology [2] is given by equation (1); where (1) and (n) define respectively the duty cycle and parallel input converter number.
The voltage drops in the Ln and inductances are given by equation (2).
. Figure 2. (a): Multi boost Converter topology
. Figure 2 (b) Multi full bridge converter topology
The converter average model has a nonlinear behavior because of crosses between 1 control variable and Vbus1 parameter. The Vbus1, Vsc1, Vsc2, Vscn , Ich and Vbat variables can to disturb the control, they must be measured and used in the estimate of the control law to ensure dynamics of control [3]. The multi boost converter [4] topology control law which results from the boost converter modeling is presented by 1 duty cycle (3); where Np = max (n) is the maximum number of parallel converters.
= 1 . 1+ 2+..+ (1 +2 ++ ) (3)
1
The multi boost converter control strategy is presented in Fig.3 (a). It ensures the super capacitor modules discharge with variable current. The super capacitors reference current (Iscref) is obtained starting from the power management between batteries and hybrid vehicle DC-link. This control strategy includes the super capacitors and batteries current control loops. PWM1 signal ensures thematic boost converters control during super capacitor modules discharge. These modules being identical, the energy management between the modules and the hybrid vehicle DC-link enable to write the super capacitors current reference(4)
To simplify the super capacitors current references estimation, the multi boost converter efficiency () was fixed at 85%.
The multi full bridge converter control strategy proposed in this paper consists to establish the full bridge converters standardized voltage The control law which result from the multi full bridge converter modeling is presented by equation (5), where (m) defines the transformer turns ratio.This standardized voltage is compared with two triangular carrier waves of amplitude Vmax = 1V witha switching frequency of 20 kHz. The inverter control strategy is presented in Fig.3(b) where Q1,
Q2,Q3 and Q4 are the control signal applied to K1, K2, K3 and K4 switches. The simulations and experimental parameters are presented in table below.
3a) Multi boost control strategy
3(b) Multi full bridge control strategy
Figure 3. Multi boost and Multi full bridge converters control strategy
2.2 Full bridge converter simulation results
The maximum and minimum voltages of the super capacitor modules are respectively fixed at 270V and 135V. The hybrid vehicle requested current (Ich) is respectively fixed at 100A from 0 to 0.5s, 400A from 0.5s to 18s and 100A from 18s to20s. Battery reference current (Ibatref) is fixed at 100A independently of the hybrid vehicle power request. Super capacitor modules voltages (Vsc1, Vsc2) presented in Fig(a) are identical. The currents amplitudes (Isc1, Isc2) presented in Fig.4(b) are also identical. Control enables to maintain the battery current (Ibat) at 100A; but around 0.5s and 18s the battery current control loop has not enough time toreact The important power of the transient states is ensured by the super capacitors modules(IL) Simulation parameters are presented in TABLE 1.
Table 1: full bridge topologies simulations parameters
Symbol |
Value |
Name |
25µH |
Battery current smoothing inductance |
|
M |
3 |
Planar transformer turns ratio |
1 |
604V-432V |
DC-link voltage |
L1=L2 |
50µH |
Super capacitors currents smoothing inductance |
4(a) Full bridge converter voltage
4(b) full bridge converter output voltage
4(c) Full bridge converter pulse generator
3.1. Boost converters simulation results
The boost converters experimental test is carried out in the following conditions: During the supe capacitors discharge, the batteries current reference (Ibatref) is fixed at 13A so that, the super capacitors modules provide hybrid vehicle power request during the transient states. For these tests, the hybrid vehicle request (Ich) was fixed at 53A. The experimental and simulations results of the modules voltage are compared The (Isc1) and (Isc2) experimental currents are not identical Fig.5(a) Fig.5 (b) because the super capacitors dispersion and the power electronic circuits (boost converters) inequality. The first boost converter ensures 50% and the second ensures also 50% of the DC-link current(IL). In other words the two super capacitors modules ensure a (IL) current of 40A to hybrid vehicle as presented in and 13A only is provided by the batteries.
5(a) boost converter with Dc-machine load
5(b) Simulation result of speed (Wm), armature current (Ia),
4. Design of planetary gear system topology
In this Fig.4.1The electrical motor is a 500 Vdc, 50 kW interior Permanent Magnet Synchronous Machine (PMSM) with the associated drive . This motor has 8 pole and the magnets are buried. A flux weakening vector control is used to achieve a maximum motor speed of 6 000 rpm.The generator is a 500 Vdc, 2 pole, 30 kW PMSM with the associated drive . A vector control is used to achieve a maximum motor speed of 13000 rpm.The battery is a 6.5 Ah, 200 Vdc, 21 kW Nickel- Metal-Hydride battery. The DC/DC converter (boost type) is voltage-regulated. The DC/DC converter adapts the low voltage of the battery (200 V) to the DC bus which feeds the AC motor at a voltage of 500V.
4.1: Simulation circuit of planetary gear system
The planetary gear system is carried out for the following conditions. The (Isc1) and (Isc2) experimental currents are not identical Fig.6(a) because the super capacitors dispersion and the power electronic circuits inequality. The first planetary gear ensure 50% and the second ensures also 50% motor electromagnetic torque(Te) presented in Fig.6(a) and Fig.6(b).motor rotor speed in Fig.6(c) and generator state current, rotor speed, Electromagnetic torque in Fig.6(d).
6(a) Simulation result of motor stator current
6(b) Simulation result of motor electromagnetic torque
6(c) Simulation result of motor rotor speed
6(d) Simulation result of generator state current, rotor speed, Electro magnetic torque
CONCLUSION
This paper concentrates on Battery Association Methodology for hybrid vehicle using planetary gear system which is control by DC motor drive with generator set. The multi boost and full bridge converter topologies are implemented with super capacitors to reduce cost and good power management in hybrid vehicle system, full bridge simulation test condensations were different from that of boost converter topology, so at the time it is not easy to make a good power comparison between the two topologies. However, multi full bridge converter topology is well suitable to adapt the level of available voltage to the DC-link, for low voltage and high current applications such as super capacitors.
The full bridge converter is higher efficiency, therefore the multi boost and full bridge converter is used in traction system and it ensures good power management. This system is further extended in planetary gear system which is applicable for vehicling system it is most accurate main energy system and it is also applicable for Renewable Energy Sources vehicling system Therefore the system is least cost and more advantageous the motor and generator is combining to change the battery and as well as the vehicle system is improving any voltage system, speed fluctuations and jerking.
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