An isolated topology for reactive power compensation with a modularized Dynamic-Current building-block This paper presents a novel topology for instantaneous reactive power compensation. The topology is derived from Dynamic-Current or Dyna-C, which is a patented power converter capable of transferring energy for two- or multi-terminal DC, single- and/or multi-phase AC systems. The proposed topology has a modularized low-voltage current source building block that can be stacked for medium-voltage (MV) applications to provide dynamic leading or lagging reactive power. In addition, the phases are coupled through a high-frequency transformer for inter-phase fault isolation among the three-phase. The converter functionality is validated through simulations and experimental results with a 480 V, 75 kVAr prototype. Web : http://www.lemenizinfotech.com Web : http://ieeemaster.com Web : http://www.lemenizinfotech.com/power-system-ieee-projects-2016-2017/ Web : http://ieeemaster.com/power-system-ieee-projects-2016-2017/ Address: 36, 100 Feet Road(Near Indira Gandhi Statue), Natesan Nagar, Pondicherry-605 005 Contact numbers: +91 95663 55386, 99625 88976 (0413) 420 5444 Mail : projects@lemenizinfotech.com Mobile : 9566355386 / 9962588976

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An Isolated Topology for Reactive Power
Compensation with a Modularized
Dynamic-Current Building-Block
Introduction:
Proliferation of non-resistive loads imposes power quality
concerns over the existing grid network. The reactive power loads,
which possess a low power factor, draw high amount of volt-ampere
reactive power from the grid and thus restrict the active power
transfer capability. The excessive reactive power flow over the
network heavily burdens the transformer, distribution and
transmission lines, increases the line losses, and impacts the voltage
stability. Reactive power compensators used for grid support with
slow dynamic response include the mechanically-switched capacitor
with damping network (MSCDN), the thyristor switched capacitor
(TSC), and the thyristor-controlled reactor (TCR). A static
synchronous compensator (STATCOM), built using voltage source
converter (VSC), can provide reactive power support with a less noisy
sinusoidal current injection due to operation at higher effective
frequency and generally take up less real estate compared to TSCs
and TCRs for the same level of harmonics and power rating.
Existing system:
The Multi-level STATCOM architectures such as the diode or
neutral-clamped, flying capacitor, and cascaded H-bridges, can be
scaled to medium voltage with fractionally-rated components. VSC-
based VAr compensators require bulk energy storage, typically

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implemented using electrolytic capacitors, to support the DC link
voltages. While the technology advances in electrolytic capacitors
have come a long way, compared to film-based capacitors, they still
have reliability and safety issues that contribute to a shorter life. In
addition, fault management in a VSC-based architecture is made
complex due to the presence of DC source(s) that can contribute to
high fault currents, requiring fast detection and isolation. As
reliability and long life is of utmost concern with utility-grade
equipment, a technology that can provide STATCOM functionality
but with higher reliability and longer life is needed. As an alternative
to the VSC based VAr compensator, this paper proposes a novel
modular current source inverter (CSI) based topology to provide
STATCOM functionality. The topology is derived from Dynamic-
Current or Dyna-C, a patented power converter capable of
transferring energy for two- or multi-terminal DC, single- and/or
multi-phase AC systems
Disadvantages:
 Excessive reactive power flow over the network heavily burdens
the transformer,
 Distribution and transmission lines,
 Increases the line losses,
 Impact the voltage stability.
Proposed system:
The proposed topology of the Dyna-C DVC, which is also a
modular building block, consists of three single-phase CSI modules
coupled together with a three-winding medium- to high-frequency
transformer. Appropriate LC filters are used around the three low
frequency AC terminals for suppressing switching harmonics in the

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current. Unlike a CSI, the magnetizing inductance of the transformer
itself is used to store energy. The modules are the proposed topology
of the Dyna-C DVC. The topology, which is also a modular building
block, consists of three single-phase CSI modules coupled together
with a three-winding medium- to high-frequency transformer.
Appropriate LC filters are used around the three low frequency AC
terminals for suppressing switching harmonics in the current. Unlike a
CSI, the magnetizing inductance of the transformer itself is used to
store energy. The modules are to isolate a fault on one phase from
propagating to the other two phases, especially in medium-voltage
application where the fault could quickly bridge the phases and
propagate through all the modules, compromising safety and speed of
fault isolation. However, in low-voltage applications in which
alternate safety mechanisms are provides, the three-winding
transformer can be replaced by an inductor with a single winding and
a core. The switching devices of the CSI bridges conduct current in
one direction but block voltages in both directions. This is typically
implemented with either a MOSFET or IGBT in series with a diode,
or a revere blocking IGBT (RB-IGBT).

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Advantages:
 Dynamically leading or lagging of reactive power.
 High-frequency transformer is used for inter-phase fault
isolation among the three-phase.
 Current ripple can be significantly reduced,
 Smaller filter design.
Applications:
 Medium voltage applications
 Power transmission applications

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Block diagram:
Dynamic current building block
AC Unbalanced
Load
CSI 2
DC
supply
Gate driver circuit 12 V
DC
Buffer circuit
Micro-controller
circuit
5V
DC
Supply
L filter
Impedance
circuit
CSI 3
CSI 1
Multi winding
Transformer
DC
supply
Inductive
circuit
Inductive
circuit