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DTSTART:20201004T030000
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DTSTAMP:20200803T090126Z
UID:866EFDDE-6031-45E6-864A-2DF4C1419462
DTSTART;TZID=Australia/Sydney:20200721T113000
DTEND;TZID=Australia/Sydney:20200721T123000
DESCRIPTION:Over the last decade\, electronics industry has seen many comme
 rcial versions of electrical double layer capacitors (EDLC)\, which are al
 so known as ultra-capacitors and supercapacitors. The usual application sc
 ope of EDLCs is replacing the electrochemical batteries with their higher 
 power density and moderately high energy density. An EDLC gives an approxi
 mately one million times larger capacitance compared to an electrolytic. I
 n the current component markets\, EDLCs come in capacitances vary from 0.2
  to 7500 farads\, with the limitation of very low DC voltage ratings from 
 0.7 V to 4 V. Recently some SC manufacturers have introduced a novel famil
 y of supercap- batteries where capacitance has gone up to 70\,000 F. Joint
  work of power electronics research groups at the University of Waikato an
 d AUT established the early scientific clues of using supercapacitors in t
 he non-traditional application domain to develop novel power electronic ci
 rcuit topologies. The success of the early projects was able to achieve th
 e unique SCALoM theory in which the losses in the RC loop can be theoretic
 ally minimized by two combined steps namely\; (i) adding a power electroni
 cs building block (PEBB) into RC the loop\, and (ii) replacing the capacit
 or with a several orders larger device. Based on this concept\, numerous s
 upercapacitor- assisted (SCA) power converter circuit topologies have been
  investigated over the last 10 years of research work.\n\nIn this webinar\
 , the SCALoM Theory and the examples of successful SCA applications will b
 e discussed including many patented or patent pending such as SCA low drop
 out regulator (SCALDO)\, SCA surge absorber (SCASA)\, SCA wide input PV in
 verter (SCAWI-PV Inverter) and SCA light emitting diodes (SCALED). With re
 newable energy resources proliferating with DC loads such as data centres\
 , variable speed drives and other internally DC driven domestic and indust
 rial loads\, SCA techniques’ wide scope in the potential applications in
  DC Microgrid area will also be discussed.\n\nSpeaker(s): Dr Kosala Gunawa
 rdane\, A/Prof Nihal Kularatna \n\nvia Zoom\, link at bottom of page\, New
  South Wales\, Australia
LOCATION:via Zoom\, link at bottom of page\, New South Wales\, Australia
ORGANIZER:dylandclu@ieee.org
SEQUENCE:10
SUMMARY:Supercapacitor-assisted novel power electronic circuit topologies f
 or DC Microgrid Applications
URL;VALUE=URI:https://events.vtools.ieee.org/m/234367
X-ALT-DESC:Description: &lt;br /&gt;&lt;p&gt;Over the last decade\, electronics industr
 y has seen many commercial versions of electrical double layer capacitors 
 (EDLC)\, which are also known as ultra-capacitors and supercapacitors. The
  usual application scope of EDLCs is replacing the electrochemical batteri
 es with their higher power density and moderately high energy density. An 
 EDLC gives an approximately one million times larger capacitance compared 
 to an electrolytic. In the current component markets\, EDLCs come in capac
 itances vary from 0.2 to 7500 farads\, with the limitation of very low DC 
 voltage ratings from 0.7 V to 4 V. Recently some SC manufacturers have int
 roduced a novel family of supercap- batteries where capacitance has gone u
 p to 70\,000 F. Joint work of power electronics research groups at the Uni
 versity of Waikato and AUT established the early scientific clues of using
  supercapacitors in the non-traditional application domain to develop nove
 l power electronic circuit topologies. The success of the early projects w
 as able to achieve the unique SCALoM theory in which the losses in the RC 
 loop can be theoretically minimized by two combined steps namely\; (i) add
 ing a power electronics building block (PEBB) into RC the loop\, and (ii) 
 replacing the capacitor with a several orders larger device. Based on this
  concept\, numerous supercapacitor- assisted (SCA) power converter circuit
  topologies have been investigated over the last 10 years of research work
 .&lt;/p&gt;\n&lt;p&gt;In this webinar\, the SCALoM Theory and the examples of successf
 ul SCA applications will be discussed including many patented or patent pe
 nding such as SCA low dropout regulator (SCALDO)\, SCA surge absorber (SCA
 SA)\, SCA wide input PV inverter (SCAWI-PV Inverter) and SCA light emittin
 g diodes (SCALED). With renewable energy resources proliferating with DC l
 oads such as data centres\, variable speed drives and other internally DC 
 driven domestic and industrial loads\, SCA techniques&amp;rsquo\; wide scope i
 n the potential applications in DC Microgrid area will also be discussed.&lt;
 /p&gt;
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