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Series Features ◆Low torque, Compact design ◆Compatible with data bus protocols ◆Operating smoothly and reliability ◆Gold-Gold contact ensures low resistance ◆Precious metal contact makes the lifetime over-long

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SlipRing Sol u ti on s TEL +86- 755- 8204 2235 | Email | sal es sl i pri n g. cn | www.s l i p r i n g . c n | JINPAT E l ect roni cs C o. Lt d LPC/LPM/LPMS SERIES S eri esFeatures ◆ Low torque C o mp ac t design ◆ C o mp at i b l ewith data bus p r ot oc ol s ◆ Operating s moot hl y an d rel iab il it y ◆ Go l d -Go l d contact ens ureslow re si st anc e ◆ Prec ious me t al contact mak e s the lif et i me ov e r-l ong S p e c ific at ions Ca p s u l eSlipRing LP C/ LP M / LP M S S ERIES Co m p a c t d es ign---d iam et erofLPC s eriesis 22mmLPM s eriesis 12.5mmLPMS s er ies w ork t emp erat u r ecouldbe highto 200℃ is 7.9 -11.1 mm only. This s eriesof pr o du c tenjoys very high p r e c is io nand a do pt e d ad v an c e d m ili t a r y t e c hni qu eof su r fa c e -p r o c e ssi ng.Goldto gold cont act ens u re slow res is t anc e long lif e t im e and r e lia b le op e r a t i on . Its e s p e c ia lly fit for s m a ll/ m in i a t u r e r o ta ti n g sy st e mof tr a n s mi tti n glow c o nt r o lling s igna l.Metal or p la s t ic ho u s i ngare op t i on a l . T e chni cal P a ramet ers Numberof Cir c u it s 1 -125 ci r cu i t sor more Working Temp erat u r e -20℃ +60℃orcustomize Working Humidity 60R H or hi ghe r Vo l t ageRating 240 V AC/ D C Cu rre ntRating 2ampsper ci r cu i tor hi ghe r D ie le c t r ic S tr e n gth ≥ 500VAC 50Hz b et w ee neach ci r cu i t Ins u la t io n R e si st a nc e 100MΩ 500VD E le c t r ic a l Noise 1mΩMin WireSize AW G 28silverplated c o ppe r TeflonUL WireLength 250 mm O p t io na l Housing M at e r i al E ngi ne e r i ng p la s t icor me ta l O p ti o n a l P rot ec t ionGrade IP54or hi ghe r Remarks 1. Tr a ns m i t t i ng morethan30 kinds of si gna l ssuchasUSBRSLVDS C anbus FireWire 2. ins t a lla t i o nwaycanbeset accor d i ngto realusing s it u a t io n .

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SlipRing Sol u ti on s TEL +86- 755- 8204 2235 | Email | sal es sl i pri n g. cn | www.s l i p r i n g . c n | JINPAT E l ect roni cs C o. Lt d LPC/LPM/LPMS SERIES Notes: ◆ Operationa llif e≥5000000 0revolution s r efer e nc e ◆ Th e operationa llif e o fth euni tdepend s uponworking t emp er at u r e r ot a t i on s pe e d e nv i r o nm e ntand c on t i n u ou sworking lif e . Typical A ppl i c at i o n ◆ E le c t r ic a ltest equ ip ment ◆ Manufacturin gan dproces scontro l equ ip ment ◆ Indexin gtable cabl ereels ◆ C CT VPa n Til tcamer a mounts ◆ R ob ot i c s rot ary se nso r surgent illu m ina t i o n equ ip ment ◆ Exhibi t/displa yequipment ◆ Av ia t io n m il it a r y i ns t r u m e nt medical equ ip ment ◆ Clo s e d -c ir c u it c on t r ol ◆ Win dturbin e generator Option: ◆ Connecto r ◆ 2-12 5 Circuit s ◆ Housin g materia l ◆ Positio no fwir eoutle t ◆ P r ot e c t i onclassdustand w at er ◆ Cent ralthroughbore from 1.5-7mm ◆ Op erat ing s pe e d c u rr ent voltage ◆ Co npa t iblewithdatabus p r ot oc ol s E t he r ne tsignal RS s er iessignal ◆ Powe rrin gwit h5 Aan d10 Ai savailabl eupo n2 Aring scombinatio n Clo s e d -c ir c u it c on t r ol keeping im pr o vin gand i nno v a t i ng pr ec is io n s lip rings pr o du c e d by Jinpathave b een a ppl i e din eng i neer i ng m a c hi ner y security r adar a nt enna au t o m at i o n eq u i p m en t robot i ns t r um ent m edic a l av i at i o n marine eq u i p m en t shipandother v es s eland m ilit a r y fields

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S l i p R i n g S o l u ti o n s T E L + 8 6 - 7 5 5 - 8 2 0 4 2 2 3 5 | E m a i l | s a l e s s l i p r i n g . c n | w w w . s l i p r i n g . c n | J I N P A T E l e c t r o n i c s C o . L t d LPC SERIES D im e n s i o n s W i r e C o l o r C o d e W i r e S i z e R i n g C o l o r R i n g C o l o r R i n g C o l o r R i n g C o l o r A W G 2 8 s i l v e r p l a t e d c o p p e r T e f l o n U L 1 B L K 2 B R N 3 R E D 4 O R G 5 Y E L 6 G R N 7 B L K-B L U 8 P U R 9 G R A Y 1 0 W I T 1 1 P I N K 1 2 A Z U R Y 1 3 W I T / B L K 1 4 W I T / B R N 1 5 W I T / R E D 1 6 W I T / O R G 1 7 W I T / Y E T 1 8 W I T / G R N 1 9 W I T / B L U 2 0 W I T / P U R 2 1 W I T / G R A Y 2 2 C L A R 2 3 B L K-R E D 2 4 B L K/ B R N R e m a r k s : 1 . A W G 2 8 s i l v e r p l a t e d c o p p e r T e f l o n U L 2 4 d i f f e r e n t c o l o r s i n g l e w i r e s f o r a c i r c l e 2 . 1 f r o m r o t o r s i d e T h e c o l o r i f t h e w i r e c a n b e c h a n g e d .

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S l i p R i n g S o l u ti o n s T E L + 8 6 - 7 5 5 - 8 2 0 4 2 2 3 5 | E m a i l | s a l e s s l i p r i n g . c n | w w w . s l i p r i n g . c n | J I N P A T E l e c t r o n i c s C o . L t d LPC SERIES M o d e l C i r c u i t s O D L m m V o l t a g e V C u r r e n t( A O p e r a t i n g S p e e d r p m D e t a i l s L P C - 0 3 P 3 ø 2 2 . 0 X4 2 . 5 3 2 4 0 V 1 0 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 0 6 A 6 ø 2 2 . 0 X1 9 . 2 0 2 4 0 V 2 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 0 6 C 6 ø 2 1 . 5 X1 9 . 5 3 2 4 0 V 2 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 0 6 D 6 ø 2 2 . 0 X2 2 . 2 0 2 4 0 V 2 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 0 6 E 6 ø 2 2 . 0 X1 9 . 5 3 2 4 0 V 2 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 0 6 F 6 ø 2 2 . 0 X1 9 . 7 2 4 0 V 2 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 0 6 T 6 ø 2 4 . 8 × 3 1 2 4 0 V 2 A 0 2 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 0 8 A 8 ø 2 2 X2 1 . 4 2 4 0 V 2 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 0 8 B 8 ø 2 2 . 0 X2 6 . 4 3 2 4 0 V 2 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 1 2 A 1 2 ø 2 2 . 0 X2 6 . 4 3 2 4 0 V 2 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 1 2 C 1 2 ø 2 1 . 5 X2 6 . 3 8 2 4 0 V 2 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 1 2 D 1 2 ø 2 2 . 0 X2 6 . 3 8 2 4 0 V 2 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 1 2 E 1 2 ø 2 2 . 0 X2 6 . 4 3 2 4 0 V 2 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 1 2 H 1 2 ø 1 8 . 0 X2 1 . 0 0 2 4 0 V 2 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 1 2 T 1 2 ø 2 4 . 8 X3 9 . 8 2 4 0 V 2 A 0 2 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 1 3 A 1 3 ø 1 9 X2 8 . 9 2 4 0 V 2 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 1 4 B 1 4 ø 2 2 X2 9 . 2 2 4 0 V 2 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 1 8 A 1 8 ø 2 2 . 0 X3 5 . 0 3 2 4 0 V 2 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 1 8 D 1 8 ø 2 2 X3 2 . 8 5 2 4 0 V 2 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 1 8 F 1 8 ø 2 2 3 3 . 4 2 4 0 V 2 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 1 8 G 1 8 ø 2 2 X3 2 . 5 8 2 4 0 V 2 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 1 8 H 1 8 ø 2 2 . 8 3 3 . 4 2 4 0 V 2 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 2 4 A 2 4 ø 2 2 . 0 X4 2 . 5 3 2 4 0 V 2 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 2 4 T 2 4 ø 2 4 . 8 × 5 4 . 8 2 4 0 V 2 A 0 2 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 3 0 A 3 0 ø 2 2 X4 9 . 8 2 4 0 V 2 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 3 0 T 3 0 ø 3 5 . 5 X6 2 . 3 2 4 0 V 2 A 0 2 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 3 6 A 3 6 ø 2 2 . 0 X5 7 . 2 2 4 0 V 2 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 3 6 T 3 6 ø 2 4 . 8 × 6 8 . 5 2 4 0 V 2 A 0 2 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 5 6 A 5 6 ø 2 5 . 0 X8 5 . 7 0 2 4 0 V 2 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 7 6 A 7 6 ø 3 5 . 5 X1 0 4 . 8 5 2 4 0 V 2 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P C - 1 2 5 1 2 5 ø 5 4 × 2 8 6 2 4 0 V 2 A 0 1 0 0 C o n t a c t u s f o r 3 D D r a w i n g

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S l i p R i n g S o l u ti o n s T E L + 8 6 - 7 5 5 - 8 2 0 4 2 2 3 5 | E m a i l | s a l e s s l i p r i n g . c n | w w w . s l i p r i n g . c n | J I N P A T E l e c t r o n i c s C o . L t d LPM SERIES T e c h n i c a l P a r a m e t e r s N u m b e r o f C i r c u i t s 1 - 3 0 c i r c u i t s o r m o r e W o r k i n g S p e e d 0 3 0 0 r m p o r h i g h e r W o r k i n g T e m p e r a t u r e -2 0℃ + 6 0℃ o r a c c o r d i n g t o s p e c i f i c r e q u i r e m e n t s W o r k i n g H u m i d i t y 6 0 R H o r h i g h e r V o l t a g e R a t i n g 2 4 0 V A C / D C C u r r e n t R a t i n g 1 2 a m p s p e r c i r c u i t o r h i g h e r D i e l e c t r i c S t r e n g t h ≥ 5 0 0 V A C 5 0 H z b e t w e e n e a c h c i r c u i t I n s u l a t i o n R e s i s t a n c e 1 0 0 MΩ 5 0 0 V D E l e c t r i c a l N o i s e 1 m Ω Mi n W i r e S i z e A W G 3 0 s i l v e r p l a t e d c o p p e r T e f l o n U L o r o t h e r w i r e s W i r e L e n g t h 2 5 0 m m O p t i o n a l H o u s i n g Ma t e r i a l E n g i n e e r i n g p l a s t i c o r m e t a l O p t i o n a l P r o t e c t i o n G r a d e I P 5 4 o r h i g h e r R e m a r k s 1 . T r a n s m i t t i n g m o r e t h a n 3 0 k i n d s o f s i g n a l s s u c h a s U S B R S L V D S C a n b u s Fi r e W i r e S D I . 2 . i n s t a l l a t i o n w a y c a n b e s e t a c c o r d i n g t o r e a l u s i n g s i t u a t i o n . ◆ O p e r a t i o n a l l i f e ≥ 5 0 0 0 0 0 0 0 r e v o l u t i o n s r e f e r e n c e ◆ T h e o p e r a t i o n a l l i f e o f t h e u n i t d e p e n d s u p o n w o r k i n g t e m p e r a t u r e r o t a t i o n s p e e d e n v i r o n m e n t a n d c o n t i n u o u s w o r k i n g l i f e . W i r e C o l o r C o d e W i r e S i z e R i n g C o l o r R i n g C o l o r R i n g C o l o r R i n g C o l o r A W G 2 8 s i l v e r p l a t e d c o p p e r T e f l o n U L 1 B L K 2 B R N 3 R E D 4 O R G 5 Y E L 6 G R N 7 B L K-B L U 8 P U R 9 G R A Y 1 0 W I T 1 1 P I N K 1 2 A Z U R Y 1 3 W I T / B L K 1 4 W I T / B R N 1 5 W I T / R E D 1 6 W I T / O R G 1 7 W I T / Y E T 1 8 W I T / G R N 1 9 W I T / B L U 2 0 W I T / P U R 2 1 W I T / G R A Y 2 2 C L A R 2 3 B L K-R E D 2 4 B L K/ B R N R e m a r k s : 1 . A W G 2 8 s i l v e r p l a t e d c o p p e r T e f l o n U L 2 4 d i f f e r e n t c o l o r s i n g l e w i r e s f o r a c i r c l e 2 . 1 f r o m r o t o r s i d e T h e c o l o r i f t h e w i r e c a n b e c h a n g e d .

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S l i p R i n g S o l u ti o n s T E L + 8 6 - 7 5 5 - 8 2 0 4 2 2 3 5 | E m a i l | s a l e s s l i p r i n g . c n | w w w . s l i p r i n g . c n | J I N P A T E l e c t r o n i c s C o . L t d LPM SERIES M o d e l C i r c u i t s O D L( m m V o l t a g e V C u r r e n t( A O p e r a t i n g S p e e d r p m D e t a i l s L P M - 0 6 G 6 ø 1 2 . 5 X1 8 . 2 2 4 0 V 2 A / w i r e 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M - 0 4 A 4 ø 1 2 . 5 X1 5 . 6 2 4 0 V 2 A / w i r e 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M - 0 6 A 6 ø 1 2 . 5 X1 8 . 2 0 2 4 0 V 2 A / w i r e 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M - 0 6 B 6 ø 1 2 . 5 X1 8 . 2 0 2 4 0 V 2 A / w i r e 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M - 0 6 C 6 ø 1 2 . 9 5 X1 8 . 2 0 2 4 0 V 2 A / w i r e 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M - 0 6 D 6 ø 1 3 X1 8 . 4 2 4 0 V 2 A / w i r e 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M - 0 6 E 6 ø 1 6 X1 7 . 2 2 4 0 V 2 A / w i r e 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M - 0 6 M 6 ø 1 2 . 5 X1 8 . 2 0 2 4 0 V 2 A / w i r e 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M - 0 6 U 6 ø 1 2 . 5 X1 8 . 2 0 2 4 0 V 2 A / w i r e 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M - 1 2 A 1 2 ø 1 2 . 5 X2 5 . 3 2 4 0 V 2 A / w i r e 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M - 1 2 B 1 2 ø 1 2 . 5 X2 5 . 5 0 2 4 0 V 2 A / w i r e 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M - 1 2 C 1 2 ø 1 2 . 5 X2 5 . 5 2 4 0 V 2 A / w i r e 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M - 1 2 D 1 2 ø 1 2 . 5 X2 5 . 5 0 2 4 0 V 2 A / w i r e 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M - 1 2 H 1 2 ø 1 2 . 4 X2 0 2 4 0 V 2 A / w i r e 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M - 1 2 M 1 2 ø 1 2 . 5 X2 5 . 3 2 4 0 V 2 A / w i r e 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M - 1 2 U 1 2 ø 1 2 . 5 X2 5 . 3 2 4 0 V 2 A / w i r e 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M - 1 8 A 1 8 ø 1 5 . 5 X4 0 2 4 0 V 2 A / w i r e 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M - 1 8 C 1 8 ø 1 2 . 8 X2 3 . 5 2 4 0 V 2 A / w i r e 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M - 2 0 B 2 0 ø 1 5 . 5 X3 5 2 4 0 V 2 A / w i r e 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M - 2 4 A 2 4 ø 1 5 . 5 X3 9 . 7 2 4 0 V 2 A / w i r e 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M - 3 0 A 3 0 ø 1 6 X3 9 . 5 2 4 0 V 2 A / w i r e 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M - 3 0 B 3 0 ø 1 6 . 0 X3 7 . 0 0 2 4 0 V 1 . 5 A / w i r e 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M - 1 2 N 1 2 ø 1 2 . 8 X2 0 . 2 2 4 0 V 2 A / w i r e 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g

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S l i p R i n g S o l u ti o n s T E L + 8 6 - 7 5 5 - 8 2 0 4 2 2 3 5 | E m a i l | s a l e s s l i p r i n g . c n | w w w . s l i p r i n g . c n | J I N P A T E l e c t r o n i c s C o . L t d LPMS SERIES T e c h n i c a l P a r a m e t e r s N u m b e r o f C i r c u i t s 1 -1 2 c i r c u i t s o r m o r e W o r k i n g S p e e d 0 3 0 0 r m p o r h i g h e r W o r k i n g T e m p e r a t u r e -2 0℃ + 6 0℃ o r a c c o r d i n g t o s p e c i f i c r e q u i r e m e n t s W o r k i n g H u m i d i t y 6 0 R H o r h i g h e r V o l t a g e R a t i n g 2 4 0 V A C / D C C u r r e n t R a t i n g 1 A e a c h o r h i g h e r D i e l e c t r i c S t r e n g t h ≥ 5 0 0 V A C 5 0 H z b e t w e e n e a c h c i r c u i t I n s u l a t i o n R e s i s t a n c e 1 0 0 MΩ 5 0 0 V D C E l e c t r i c a l N o i s e 1 m Ω Mi n W i r e S i z e A W G 3 0 T e f l o n o r o t h e r w i r e s W i r e L e n g t h 2 5 0 m m O p t i o n a l H o u s i n g Ma t e r i a l E n g i n e e r i n g p l a s t i c o r a l u m i n u m a l l o y O p t i o n a l P r o t e c t i o n G r a d e I P 5 4 o r h i g h e r R e m a r k s 1 . T r a n s m i t t i n g E t h e r n e t s u c h a s U S B R S C a n b u s Fi r e W i r e s i g n a l a n d s o f o r t h . 2 . I n s t a l l a t i o n w a y c a n b e s e t a c c o r d i n g t o r e a l u s i n g s i t u a t i o n . ◆ O p e r a t i o n a l l i f e ≥ 5 0 0 0 0 0 0 0 r e v o l u t i o n s r e f e r e n c e ◆ T h e o p e r a t i o n a l l i f e o f t h e u n i t d e p e n d s u p o n w o r k i n g t e m p e r a t u r e r o t a t i o n s p e e d e n v i r o n m e n t a n d c o n t i n u o u s w o r k i n g l i f e . W i r e C o l o r C o d e W i r e S i z e R i n g C o l o r R i n g C o l o r R i n g C o l o r R i n g C o l o r A W G 3 0 s i l v e r p l a t e d T e f l o n U L 1 B L K 2 B R N 3 R E D 4 O R G 5 Y E L 6 G R N 7 B L K-B L U 8 P U R 9 G R A Y 1 0 W I T 1 1 P I N K 1 2 A Z U R Y R e m a r k s : 1 . A W G 3 0 s i l v e r p l a t e d c o p p e r T e f l o n U L 1 2 d i f f e r e n t c o l o r f o r a c i r c l e 2 . 1 f r o m r o t o r s i d e T h e c o l o r i f t h e w i r e c a n b e c h a n g e d .

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S l i p R i n g S o l u ti o n s T E L + 8 6 - 7 5 5 - 8 2 0 4 2 2 3 5 | E m a i l | s a l e s s l i p r i n g . c n | w w w . s l i p r i n g . c n | J I N P A T E l e c t r o n i c s C o . L t d LPMS SERIES M o d e l C i r c u i t s O D L( m m V o l t a g e V C u r r e n t( A O p e r a t i n g S p e e d r p m D e t a i l s L P M S - 0 4 A 4 ø 7 . 9 X1 0 . 8 0 2 4 0 V 1 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M S - 1 0 A - 0 8 8 ø 1 0 X1 4 . 6 2 4 0 V 1 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M S - 1 0 A 1 0 ø 1 0 X1 4 . 6 2 4 0 V 1 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M S - 1 2 A 1 2 ø 1 1 . 1 2 4 2 4 0 V 1 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M S - 0 6 B 6 ø 8 . 5 X1 1 . 2 2 4 0 V 1 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M S - 1 0 B 1 0 ø 1 0 . 5 X1 3 . 6 2 4 0 V 1 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M S - 0 4 D 4 ø 7 . 9 0 1 0 . 8 0 2 4 0 V 2 A 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g L P M S - 0 4 C 4 ø 7 . 9 0 1 0 . 8 0 2 4 0 V 1 A o r h i g h e r 0 3 0 0 C o n t a c t u s f o r 3 D D r a w i n g

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