High-voltage Static VAR Compensator (SVC) - Sun.King Technology Group Limited

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High-voltage �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Static VAR Com�� Ƴ�� Ƴ�� Ƴ��pensator (SV�� Ƴ�� Ƴ�� Ƴ�� Ƴ��C)

High-voltage S�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tatic VAR Compensator �� Ƴ�� Ƴ�� Ƴ��(SVC)

High-voltage Sta�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tic VAR Compensat�� Ƴ�� Ƴ�� Ƴ�� Ƴ��or is a typica�� Ƴ�� Ƴ�� Ƴ��l Flexible AC �� Ƴ�� Ƴ�� Ƴ�� Ƴ��transmission device. Whe�� Ƴ�� Ƴ�� Ƴ��n applied in power t�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ransmission systems, it �� Ƴ�� Ƴ�� Ƴ��increases tran�� Ƴ�� Ƴ�� Ƴ��smission capacity,�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� stabilizes system�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� voltage, damps �� Ƴ�� Ƴ�� Ƴ�� Ƴ��low frequency�� Ƴ�� Ƴ�� oscillations�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� and suppresses �� Ƴ�� Ƴ�� Ƴ�� Ƴ��sub synchronous os�� Ƴ�� Ƴ�� Ƴ�� Ƴ��cillations. Wh�� Ƴ�� Ƴ�� Ƴ��en used in ind�� Ƴ�� Ƴ��ustrial power dis�� Ƴ�� Ƴ��tribution networks, su�� Ƴ�� Ƴ��ch as electrified ra�� Ƴ�� Ƴ�� Ƴ��ilways, metallurgic�� Ƴ�� Ƴ�� Ƴ�� Ƴ��al and other in�� Ƴ�� Ƴ�� Ƴ�� Ƴ��dustrial users, SVC can �� Ƴ�� Ƴ�� Ƴ�� Ƴ��lower voltag�� Ƴ�� Ƴ�� Ƴ�� Ƴ��e fluctuatio�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ns, flickering, negativ�� Ƴ�� Ƴ��e sequences and harmonic�� Ƴ�� Ƴ�� Ƴ�� Ƴ��s which are cau�� Ƴ�� Ƴ�� Ƴ��sed by nonlinear �� Ƴ�� Ƴ�� Ƴ�� Ƴ��and impact load�� Ƴ�� Ƴ��s, and in the meanti�� Ƴ�� Ƴ�� Ƴ��me improve power quali�� Ƴ�� Ƴ�� Ƴ��ty, effectively �� Ƴ�� Ƴ�� Ƴ��enhance users’ produc�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tion efficiency, incre�� Ƴ�� Ƴ�� Ƴ��ase load powe�� Ƴ�� Ƴ�� Ƴ�� Ƴ��r factors, reduc�� Ƴ�� Ƴ�� Ƴ��e reactive power flo�� Ƴ�� Ƴ�� Ƴ��w and cut netwo�� Ƴ�� Ƴ�� Ƴ��rk losses.

Device functi�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ons

Functions of SVC in tra�� Ƴ�� Ƴ��nsmission grids

Significantly increas�� Ƴ�� Ƴ�� Ƴ�� Ƴ��e transmission �� Ƴ�� Ƴ��capacity
Improve syste�� Ƴ�� Ƴ��m stability
Enhance damping and�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� low frequency oscil�� Ƴ�� Ƴ�� Ƴ�� Ƴ��lation suppre�� Ƴ�� Ƴ�� Ƴ��ssion
Reduce sub-s�� Ƴ�� Ƴ��ynchronous resonance
Achieve continuous�� Ƴ�� Ƴ�� Ƴ��, dynamic and pre�� Ƴ�� Ƴ�� Ƴ�� Ƴ��cise system volt�� Ƴ�� Ƴ��age regulati�� Ƴ�� Ƴ�� Ƴ��on
Reduce netwo�� Ƴ�� Ƴ�� Ƴ�� Ƴ��rk losses

Functions of SV�� Ƴ�� Ƴ�� Ƴ�� Ƴ��C in industrial dis�� Ƴ�� Ƴ��tribution net�� Ƴ�� Ƴ�� Ƴ��works

Increase the power fa�� Ƴ�� Ƴ��ctor
Reduce network losses
Suppression of harmo�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nic interference caus�� Ƴ�� Ƴ�� Ƴ��ed by a nonlinear�� Ƴ�� Ƴ�� Ƴ�� load
3-phase load balancing
Reduce negative se�� Ƴ�� Ƴ�� Ƴ�� Ƴ��quence, voltage�� Ƴ�� Ƴ�� Ƴ�� fluctuations and flick�� Ƴ�� Ƴ��er
Improve power�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� quality
Improve production e�� Ƴ�� Ƴ�� Ƴ�� Ƴ��fficiency

Functions of �� Ƴ�� Ƴ�� Ƴ�� Ƴ��SVC in wind farms

Increase system�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� stability
Suppress voltag�� Ƴ�� Ƴ�� Ƴ��e fluctuations
Enhance damping and low �� Ƴ�� Ƴ��frequency oscillatio�� Ƴ�� Ƴ�� Ƴ��n suppression

Technical features

DSP-based fully digi�� Ƴ�� Ƴ��tal control syst�� Ƴ�� Ƴ�� Ƴ��em, fast dynamic �� Ƴ�� Ƴ�� Ƴ�� Ƴ��response, high �� Ƴ�� Ƴ�� Ƴ��controlling accur�� Ƴ�� Ƴ�� Ƴ�� Ƴ��acy
Using optical trigg�� Ƴ�� Ƴ��er and producing en�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ergy under high volt�� Ƴ�� Ƴ�� Ƴ�� Ƴ��age from a high po�� Ƴ�� Ƴ��tential board�� Ƴ�� Ƴ��, and with BOD thyristo�� Ƴ�� Ƴ�� Ƴ��r protection,�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� the system ha�� Ƴ�� Ƴ�� Ƴ��s strong anti-jamming c�� Ƴ�� Ƴ��apabilities
With horizontal t�� Ƴ�� Ƴ�� Ƴ��hyristor valve desig�� Ƴ�� Ƴ�� Ƴ��n, the equipment i�� Ƴ�� Ƴ��s compact, reli�� Ƴ�� Ƴ��able and requir�� Ƴ�� Ƴ�� Ƴ�� Ƴ��es less maintenance
Thyristor valve uses co�� Ƴ�� Ƴ�� Ƴ�� Ƴ��mponents and water coole�� Ƴ�� Ƴ�� Ƴ��r from well-known f�� Ƴ�� Ƴ��oreign companies�� Ƴ�� Ƴ�� Ƴ�� Ƴ��
Closed pure water cooli�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ng system is adopted, p�� Ƴ�� Ƴ�� Ƴ�� Ƴ��roviding a high cool�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ing efficien�� Ƴ�� Ƴ�� Ƴ��cy and more relia�� Ƴ�� Ƴ�� Ƴ��bility in operation
The monitoring �� Ƴ�� Ƴ�� Ƴ�� Ƴ��system is in an integra�� Ƴ�� Ƴ�� Ƴ��ted workstat�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ion which provide�� Ƴ�� Ƴ�� Ƴ��s a user-friendly huma�� Ƴ�� Ƴ�� Ƴ�� Ƴ��n machine interface �� Ƴ�� Ƴ�� Ƴ��(HMI)
Flexible control �� Ƴ�� Ƴ��modes; a var�� Ƴ�� Ƴ�� Ƴ�� Ƴ��iety of control�� Ƴ�� Ƴ�� Ƴ�� modes can b�� Ƴ�� Ƴ�� Ƴ�� Ƴ��e achieved, such�� Ƴ�� Ƴ�� as three-ph�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ase simultaneous co�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ntrol, split phase �� Ƴ�� Ƴ�� Ƴ��control and balanced t�� Ƴ�� Ƴ�� Ƴ�� Ƴ��hree-phase control
Multifunctional aut�� Ƴ�� Ƴ�� Ƴ�� Ƴ��omation inter�� Ƴ�� Ƴ�� Ƴ�� Ƴ��face; remote operati�� Ƴ�� Ƴ��on and automation sys�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tem interface �� Ƴ�� Ƴ�� Ƴ��functions can be a�� Ƴ�� Ƴ��chieved, thus �� Ƴ�� Ƴ�� Ƴ��system allows to be �� Ƴ�� Ƴ�� Ƴ�� Ƴ��unattended
Dual-redundant digital �� Ƴ�� Ƴ�� Ƴ��protection: the syst�� Ƴ�� Ƴ�� Ƴ��em includes a �� Ƴ�� Ƴ��fast failure locko�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ut device in�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� addition to�� Ƴ�� Ƴ�� Ƴ�� back-up computer pr�� Ƴ�� Ƴ�� Ƴ�� Ƴ��otection;
Modular desi�� Ƴ�� Ƴ�� Ƴ�� Ƴ��gn, which is ab�� Ƴ�� Ƴ�� Ƴ��le to offer integrated�� Ƴ�� Ƴ�� constructions to dev�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ices ranging from sever�� Ƴ�� Ƴ�� Ƴ��al megabytes to se�� Ƴ�� Ƴ�� Ƴ��veral hundred meg�� Ƴ�� Ƴ�� Ƴ�� Ƴ��abytes
All outdoor layout
In order to reduc�� Ƴ�� Ƴ��e the installation a�� Ƴ�� Ƴ�� Ƴ��rea and to be mobile �� Ƴ�� Ƴ��and flexible, the m�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ovable SVC (RSVC) with�� Ƴ�� Ƴ�� its compact l�� Ƴ�� Ƴ�� Ƴ��ayout can be used