High power rectifier isolated power grid project - Sun.King Technology Group Limited

High power rec�� Ƴ�� Ƴ�� Ƴ��tifier isolated po�� Ƴ�� Ƴ�� Ƴ�� Ƴ��wer grid proj�� Ƴ�� Ƴ��ect

1. Introduction

In the electr�� Ƴ�� Ƴ�� Ƴ�� Ƴ��olytic aluminum and �� Ƴ�� Ƴ�� Ƴ�� Ƴ��electrochemical �� Ƴ�� Ƴ��industry, the cost�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� of electrolytic pro�� Ƴ�� Ƴ�� Ƴ��duction is high in�� Ƴ�� Ƴ�� the proport�� Ƴ�� Ƴ��ion of electricity pr�� Ƴ�� Ƴ��ice. Saving electrici�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ty can reduce production�� Ƴ�� Ƴ�� Ƴ�� cost, strive for grea�� Ƴ�� Ƴ��ter profit. Recently�� Ƴ�� Ƴ��, many large�� Ƴ�� Ƴ�� power users are �� Ƴ�� Ƴ�� Ƴ��considering setting up t�� Ƴ�� Ƴ�� Ƴ�� Ƴ��heir own "micro�� Ƴ�� Ƴ��grids". That is, u�� Ƴ�� Ƴ��sing the isolat�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ed power grid�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� rectifier te�� Ƴ�� Ƴ�� Ƴ�� Ƴ��chnology. In�� Ƴ�� Ƴ�� this situation, becaus�� Ƴ�� Ƴ�� Ƴ��e the thyristor has the�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� ability to �� Ƴ�� Ƴ�� Ƴ��adjust the curre�� Ƴ�� Ƴ��nt quickly, stabl�� Ƴ�� Ƴ��y and accurately, on�� Ƴ�� Ƴ�� Ƴ��ly using the high-p�� Ƴ�� Ƴ��ower thyristor r�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ectifier can i�� Ƴ�� Ƴ��t accommodate to the�� Ƴ�� Ƴ�� Ƴ�� load change�� Ƴ�� Ƴ�� Ƴ�� (low frequency l�� Ƴ�� Ƴ�� Ƴ��oad reduction) caused b�� Ƴ�� Ƴ�� Ƴ��y the generator set in�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� the power pl�� Ƴ�� Ƴ��ant. That is to sa�� Ƴ�� Ƴ��y, it can save �� Ƴ�� Ƴ��more cost of ele�� Ƴ�� Ƴ�� Ƴ��ctricity by th�� Ƴ�� Ƴ��e high-power rectifi�� Ƴ�� Ƴ�� Ƴ�� Ƴ��er power supply technolo�� Ƴ�� Ƴ�� Ƴ��gy in the isolat�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ed power gri�� Ƴ�� Ƴ�� Ƴ��d.

The rectifier d�� Ƴ�� Ƴ��evice for alu�� Ƴ�� Ƴ��minum electrolys�� Ƴ�� Ƴ�� Ƴ��is in the power supply m�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ode of isolated pow�� Ƴ�� Ƴ�� Ƴ�� Ƴ��er grid is an independen�� Ƴ�� Ƴ�� Ƴ��t rectifier s�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ystem developed by our �� Ƴ�� Ƴ�� Ƴ��company. The results �� Ƴ�� Ƴ��of the project can�� Ƴ�� Ƴ�� Ƴ�� be widely used under t�� Ƴ�� Ƴ�� Ƴ�� Ƴ��he power supply m�� Ƴ�� Ƴ�� Ƴ��ode of the isolated p�� Ƴ�� Ƴ��ower grid in th�� Ƴ�� Ƴ��e coal, electric�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ity and alumin�� Ƴ�� Ƴ�� Ƴ�� Ƴ��um integratio�� Ƴ�� Ƴ�� Ƴ�� Ƴ��n project, and el�� Ƴ�� Ƴ��ectrolytic alumin�� Ƴ�� Ƴ��um projects w�� Ƴ�� Ƴ�� Ƴ��here clean and r�� Ƴ�� Ƴ�� Ƴ�� Ƴ��enewable energy sources�� Ƴ�� Ƴ�� Ƴ�� such as wind or s�� Ƴ�� Ƴ�� Ƴ�� Ƴ��olar power are comb�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ined with tradi�� Ƴ�� Ƴ��tional thermal �� Ƴ�� Ƴ��power. Its re�� Ƴ�� Ƴ��ctifying efficiency is �� Ƴ�� Ƴ��2% higher than that o�� Ƴ�� Ƴ�� Ƴ��f the traditional dio�� Ƴ�� Ƴ�� Ƴ�� Ƴ��de rectifier �� Ƴ�� Ƴ�� Ƴ�� Ƴ��system, and it �� Ƴ�� Ƴ�� Ƴ��has remarkable ener�� Ƴ�� Ƴ��gy saving effect.�� Ƴ�� Ƴ�� Ƴ�� The popularizatio�� Ƴ�� Ƴ��n of the project ac�� Ƴ�� Ƴ�� Ƴ�� Ƴ��hievement can drive th�� Ƴ�� Ƴ�� Ƴ��e transformation from t�� Ƴ�� Ƴ��raditional e�� Ƴ�� Ƴ�� Ƴ�� Ƴ��lectrolytic aluminum �� Ƴ�� Ƴ�� Ƴ��diode rectifier�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� to the thyris�� Ƴ�� Ƴ��tor rectifier�� Ƴ�� Ƴ�� Ƴ�� which is po�� Ƴ�� Ƴ�� Ƴ��werd by the is�� Ƴ�� Ƴ��olated power grid suppl�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ied with renewab�� Ƴ�� Ƴ�� Ƴ�� Ƴ��le energy.

2. Project case

The second phase of �� Ƴ�� Ƴ�� Ƴ��a technical reform p�� Ƴ�� Ƴ�� Ƴ�� Ƴ��roject in Northw�� Ƴ�� Ƴ��est China — an elect�� Ƴ�� Ƴ��rolytic aluminum �� Ƴ�� Ƴ�� Ƴ�� Ƴ��project with an �� Ƴ�� Ƴ��annual output of 2×45�� Ƴ�� Ƴ��0,000 tons.

Description of works：

After the completion�� Ƴ�� Ƴ�� of the proje�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ct, there are �� Ƴ�� Ƴ�� Ƴ��6×300MW gener�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ator units running p�� Ƴ�� Ƴ�� Ƴ�� Ƴ��arallel to build an int�� Ƴ�� Ƴ��ernal microgrid �� Ƴ�� Ƴ��( the isolated power�� Ƴ�� Ƴ�� grid), which dir�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ectly supplies power �� Ƴ�� Ƴ�� Ƴ�� Ƴ��to two aluminum elec�� Ƴ�� Ƴ�� Ƴ��trolysis series �� Ƴ�� Ƴ�� Ƴ��through the 330kV genera�� Ƴ�� Ƴ�� Ƴ�� Ƴ��trix.

Aluminum electr�� Ƴ�� Ƴ�� Ƴ�� Ƴ��olysis series adopts�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� 500kA electrolytic cell�� Ƴ�� Ƴ�� Ƴ��, each series ins�� Ƴ�� Ƴ�� Ƴ�� Ƴ��talls 336 sets, rate�� Ƴ�� Ƴ��d voltage is�� Ƴ�� Ƴ�� Ƴ�� 1480V. The sy�� Ƴ�� Ƴ�� Ƴ��stem is connected to �� Ƴ�� Ƴ�� Ƴ��the external large po�� Ƴ�� Ƴ��wer grid through �� Ƴ�� Ƴ�� Ƴ��a 330kV dedic�� Ƴ�� Ƴ��ated circuit, an�� Ƴ�� Ƴ�� Ƴ��d can provide two alumi�� Ƴ�� Ƴ�� Ƴ��num electrolysis series �� Ƴ�� Ƴ�� Ƴ�� Ƴ��with emergency s�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tandby pow�� Ƴ�� Ƴ�� Ƴ�� Ƴ��er supply not higher th�� Ƴ�� Ƴ��an 500MW.

3. Product adv�� Ƴ�� Ƴ�� Ƴ��antages

The main technical �� Ƴ�� Ƴ�� Ƴ��advantages a�� Ƴ�� Ƴ��re as follows�� Ƴ�� Ƴ�� Ƴ�� Ƴ��:

3.1 The inte�� Ƴ�� Ƴ��lligent digital te�� Ƴ�� Ƴ�� Ƴ��chnology is used to �� Ƴ�� Ƴ�� Ƴ��combine the total c�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ontrol system,�� Ƴ�� Ƴ�� Ƴ�� the split-f�� Ƴ�� Ƴ�� Ƴ�� Ƴ��low regulation stead�� Ƴ�� Ƴ�� Ƴ��y current contro�� Ƴ�� Ƴ�� Ƴ��l system, the cons�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tant power contro�� Ƴ�� Ƴ�� Ƴ��l, the frequ�� Ƴ�� Ƴ��ency modulation and�� Ƴ�� Ƴ�� load reduction tech�� Ƴ�� Ƴ��nology etc. �� Ƴ�� Ƴ�� Ƴ�� Ƴ��into a control s�� Ƴ�� Ƴ�� Ƴ��ystem organically.

According to the c�� Ƴ�� Ƴ�� Ƴ�� Ƴ��hange of power suppl�� Ƴ�� Ƴ��y and load, the aut�� Ƴ�� Ƴ�� Ƴ��omatic switchin�� Ƴ�� Ƴ�� Ƴ�� Ƴ��g uses different opera�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tion modes such as s�� Ƴ�� Ƴ�� Ƴ��teady current �� Ƴ�� Ƴ��control and constant po�� Ƴ�� Ƴ�� Ƴ��wer control, �� Ƴ�� Ƴ��which can ensure the�� Ƴ�� Ƴ�� safety of t�� Ƴ�� Ƴ�� Ƴ��he power plant gene�� Ƴ�� Ƴ�� Ƴ�� Ƴ��rator and meet the need�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� of stable ope�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ration of the electrol�� Ƴ�� Ƴ��ytic cell.

3.2 This proje�� Ƴ�� Ƴ��ct adopts thyri�� Ƴ�� Ƴ�� Ƴ�� Ƴ��stor digital i�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ntelligent stead�� Ƴ�� Ƴ�� Ƴ��y current tech�� Ƴ�� Ƴ��nology, digital�� Ƴ�� Ƴ�� Ƴ�� frequency modulatio�� Ƴ�� Ƴ��n and load reduction�� Ƴ�� Ƴ�� Ƴ�� technology �� Ƴ�� Ƴ��of power network. Th�� Ƴ�� Ƴ��e thyristor di�� Ƴ�� Ƴ��gital steady current sy�� Ƴ�� Ƴ�� Ƴ��stem makes the rectifier�� Ƴ�� Ƴ�� Ƴ�� have the advantages of �� Ƴ�� Ƴ��fast response time and �� Ƴ�� Ƴ��wide range of load�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� regulation, whi�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ch makes the spe�� Ƴ�� Ƴ��ed and effect of digit�� Ƴ�� Ƴ�� Ƴ�� Ƴ��al frequency modul�� Ƴ�� Ƴ�� Ƴ��ation and load red�� Ƴ�� Ƴ�� Ƴ�� Ƴ��uction of power grid �� Ƴ�� Ƴ�� Ƴ�� Ƴ��better.

After the alumi�� Ƴ�� Ƴ��num electrolysis pr�� Ƴ�� Ƴ��oject used this tech�� Ƴ�� Ƴ��nology in the i�� Ƴ�� Ƴ�� Ƴ�� Ƴ��solated power �� Ƴ�� Ƴ�� Ƴ�� Ƴ��supply mode, th�� Ƴ�� Ƴ�� Ƴ��e AC side power grid �� Ƴ�� Ƴ�� Ƴ��is more stable�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� because of digita�� Ƴ�� Ƴ�� Ƴ��l frequency m�� Ƴ�� Ƴ�� Ƴ��odulation and load�� Ƴ�� Ƴ�� reduction technolo�� Ƴ�� Ƴ�� Ƴ��gy, the stea�� Ƴ�� Ƴ�� Ƴ�� Ƴ��dy current effec�� Ƴ�� Ƴ��t of DC side�� Ƴ�� Ƴ�� Ƴ�� current is bet�� Ƴ�� Ƴ��ter, and the�� Ƴ�� Ƴ�� precision of stea�� Ƴ�� Ƴ�� Ƴ��dy current is up to �� Ƴ�� Ƴ��0.2% because of thyris�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tor digital intelligent �� Ƴ�� Ƴ�� Ƴ�� Ƴ��steady curre�� Ƴ�� Ƴ�� Ƴ��nt technolog�� Ƴ�� Ƴ�� Ƴ��y. Compared with the�� Ƴ�� Ƴ�� diode rectifier e�� Ƴ�� Ƴ�� Ƴ��quipment wit�� Ƴ�� Ƴ�� Ƴ�� Ƴ��hout this technol�� Ƴ�� Ƴ��ogy, the electricity co�� Ƴ�� Ƴ�� Ƴ��nsumption can be �� Ƴ�� Ƴ��saved by 2% in the pr�� Ƴ�� Ƴ�� Ƴ��oduction process�� Ƴ�� Ƴ�� of aluminum electrolysi�� Ƴ�� Ƴ�� Ƴ�� Ƴ��s, and the ene�� Ƴ�� Ƴ��rgy saving effect is�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� remarkable.

3.3 The digital pulse c�� Ƴ�� Ƴ�� Ƴ��ontrol technolo�� Ƴ�� Ƴ��gy has strong magnetic �� Ƴ�� Ƴ��field resistance�� Ƴ�� Ƴ�� Ƴ�� Ƴ��. The thyristor rect�� Ƴ�� Ƴ��ifier uses pulse op�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ening angle t�� Ƴ�� Ƴ�� Ƴ�� Ƴ��o steady the current�� Ƴ�� Ƴ�� Ƴ��. The digital �� Ƴ�� Ƴ�� Ƴ�� Ƴ��PID operation c�� Ƴ�� Ƴ�� Ƴ��an improve the st�� Ƴ�� Ƴ�� Ƴ��eady current effect and�� Ƴ�� Ƴ�� Ƴ�� the response �� Ƴ�� Ƴ�� Ƴ��speed greatly. The �� Ƴ�� Ƴ��higher the st�� Ƴ�� Ƴ��ability of DC powe�� Ƴ�� Ƴ�� Ƴ��r supply in e�� Ƴ�� Ƴ�� Ƴ��lectrolytic aluminum�� Ƴ�� Ƴ�� Ƴ�� is, the higher�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� the product�� Ƴ�� Ƴ��ion efficiency will be�� Ƴ�� Ƴ��. The digital stead�� Ƴ�� Ƴ�� Ƴ�� Ƴ��y current control sys�� Ƴ�� Ƴ�� Ƴ�� Ƴ��tem can effectively �� Ƴ�� Ƴ��improve the productio�� Ƴ�� Ƴ�� Ƴ��n efficiency of e�� Ƴ�� Ƴ��lectrolytic al�� Ƴ�� Ƴ�� Ƴ��uminum.

3.4 The recur�� Ƴ�� Ƴ��rent protection f�� Ƴ�� Ƴ��unction of the newly dev�� Ƴ�� Ƴ�� Ƴ��eloped thyrist�� Ƴ�� Ƴ�� Ƴ�� Ƴ��or rectifier device c�� Ƴ�� Ƴ�� Ƴ��an make the t�� Ƴ�� Ƴ�� Ƴ�� Ƴ��hyristor achieve th�� Ƴ�� Ƴ�� Ƴ��e effect which o�� Ƴ�� Ƴ��f diode state at the �� Ƴ�� Ƴ�� Ƴ�� Ƴ��moment of high vol�� Ƴ�� Ƴ��tage tripping, �� Ƴ�� Ƴ�� Ƴ��fully release th�� Ƴ�� Ƴ�� Ƴ��e energy storage, and�� Ƴ�� Ƴ�� Ƴ�� protect the safety of D�� Ƴ�� Ƴ��C power supp�� Ƴ�� Ƴ�� Ƴ��ly equipment.

3.5 The industrializati�� Ƴ�� Ƴ��on and application of hi�� Ƴ�� Ƴ�� Ƴ��gh-power recti�� Ƴ�� Ƴ��fier isolated powe�� Ƴ�� Ƴ�� Ƴ�� Ƴ��r grid supply �� Ƴ�� Ƴ��project conform�� Ƴ�� Ƴ�� Ƴ��s to the energy-�� Ƴ�� Ƴ�� Ƴ��saving techn�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ology of boiler, kiln,�� Ƴ�� Ƴ�� reactor and relat�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ed energy consu�� Ƴ�� Ƴ��mption equipment in t�� Ƴ�� Ƴ�� Ƴ��he field of en�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ergy saving and enviro�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nmental protectio�� Ƴ�� Ƴ�� Ƴ��n; and new technologies �� Ƴ�� Ƴ�� Ƴ�� Ƴ��and equipment in the f�� Ƴ�� Ƴ��ield of new energy and �� Ƴ�� Ƴ��renewable energy, such �� Ƴ�� Ƴ�� Ƴ��as wind energ�� Ƴ�� Ƴ�� Ƴ�� Ƴ��y、 solar ene�� Ƴ�� Ƴ�� Ƴ��rgy.

The product of this pr�� Ƴ�� Ƴ�� Ƴ�� Ƴ��oject fills the tec�� Ƴ�� Ƴ�� Ƴ��hnology blank in China, �� Ƴ�� Ƴ�� Ƴ��the technical l�� Ƴ�� Ƴ�� Ƴ��evel reaches the intern�� Ƴ�� Ƴ��ational leading le�� Ƴ�� Ƴ�� Ƴ��vel, greatly e�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nhances the �� Ƴ�� Ƴ�� Ƴ�� Ƴ��competitive power �� Ƴ�� Ƴ��of the product in do�� Ƴ�� Ƴ�� Ƴ�� Ƴ��mestic and foreign marke�� Ƴ�� Ƴ�� Ƴ�� Ƴ��t .

4. Pictures of project�� Ƴ�� Ƴ��s

4.1 Power grid system�� Ƴ�� Ƴ�� Ƴ��

4.2 Rectifier �� Ƴ�� Ƴ��cabinet device in or�� Ƴ�� Ƴ��der

4.3 Control �� Ƴ�� Ƴ�� Ƴ�� Ƴ��system in ce�� Ƴ�� Ƴ��ntralized pl�� Ƴ�� Ƴ��acement

5. Latest cooperation�� Ƴ�� Ƴ�� Ƴ�� projects

In running:

Phase II electro�� Ƴ�� Ƴ�� Ƴ��lytic aluminum project o�� Ƴ�� Ƴ�� Ƴ�� Ƴ��f Jia-jiu wind �� Ƴ�� Ƴ��power high-load ch�� Ƴ�� Ƴ��aracteristic alumi�� Ƴ�� Ƴ�� Ƴ��num alloy ener�� Ƴ�� Ƴ��gy-saving tec�� Ƴ�� Ƴ�� Ƴ�� Ƴ��hnical reform pro�� Ƴ�� Ƴ�� Ƴ��ject with the�� Ƴ�� Ƴ�� annual prod�� Ƴ�� Ƴ�� Ƴ�� Ƴ��uction of 2×�� Ƴ�� Ƴ��450,000 tons of Ji�� Ƴ�� Ƴ��ugang Group Gansu�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Dongxing Aluminum I�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ndustry Co., Ltd.&�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nbsp; &�� Ƴ�� Ƴ��nbsp;

Series 3 and Series�� Ƴ�� Ƴ�� Ƴ�� 4 electrolyt�� Ƴ�� Ƴ��ic aluminum proj�� Ƴ�� Ƴ�� Ƴ��ect of Xinjia�� Ƴ�� Ƴ�� Ƴ��ng East Hope G�� Ƴ�� Ƴ��roup

Non running：

Electrolytic aluminum�� Ƴ�� Ƴ�� project of G�� Ƴ�� Ƴ�� Ƴ�� Ƴ��uangxi Hualei new�� Ƴ�� Ƴ�� material co., Ltd �� Ƴ�� Ƴ��with the annua�� Ƴ�� Ƴ��l production of 45�� Ƴ�� Ƴ�� Ƴ�� Ƴ��0,000 tons

Electrolytic Al�� Ƴ�� Ƴ�� Ƴ�� Ƴ��uminum Project of Inner �� Ƴ�� Ƴ�� Ƴ��Mongolia Huayun New�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� material Co.,�� Ƴ�� Ƴ�� Ltd. with the�� Ƴ�� Ƴ�� annual production of 5�� Ƴ�� Ƴ��00,000 tons

Electrolytic �� Ƴ�� Ƴ��Aluminum Projec�� Ƴ�� Ƴ�� Ƴ�� Ƴ��t of Inner Mongolia�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� Chuangyuan Aluminum �� Ƴ�� Ƴ��Industry Co., �� Ƴ�� Ƴ�� Ƴ�� Ƴ��Ltd. with the annual p�� Ƴ�� Ƴ�� Ƴ�� Ƴ��roduction of 450,0�� Ƴ�� Ƴ��00 tons

Electrolytic Alumin�� Ƴ�� Ƴ��um Project of Guiz�� Ƴ�� Ƴ�� Ƴ�� Ƴ��hou Xingren Dengga�� Ƴ�� Ƴ��o Aluminum Industry Co�� Ƴ�� Ƴ�� Ƴ��., Ltd. with the an�� Ƴ�� Ƴ�� Ƴ�� Ƴ��nual production of 50�� Ƴ�� Ƴ�� Ƴ��0,000 tons

6. Project ach�� Ƴ�� Ƴ��ievement

obtained 1 inventio�� Ƴ�� Ƴ��n patent

A control system of hi�� Ƴ�� Ƴ�� Ƴ��gh power thyristor �� Ƴ�� Ƴ�� Ƴ�� Ƴ��rectifier for�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� aluminum el�� Ƴ�� Ƴ�� Ƴ�� Ƴ��ectrolysis under is�� Ƴ�� Ƴ��olated power�� Ƴ�� Ƴ�� Ƴ�� Ƴ�� grid operatio�� Ƴ�� Ƴ��n patent number：Z�� Ƴ�� Ƴ�� Ƴ�� Ƴ��L201310608929.8

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