Voltage and Frequency Regulation in Wind Farm using Novel Boost Converter and MLI

International Journal of Electronics Engineering Research. ISSN 0975-6450 Volume 9, Number 4 (2017) pp. 557-568 Research India Publications http://www.ripublication.com Voltage and Frequency Regulation in Wind Farm using Novel Boost Converter and MLI Randeep Singh 1 (M.Teсh), Shashank Shukla 2 (M.Teсh), Amar Shukla 3 (M.Teсh) School of Electronics & Eleсtriсаl Engineering Lovely Professional University Jаlаndhаr, India Abstract WECS is dependent only on flow of wind. Regarding environmental conditions wind does not have constant speed and unpredictable. The generated output power is fluctuation in nature during low wind speed. Speed of the wind turbine increases with increase in speed of the wind up to a certain range. Since generator is placed on the same shaft at which wind turbine is placed. Therefore, change in the wind speed is directly affected the output generated by the generator. So it is important to control this power fluctuation by maintaining the voltage as well as frequency constant. In this paper DC-DC boost converter is used to maintain voltage at certain point with PMSG. PMSG is used here because of its inherit property. Although the PMSG is costly than IM but the total cost involved in generated the same amount of power using PMSG is less than IM. The AC output is converted into DC using rectifier and then it is fed to the boost converter to maintain the desired value of voltage. Again this DC voltage is converted into AC voltage by the use of inverter and then fed to the grid. Keywords: Boost converter, Drive train, IM, Pitch angle control, PMSG, Wind Turbine, WECS (wind energy conversion system INTRODUСTION Now a days, world is facing the energy crisis and most of the power is generated by fossil fuel. The time will come when it will be exhausted if the use of fossil fuel will be like this. Therefore, most of the utilities are going towards the use of Renewable Energy Sources (RES). RES are wind, solar, tidal, small hydro plant, geothermal, etc. From last some decades WECS are most attracted area. Researchers are doing their best to maximize the efficiency of WECS. Since Wind is abundant in nature and it does not include the cost of fuel so it is most preferable area for researchers. WECS is green power site, it does not emit harmful gases like greenhouse gases which causes global

558 Randeep Singh, Shashank Shukla and Amar Shukla warming [1]. Wind energy sources is completely renewable sources it can be used for other purposes except to generation of electrical energy and for that no need to depend on other sources. In present era, wind and solar energy sources are attracting the attention of researchers. But they are having a common drawback which is, they are dependent on environmental conditions. Wind and solar are unable to generate the electrical energy throughout the day, they can only generate a substantial part of the day. The efficiency of wind turbine is dependent upon the turbine blades means how much kinetic energy they are extracting from wind. Extraction of kinetic energy from wind is dependent on the shape of turbine blades, either flattened or curvy. Turbine blades can be of two types which are drag type and lift type. Lift type blades are having more efficiency than drag type. Therefore, optimal design technique of blade is required to have efficient and economical use of wind energy sources. In this paper, DC-DC boost converter is used to optimize output power from wind energy system. Here, boost converter is used to boost up the voltage which is getting from rectifier after AC-DC conversion [1]. Now a days researchers are doing their best to reduce the size of component which are using in WECS and get the maximum output. This proposed technique has scope in future application in the area of WECS. Particularly, the use of large inductance in the converter makes it large in size. It has high power components like DC-DC boost converter which helps to work on high frequency application as well as reduces the size of component [2]. It has mainly two problems, the first one is, as the frequency is increases in that proportion switching losses is increases. In other hand, level of frequency increases is proportional to increase in switching losses. Because of high switching losses, switching converter efficiency decreases but controlling mechanism will be easy. Cooling requirement increases with the increase in switching losses [1]. Requirement of this high cooling system increases the overall cost as well as the size of the converter and due to theses, weight of the nacelle is also increases. Second, the use of hard switching of high power IGBT and it limits the device up to 30 KHz application [1]. In contrast, the use of soft switching increases the operating frequency up to 70 KHz application and reduces the cooling requirement as well as size of the converter. This proposed converter fined future аppliсаtion in a miсro wind turbine. Fig 1: Сonсepts of model with boost converter

Voltage and Frequency Regulation in Wind Farm using Novel Boost Converter and MLI 559 II. WIND SYSTEM STRUСTURE The concept of model with the use of DC-DC boost converter is shown in Fig 1. In this, the kinetic energy present in the wind is extracted from wind blades and due to flow of wind, wind turbine rotate and converts the kinetic energy into mechanical energy. Wind turbine and PMSG are placed at the same shaft so the rotation of wind turbine rotates the PMSG also and then PMSG convers this mechanical energy into electrical energy and this electrical energy is in the form of AC. This AC output signal is converted into DC using rectifier and then boost converter is used to match this voltage with desired voltage. Since wind speed is not constant all the time, it fluctuate with the time due to that wind turbine get damaged and AC output voltage will also fluctuate with the time [5]. Therefore, for economical operation and also to protect system, this AC voltage is converted into DC voltage and then DC-DC boost converter is used [2]. Firing angle control mechanism is used to generate trigger signal for DC-DC boost converter to work upon the voltage which is coming from the rectifier. After boosting the voltage level, output signal is sent to the inverter and inverter is used to convert this DC voltage into AC voltage with the help of PWM. PWM is used to generate signal for those IGBT s which are using in inverter. In PWM, firing signal is generated by comparing the sine wave with high frequency saw tooth wave because inverter require force commutation that s why each IGBT s need firing signal. Then this AC voltage is fed to the AC load. In wind system, the main component is pitch control mechanism. Pitch control mechanism is used to control the angle of attack by which it can change the facing that means, how wind is hitting the turbine blades. Previously pitch control mechanism was doing one by one blades but now a days it can control simultaneously all the blades at the same time. Using this, optimal output can be achieved. WIND GENERATOR SELEСTION The DC-DC boost converter is used to boost the voltage level by step up the voltage level and step down the current. In this inductor is used which play its natural role. The tendency of inductor is to resist the sudden change in the incoming current by creating and destroying the magnetic field [1]. The key principle of boost converter- (a). When the switch is closed, current flows through inductor not through the diode. Although diode is in forward bias but current always flow through the minimum resistance path. When current flows through the inductor, it stores energy by generating magnetic field. Left side of the inductor has positive polarity and right side has negative polarity. (b). When switch is opened, current flows through diode to the capacitor and load as well. At this time, inductor releases its stored energy by changing the polarity. Due to that capacitor stored voltage twice of the supply voltage. When switch is closed, capacitor supply the load.

560 Randeep Singh, Shashank Shukla and Amar Shukla VL= L (di/dt) Fig 2: Сonventionаl Boost Converter СONTROL STRATEGY The controlling of inverter means, the generation of firing pulses at certain instant of time. Here the firing pulses is obtained by comparing the fundamental sine wave with high frequency triangular wave and it is known as SPWM inverter [3]. Snubber circuit is used to protect the switch from over voltage and high initial current [7]. With the help of this SPWM inverter, the output is obtained with three level [10]. Fig 3: Comparison of Sin wave with triangular wave.

Voltage and Frequency Regulation in Wind Farm using Novel Boost Converter and MLI 561 PROPOSED WORK AND SIMULATION Fig 4: Simulink model of wind generation In this proposed work, wind turbine is designed for the use of PMSG and here base speed of the wind turbine is considered 12m/s and at this wind speed whatever power is obtained is the power at PMSG [7]. Transient conditions is introduce here by changing the speed of the wind. Output power is vary with change in speed. This is shown in table which is listed below and the length of blade is taken as 5m. Table 1: Power (KW) at different wind speed. Wind Speed POWER 10 19.32 12 33.38 15 65.21 20 154.56 22 205.73 25 301.88

562 Randeep Singh, Shashank Shukla and Amar Shukla Fig 5: Speed vs Power Fig 6: Turbine Characteristics The obtained AС power is then fed to the bridge rectifier. A three-phase power converter has six switches which are connected in а bridge manner [2]. This bridge rectifier will convert AС into DС signal. The main role of project comes after the bridge rectifier. It gets 352.8 V as input voltage and boost up at 1950 V. Now the second problem is frequency and to maintain this frequency level different control technique is used [7].

Voltage and Frequency Regulation in Wind Farm using Novel Boost Converter and MLI 563 Fig 7: Five Level Inverter RESULTS In this paper, soft switching is done in DC-DC boost converter which boosts up the input voltage from 352.8 V to 1950 V. Fig 8 is the graph of input voltage at the input terminal of the boost converter and it is also output voltage across bridge rectifier. Fig 8: Boost Input Voltage

564 Randeep Singh, Shashank Shukla and Amar Shukla Fig 9 is showing the output voltage across the boost converter, which is 1950 V. Fig 9: Boost output Voltage Five level Inverter is used to convert DC-AC conversion. SPWM technique is used here to generate the pulses of the inverter. Fig 10 and Fig 11 are showing the level of three phase voltage after the inverter and three phase current respectively. Fig10: Inverter 3-phase Voltage

Voltage and Frequency Regulation in Wind Farm using Novel Boost Converter and MLI 565 Fig 11: Inverter 3-phase Current Here Induction Motor is used as а load and асross this output is taken out. Fig 12,13,14,15 show the rotor current, stator current, rotor speed and electromagnetic torque respectively. Fig 12: Rotor Current

566 Randeep Singh, Shashank Shukla and Amar Shukla Fig13: Stator Current Fig14: Rotor Speed Fig15: Electromagnetic Torque

Voltage and Frequency Regulation in Wind Farm using Novel Boost Converter and MLI 567 CONCLUSION In this paper, Soft switching technique is used by using IGBT s, which gives less stress on switches, less losses, reduce fluctuations, improves efficiency and enhance the speed as compare to hard switching. Five level inverter is used to reduce the THD, which provides DC-AC conversion and also controls voltage and maintains frequency. Switching ON and OFF is done by the use of IGBT s and it is highly sensitive to high power application. That s why IGBT is used here as a controlling switch. Induction motor uses as a load which gives output in terms of Ir, Is,Te, Vs. REFERENСE [1]. S.Bhаgаwаth Assistant Professor, Dr.S.Edwаrd Rаjаn Professor, Сonstаnt Output under Transient Condition in Wind Turbine using Novel Boost Converter Power аnd Computing Technologies 2013 IEEE. [2]. Annаmаlаi. M, Member, IEEE, Dr. M. Vijаyа Kumar, Life Fellow, ISTE Modeling & Simulation of Variable Speed Wind Turbine with Resonant DС- DС Converters (IСPESа'2012) August 25-26, 2012 Kuаlа Lumpur. [3]. E. S. dа Silva, L. dos Reis Barbosa, J. B. Vieira, L. С. de Freitаs, and V. 1. Farias, an improved boost PWM soft-single-switched converter with low voltage and current stresses, IEEE Trans. Ind. Electron., vol. 48, no. 6, pp. 1174-1179, Dec. 2001. [4]. F. L. Tofoli, E. а. а. Coelho, L. С. de Freitаs, V. J. Farias, аnd J.B.Vieirа, Proposal of а soft-switching single-phase three-level rectifier, IEEE trans. Ind. Electron., vol. 55, no. 19, pp. 107-113, Jаn.2008. [5]. Jennifer Bauman, Mehrdаd, "A Novel Сapaсitor- Switсhed Regenerative Snubber OСIDС Boost Converters" IEEE Trаn.Ind. Electron. vol. 58, no.2, pp. 514-523, Feb. 2011. [6]. QСJ. Marshall аnd M. Kаzerаni, "а novel lossless snubber for boost converters," in Proс. IEEE Int. Symp. Ind.Eleсtron, Montreal, Саnаdа, Jul.9-13, 2006, pp.1030-1035. [7]. P. С. Sen., Principles of Eleсtriсаl Mасhines аnd Power Electronics, John Wiley аnd sons, pp no.351-358, 2nd Edition, 2008. [8]. E. S. dа Silva, L. dos Reis Barbosa, J. B. Vieirа, L. С. defreitаs,аndv.1.fаriаs,"аn improved boost PWM soft- single-switched converter with low voltage аnd current stresses," IEEE Trаns.Ind. [9]. T.F.СhаnаndL.L.Lаi, Permаnent-mаgnet mасhines for distributed generation: а review, in Proс. 2007 IEEE Power Engineering annual Meeting, pp. 1 6. [10]. A.M. Cross, P.D. Evans, аnd а. J. Forsyth, DС link current in PWM inverters with unbаlаnсed аnd non-linear loads, in Proс. Inst. Elect. Eng. Eleсtriсаl Power аppliсаtions, Nov. 1999, vol. 146, no. 6, pp. 620 626.

568 Randeep Singh, Shashank Shukla and Amar Shukla [11]. Neelаm Rаthi1, Aziz аhmed2, Rajiv Kumаr3, Сompаrаtive Study of Soft Switching аnd Hard Switching for Brushless DС Motor May 2011. IJRTEISSN:2231-6612 Volume 1, Issue 1, pg:1-5