25RIA120.

BLOOMFIEL FARRAN , STREETNEW NEW JERSEY 07003 www.solidstateinc.com 

## S 46BLOOMFIEL FARRAN **D** , STREETNEW 

## a 

## 1ORIA, 1G6RIA, 22RiA, 2S5RIA SERIES 25A,35A And 40A RMS Glass-passivated 

## SCRs 

## el Major Ratings and Characteristics Description/Features 

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[storia<br>| teria | 22R1A | 25RIA | Units The RIA series of silicon controlled rectifiers<br>ianav) eefo [ea] degianed for medium power switching<br>@mate |e |e | e5 | es | | and4% phase controlaoe applications.ct ay vation {<br>ism @50Hz | 190 | 285 | 335 | 350 | New and improved glass passivation for<br>high reliability and exceptional stability<br>@6oHz | 200 | 300 | 355 | 370 | at high temperatures.<br>eee fe | TE me | = 100V through 1200V<br>@soHz | 165 | 375 | 515 | 560 | = Integral TO-208AA package<br>favvat_ [100 | 100 | 100 | 100 | V/us | = High di/dt and dv/dt capabilities<br>faire | 200 | 200 | 200 | 200 | Avs |<br>range .<br>16.51<br>(0.650)<br>MAX.<br>: 7.62 (0.300)<br>'oo | \ 6.85 (0.270)<br>Ap(0.563)MAX. CM)NYSE<br>3.81<br>1.53 (0.150)<br>(0.060)MIN. | HN:<br>30.30 pia. CO<br>(1.193) [Il 12.00<br>MAX. 12.82—, ). (0.472)<br>. MAX. CTTtT 4 DIA.<br>10.7211.50 (0.422)(0.453) Hitoy<br>| \ 1/4-28UNF-2A<br>Conforms to JEDEC OUTLINE TO-208AA (TO-48)<br>Dimensions in Millimeters and (Inches)<br>**----- End of picture text -----**<br>


## 10RIA, 16RIA, 22RIA, 25RIA Series 

|VOLTAGE RATINGS (Applied gate voltage zero or negative):|VOLTAGE RATINGS (Applied gate voltage zero or negative):|VOLTAGE RATINGS (Applied gate voltage zero or negative):|VOLTAGE RATINGS (Applied gate voltage zero or negative):|VOLTAGE RATINGS (Applied gate voltage zero or negative):|||
|---|---|---|---|---|---|---|
||||VRRM|VoRM|VRSM|IRM. OM|
||Part Number||Max. Rep. Peak | Max. Rep. Peak<br>Reverse Voltage |Off-State Voltage<br>(Vv)<br>(V)|||Max. Non-Rep. Peak |<br>Reverse Voltage<br>(Vv) tp < 5ms|Max. Peak Reverse and<br>Off-State Leakage Current<br>(ma)@)|
|TORIA1O||16RIA10<br>|22RIA10||25RIA10|100|100|150|20|
|JORIA20||16RIA20<br>|22RIA20||25RIA20|200|200|300|10|
|1ORIA40||16RIA40<br>}22RIA40||25RIA40|400|400|500|10|
|1OR!IA6O||16RIA6O<br>|22RIAGO||25RIA60|600|600|700|10|
|1O0RIA80||16RIA80<br>|}22RIA80||25R1A80|800|800|900|10|
|10R1A100|16R1A100 |22R1A100|25R1A100|||1000|1000|1100|10|
|10R1A120]16R1A120|22R1A120/25R1A120|||1200|1200|1300|10|



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ELECTRICAL SPECIFICATIONS<br>Pftorts | rt [22 | 25818<br>ON-STATE<br>ITiAv) Max. average on-state current 25 Tc = 85°C, half sine wave, 180° conduction<br>) | 0 | A<br>[Tc] [=] [60°C]<br>| ie | 22 | - | - 1ORIA, Max Tc = 51°C: [16RIA,]<br>13 Ta = 459C, half sine wave, K3 sink<br>A natural cooling, 180° conduction<br>12.5 Ta = 459C, rectangular wave K3 sink<br>A natural cooling, 120° conduction<br>ITSM Max. peak one cycle, non- ‘ 50Hz, Initial Ty = 125°C<br>repetitive surge current 190 285 335 350 A 100% rated Va py reapplied<br>with rated reverse voltage<br>appliedi followingi surge 225 335 390 395 A 50Hz, Initialitial TyT) == 45°C450<br>100% rated VaR reapplied<br>200 | 300 | 355 | 370 a | BOH2, InitialInitial Ty Ty= = 1250COC<br>100% rated Vary reapplied<br>240 350 410 A 60Hz, Initial— Ty mT.)= 45°C .<br>100% rated Vapi reapplied<br>Max. peak one cycle, non- 50Hz, Initial Ty = 125°C<br>repetitive surge current 225 340 400 | 420 A no voltage reapplied<br>with no reverse voltage - —<br>following surge 270 395 470 A 50Hz, Initial Ty = 45°C<br>no voltage reapplied<br>240 | 360 | 420 a | SOH2,Hz, InitialInitial T)Ty  == 125°C<br>no voltage reapplied<br>280 480 A 60Hz, InitiInitial Ty =4545°C<br>no voltage reapplied<br>121 Max. 12t capability, for a2 t= 10ms, Initial Ty = 125°C<br>fusing 180 405 S| 100% rated Vari reapplied<br>t= 10ms, Initial Ty = 45°C<br>255 555 755 780 A2s | 100% rated Vern reapplied<br>165 2 t = 8.3ms, Initial Ty = 125°C<br>375 ASs 100% rated Vary reapplied<br>235 2 t = 8.3ms, Initial Ty = 45°C<br>720 A“s | 100% rated VaR reapplied<br>**----- End of picture text -----**<br>


10RIA, 16RIA, 22RIA, 25RIA Series 

## ELECTRICAL SPECIFICATIONS (Continued) 

||ON-STATE (Continued)|||||||||
|---|---|---|---|---|---|---|---|---|---|
|12¢|Max. !2t capability,for<br>individual device fusing|||||||a2, |t= Sms, InitialTy = 125°C<br>5<br>no voltage reapplied||
||||255|555|755||780|2<br>Ass|t = Sms, Initial Ty = 45°C<br>no voltage reapplied|
|||||220|305||335|A2s|=1.<br>Initial Ty<br>=<br>Cc<br>t=<br>1.5ms,<br>Initia<br>. j=<br>125<br>no voltage reapplied|
|||||303|||425|a2,|=1.<br>InitialTy = 45°C<br>|i<br>Toms<br>Initial<br>Ty<br>no voltage reapplied|
|27|Max. 124/ t capability, for<br>individual device fusing|(@)|2550|{5740|{7930|||8670|A24/s|t= 0.1 — 10ms, no voltage reapplied,<br>initial Ty = 125°C.||
|Vt™|Max. peak on-state voltage||1.75|||||Vv|Ty = 25°C, 180° conduction<br>IT(AV) = 10A (32A peak)|
|||||1.75||||Vv|Ty = 25°C, 180° conduction|
||||||||||IT(AV) = 16A (50A peak)|
|||||||1.70||V|Ty = 25°C, 180° conduction|
||||||||||ITiAV) = 22A (70A peak)|
||||||||1.70|Vv|Ty = 25°C, 180° conduction|
||||||||||IT(AV) = 25A (79A peak)|
|IH|Max. holding current|||||||mA|Anode Supply = 6V, resistive load,|
||||||||||gate open, initial If = 1A|
|di/dt|Max. rate of rise of|||||||||
||turned-on current|||||||||
||Vor = <600V||||200|||Alus||
||BLOCKING|||||||||
|dv/dt min.|Critical rate-of-rise of||||||||Ty = 125°C. Exponential to 100% rated|
||off-state voltage||||300|7||V/us|VoRM:-<br>Ty = 125°C. Exponential to67%rated|
||||||||||VDRM-|
||TRIGGERING|||||||||
|+IGm|Max. peak positive gate|||||||A||
||current|||||||||
|-VGM|Max. peak negative gate|||||||Vv||
||voltage|||||||||
|IGT|Max. required DC gate current<br>to trigger ‘©)|||||||mA|Anode supply = 6V, resistive load,<br>Ty = -659C|
|||||||||Anode supply = 6V, resistive load,<br>mA | Ty = 25°C||
||||||||||Anodesupply=6V,resistiveload,|



## 1ORIA, 16RIA, 22RIA, 25RIA Series 

## ELECTRICAL SPECIFICATIONS (Continued) 

||TRIGGERING (Continued)|||||||
|---|---|---|---|---|---|---|---|
|VoT|Max. required DC gate voltage<br>to trigger®||3.0|||Vv|Anode supply = 6V, resistive load,<br>Ty = -65°C|
||||2.0|||Vv|Anode supply = 6V, resistive load,<br>Ty = 25°C|
||||1.0|||Vv|Anode supply = 6V, resistive load,<br>Ty = 125°C|
|VGD|Max. DC gate voltage not to||0.2|||V|Ty = 125°C|
||trigger ®||||||Vorm= rated value|
|eto)|Max. DC gate currentnot to<br>trigger||2.0|||mA|Ty = 125°C, Vp py = rated value|
||SWITCHING|||||||
|ter|Typical reverse recovery|||||Us|Ty = 125°C @)|
||time|||||||
|THERMAL-MECHANICAL SPECIFICATIONS||||||||
|Ty|Operating junction||-65 to|125||oc||
||temperature range|||||||
|RthJC|Max. thermal resistance,<br>junction to case|1.85|1.15|0.86|0.75||degC/W|DC<br>operation||
|Rthcs|Max. thermal resistance,<br>case to sink||0.35|||degC/W|Mounting surface smooth, flat and greased||
|||||||Ibf -in.||
|||20(27|5)||||Lubricated threads and|
|||0.23(.32)|||||(non-lubricatedthreads)|



## NOTES 

©) At rated Vaam. VoRM Ty = 125°C. ‘o) 12t for time ty = 2/t- vty. 

® From 0.67 rated Von Ty = 125°C. Peak gate current = 0.5A, rise time 1 us, pulse duration at least 6 us. 300 pulses at 50 or 6O Hz. It = (2x rated di/dt)A. Per JEDEC Standard RS-397, 5.2.2.6. ® Max. required gate current to trigger is lowest value which will trigger all units under conditions shown. 

® Max. required gate voltage to trigger is lowest value which will trigger all units under conditions shown. ® Max. gate voltage not to trigger is the maximum value that will not trigger any unit under the conditions shown. ® Gatetm =currentrated ly= ay)200m4A,for riseat leasttime2000.5 us,us, din/dtpulse duration= —10A/us.at least 6 us, Vo = 0.5 rated Vorpy Resistive circuit. ltuM= 0.1 x IT(AV): ® tm = rated IT (av) for at least 200 us duration, dip/dt = —10A/us. Minimum reverse voltage during turn-off = 100V, reapplied dv/dt = 20V/us exponential to 0.67 Voryy- Gate bias: UV, 1002. For M6 threads add ‘'M" to code, e.g., 1GRIA40M. ©) The following values of tg= 10 us up to 6OOV and 30 us up to 1200V are available on special request. 

10RIA, 16RIA, 22RIA, 25RIA Series 

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10RIA Series<br>20 1 D vy, SUSUR :<br>= DIN K3 Se deg<br>to)¥ 1 Ty = 125°C :| waeCOGANWIS x3 AN KES4We#2 ons  |]| | 34or | c/w/8<br>2 A<br>LTTs YaU7 ROSSAESS GL PeTEES4<br>. 10 Ws q PN. IN =< hs Hh NS<br>5 MF NISRA<br>3 Pe] *<br>a74 SESSASSESSSN |B oe<br>=<‘TA4 YZ Conduction‘Tee. CURVESDIN HEATSINKS FOR SPECIFIC ARE SeSS\WWN S  WE<br>< 0 4g Angle ANDFOR 180° NATURALCONDUCTION COOLING P SSS\'=<br>0 1 2 3 4 5 6 7 8 9 10 10 20 30 40 50 60 70 80 90 100 110 125<br>AVERAGE ON-STATE CURRENT (FULL CYCLE) -—A MAXIMUM PERMISSIBLE AMBIENT TEMPERATURE — °C<br>Fig. 1 — Continuous Current Rating Nomogram<br>(Phase Angle Controlled Half-Sinusoidal Waveforms,<br>50—400 Hz), 10RIA Series.<br>s 30 CONTINUOUS 7 NX \] FS<br>n| RMS LIMIT / N\ Vo= aReg<br>8 25 \ 7 NY NJ [|<br>wy —— on x11 a4 c/w<br>LVL a | 44 DIN K3 sg<br>P3 Sea<br>el 20 Z| Wa 4 Z| BN N WI AAT |<br>pat< C. |SSRNay LEE<br>let [VJ]<br>Lik VACA | SSIS RS fe [eae<br>TBS To BREST Th<br>PL Ae) UL RRR<br>tow ee eS NNN<br>i 0 |A2 4 6 8 10 12 14 16hase,10 20 30 40 50| |60 70[SSMS80 90 100110 125 [5]<br>AVERAGE ON-STATE CURRENT (FULL CYCLE) — A ’ MAXIMUM PERMISSIBLE AMBIENT TEMPERATURE- °C<br>Fig. 2 — Continuous Current Rating Nomogram<br>(Rectangular Waveforms, 50—400 Hz), 10RIA Series.<br>@) To determine required heatsink thermal resistance (Rinsa) in deg C/W use value of AR appropriate to conduction angle stated in table<br>and substitude in formula Ry,SA = X — AR, e.g. for 1ORIA at 180° conduction angle, 7.6A, and 60°C ambient temperature<br>RtnSA = 3 — 0.42 = 2.58 deg. C/W (figs, 1 & 2)<br>**----- End of picture text -----**<br>


1ORIA, 16RIA, 22RIA, 25RIA Series 

## 10RIA Series 

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” aL a<br>Boo4 a Stroma TT<br>= , mensy//Ae z tt A<br>Bozs ee SS oer!-_ °o A<br>a” Ay poet a 30° iy 8° PEPt Ht [HR] Oe 389 tt<br>wi 5 way, SEETSETS 60° Sw 8 IES 60° manne<br>BOras) 4 Hy is 90° Ht <2 FTAe EIT 90° LOTT<br>eg 2 WY | Tr zoe Bey EySS aoe<br>83 COD/A 83, ge| 1H veo 1 Tht<br>c 5 Gs / Ollie meee mmeense x 5 ne, eo I te maeaees<br>w — ye er, coon mar;Y aat —iiee HHH eto<br>< Att ‘ HH < +H ani mantic =H<br>? | CONTROLLED RECTIFIER e " UT 2 CONTROLLED! | \! RECTIFIER aay Ti<br>TURNED FULLY ON Conduction Angle aul TURNED FULLY ON 4 Conduction Angle inl<br>1 2 5 10 2 5 107 2 5 10? 1 2 5 10 2 5 107 2 5 103<br>AVERAGE ON-STATE CURRENT (FULL CYCLE) - A AVERAGE ON-STATE CURRENT (FULL CYCLE) - A<br>Fig. 3 — Maximum High Level On-State Power Loss Fig. 4 — Maximum High Level On-State Power Loss<br>Vs. Average On-State Current Vs. Average On-State Current<br>(Sinusoidal Current Waveform), 10RIA Series (Rectangular Current Waveform) 10RIA Series<br>°©wiwom130 TT | tt |<br>2 120 \NG aye A 2 pj tT tT PT PP<br>< ol We Yo 1. av ofa | eer<br>Ccw \\ GFML 120°120° fh/\ wave <| === t+ +—= p+}a.oe0eeee<br>g N ALL | at wave 5 ftpT yp=aPa Popae tJ<br>100 \) TZ 7 180°" /\ wave 5 Pot<br>wn \\WNBZC AS 2 Eero ERA<br>- WS Me eeeceee seneeeeees<br>w ' 0 a A a re<br>Z 0 Wa “t SSpee ys0eee000n08<br>z AVAL _| | ft o — (==<br><7 x7 : 2). sas<br>4zof | UAVKX / | TE 3|g Jee<br>SC= 40 IMEbeeoc TT) 2 jf titecseecce e yietcoer<br>x | iit t tt itt<br>< a Se See a ae ae ee<br>= 30 z 5 aSA2Aeaee eee ee<br>0 10 20 30 40 50 0 04 O08 1.2 16 20 24 28 3.2 3.6<br>AVERAGE ON-STATE CURRENT (FULL CYCLE) —A INSTANTANEOUS ON-STATE VOLTAGE — V<br>**----- End of picture text -----**<br>


Fig. 5 — Average On-State Current Vs. Maximum Allowable Case Temperature (Rectangular and Sinusoidal Current Waveform, 50—400 Hz), 10RIA Series. 

Fig. 6 — Maximum Instantaneous On-State Voltage Vs. Instantaneous On-State Current, 10RIA Series 

10RIA, 16RIA, 22R1A, 25R1A Series 

10RIA Series 

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LO ce sees ene oa ene eon a eeeeeemes comes ee oe a a 9 eee ee e es a a 9 ee er ee ae ee ee ee<br>p<br>SSpoSS RE A SSetee SSHsSS ssEH EF02 00 EEee FE]ee<br>A F—Rectangular;  gategaveppuise ~—+}PTT+ ee eee<br>> (a) Recommended load line for LTT NErT TTT<br>;<br>(b) rated di/dt : 10V, 209, t,=0.5us,t, 2 6ms i INS prs 0 Baill<br>2& 10 Recommended< 30% rated di/dt:load line10V,659,t,=for 15,6, > 6us +Pme SN Gy PYG 9<br>> Pt tt  44#4$$ st FR Oy Gr Ge<br>@ 4paTeSSeSCTTG b wy -e CPP<br>Fa A NNNONS SN YNas %, Lad<br>3 iH by at %<br>PL eae TI TIN TTT PON ONS Ne ONS ll<br>5 | a lS = SN<br>g AT = DN TIN<br>a ! — eee PE BES =. eet<br>=c Py CsesEsa  GeAeees a a eeeeee aaaTtBaana nNay6 fo}8 a SeSsPeer0es ee1rr2 TTT2 20Frequencyeeeelimitedeeeebyee Paiayy eee<br>eT] [ttt ft I<br>P T TT eine sianTTTTT<br>1 A EE TTPE<br>103 4 10°? 4 10" 4 1 4 10 4 10?<br>Instantaneous Gate Current — A<br>Fig. 7 — Gate Characteristics, 1ORIA Series<br>102 <= cSSst Sa SSsss a cS oSss a ae eset a a assess) ons as as asaes sss}<br>5 FAERR SESSot<br>2 CrCOCCICCTee eee<br>Yr  =6©f dT [} ow C OLTr ITe eee<br>5S= opt ||_|| ATrated ANY vagyRATED APPLieoLOAD CONDITION FoLLowincsurce AND WITH || Sg23 105 SSassiitesaceiteeeasiiinessretinamassie=== HHR ESR SeeSaatsees<br>3Sx—] INAWa ET TE ETTTTT[|| geaz2x , 2 [|SCOOTCOCCIRON eeerrrSeer ian. eirt<br>nm22o¢ 150aNee oo1S) 9 COCCTNITa APeeCCCIse|<br>wo>a r | NNTS TTTTE TE ET LLL TTT ESre io PE eTP,TT)Coo<br>3 TC Sta b Z 10 PY<br>~— Pot SEANPo aaaeager<br>85 r | [ [ | OYi“ Bani wae? ann 00 2 SN SSS SSS Sela waswasess<br>woq Yr [| f Lil foe———ESS L | ETT qt23 CoCOCCIeee<br>(«0 Tr | | Pitti Tt Fem oF 102EEE<br>ny¥ LT Ty eet SOR St ERECTSERSTinEEeeiinemnatia<br>Pr ee ee COCO<br>1.0 2ee4 6 8 10 20 40 60 ECC10°2HHI10°3 TTT10°ECE 1071 CI 1 ErTt10 102<br>NUMBER OF EQUAL AMPLITUDE HALF CYCLE CURRENT PULSES (N) SQUARE WAVE PULSE DURATION (SECONDS)<br>Fig. 8 — Maximum Non-Repetitive Surge Current Fig. 9 — Maximum Transient Thermal Impedance,<br>Vs. Number of Current Pulses, 10RIA Series Junction-to-Case Vs. Pulse Duration,<br>10RIA Series<br>**----- End of picture text -----**<br>


10ORIA, 16RIA, 22RIA, 25RIA Series 

| 

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16RIA Series<br>= 30 .<br>Bosos LEIA AYAASNDANLZ A JIN» NJ " EL ELTUT 5. | deg<br>< TALK K | NAY NP i<br>ra Ty = 125°C /| / J, x Nw x nH DIN K5 6s @<br>5 20 LL Nt at KS pot | 82<br>: VVY NOONE <A°<br>. 15 toe — aWA Ne ISK Ne<br>C27" ‘ “~<br>AGL =—7Z SENSNAT TE<br>> a<br>TG SSS<br>SLA | | Bae =SSNG<br>x AB, Angle FOR 180° CONDUCTION WN t<br>$ 4 ANDO NATURAL COOLING |<br>00 2 4 6 8 10 12 14 16 10 20 30 40 50 60 70 80 90 100 110 125<br>AVERAGE ON-STATE CURRENT (FULL CYCLE) — A MAXIMUM PERMISSIBLE AMBIENT TEMPERATURE — °C<br>Fig. 10 — Continuous Current Rating Nomogram (Phase Angle Controlled Half-Sinusoidal Waveforms,<br>50—400 Hz), 16RIA Series.<br>3B2 40 JeRIA.. AV LALENqT ELE<br>2 26 RMS LIMIT ; 7 | J \ 2 an<br>© LSA TSN NN | fetta|] eg ew<br>30 7 7 v, Wa NN NEE DIN KS 82 @)<br>SL PK RAT LLL)<br>COOGAN SAT he<br>AEEcL i200 SMZ0ZEEE sSe7<oS Net TOE180 | 0.15<br>rfESS: “a oe AeCZEBPSSneNONQKY eee120 | 0.26<br>:SCORSESEYAR ae. SNE<br>| WA SSRSSSAA Poe<br>0 5 10 15 20 25 10 20 30 40 50 60 70 80 90 100110 125<br>AVERAGE ON-STATE CURRENT (FULL CYCLE) — A MAXIMUM PERMISSIBLE AMBIENT TEMPERATURE - °C<br>Fig. 11 — Continuous Current Rating Nomogram (Rectangular Waveforms, 50—400 Hz), 16 RIA Series.<br>w 0ee ee Nn 7/7)<br>= {LA Ly) hh<br>g pee er De<br>33 =o Hin PP a ss = Saeces tae 22026 Seat oe eeess<br>ana tt eaert Sapo ttt @ PpA RS SEY<br>ie Pt Vamaus 30° thy some e1//7ameet 30° 4<br>LAER 908<br><0 so eeestte7/aeettioct Cenetiin ta Yer ee<br>hoz+ > ma meNtt Ami 120° - | TTT+H BS<0 5 YESYim tu 120° +44ll<br>53on a wyMWCC| | (Ty 180°COTTTT ss$3 4 LO yroy Wye nee DC3S mash<br>< P| FH ++ +H Fre Oo pa Et EE<br>fo t+ rts Ry HH<br>w 5 OAH Hott +++ cro 5 4 Yea mmanece<br>z AAAS// QUnttitHme M a atinelez ||TT AAT7/7 oe oT Tta eei MBeneisCT TT<br>CONTROLLED Te Pot,<br>RECTIFIER | Conduction Angle nil CONTROLLED RECTIFIER Conduction Angle 777<br>1 2 5 10 2 5 107 2 5 10? 1 2 5 10 2 5 107 2 5 10?<br>AVERAGE ON-STATE CURRENT (FULL CYCLE) - A AVERAGE ON-STATE CURRENT (FULL CYCLE) - A<br>Fig. 12 — Maximum High Level On-State Power Loss Fig. 13 — Maximum High Level On-State Power Loss<br>Vs. Average On-State Current Vs. Average On-State Current<br>(Sinusoidal Current Waveform), 16RIA Series (Rectangular Current Waveform)<br>**----- End of picture text -----**<br>


@) See page A-13 for note. 

10RIA, 16RIA, 22RIA, 25RIA Series 

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16RIA Series<br>rs)vale130 T<br>ooh Tere I<br>ANGRY ACLOlasasauae>2-<br>- [WSS] y. bo° 2 Nave « wp tit} | | | | | |Pere<br>t-@S [ol] N S|NI FY 120° ‘\ wavewave | am==t{—+—t—}Tt t+ [—ta a hort|rs es eeaant— —=<br>mya100 KN Z Ws 120°oO Jl wave bE ATa re es re es ee ee ee<br>NZ 1882 AA ave” 28<br>ZINNZZ 4 a<br>F 30 WRN > 8 Ati ye rr<br>4 Ween w ?{4 ney<br>° 80 KVKAN SPR F< wot itil Ii tt| | | ti | |tt |<br>92Sot 6070 |IAATXYLN NE1 93°4 seeptasrtesTTssTeyFestteetTeePtee eePPee ee ee eeAYeee eeeTTJ<br>szt |ULETE |) ec<br>2= 4050 il I i Foc | £e7 ttt“Preysaier fel ttTTTttt TTPtt TTtt TTry<br>o-¢ ane aeeeee<br>s 30 5 Ct<br>SCCUINHITT0 10 20 30 TT)?40 50 (ESS0 0.4 0.8EE1.2 Saase1.6 2.0 eae2.4 2.8 3.2 3.6<br>AVERAGE ON-STATE CURRENT (FULL CYCLE) — A INSTANTANEOUS ON-STATE VOLTAGE — V<br>Fig. 14 — Average On-State Current Vs. Maximum Fig. 15 — Maximum Instantaneous On- State Voltage Vs.<br>Allowable Case Temperature (Rectangular and Sinu- Instantaneous On- State Current, 16RIA Series<br>soidal Current Waveform, 50—400 Hz), 16R1A Series.<br>10? Se See on Se SS eae a Sao tae ER Re sees Gee Ena Selle——— a oesasl<br>p— 25 ee ee ee<br>> 4 [Rectangular(a) Recommendedgate pulseload line [PPTeeefor  PtLTTTE | NUEeee rTelTTT<br>&| 10 (b) ratedRecommended< 30%di/dtrated: 10V,di/dt: load 209, line10V,659,t,=1s,6,26ys fort, = 0.5ys, ty 2 6ys NII+PNININ <[SeBreaoe MSty,aCG Baaiil|Loy<br>> Pp SSeS Cy s> WY ~e LEP<br>2 gf eesCNS so NOS eg INO6 COT<br>8 pf ee OS a NO? f 2s, > aman<br>3 Hf te[— MAATTPONS NS oN o~ il<br>PLer oe c Mel | | mn, DSBs4<br>a4e—_F Totti iT to p> =a HH Ht} —H Frequency limited by Pgvay) 7<br>PotPET TT sheerime Lev TTeiI<br>io" OO|<br>10°3 4 10°? 4 10" 4 1 4 10 4 10?<br>Instantaneous Gate Current — A<br>Fig. 16 — Gate Characteristics, 1GRIA Series<br>**----- End of picture text -----**<br>


10RIA, 16RIA, 22RIA, 25RIA Series 

16RIA Series 

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10? SSS<br>Paced EESESSE<br>2 iiisawaiiiiatasiiiiaamatiiimesiimamaail<br>2 300 AT ANY RATED LOAD CONDITION ANO WITH 23s SenetFREERmamsii SSaei Se Seiteestes<br>4 We | 9 oO TEL aU aNmOHAI( CON mOGts)(ONGOnMEGitCOMmRMUETIil<br>bof< eT7 rer)Bs SORERRERS<br>Ss2Hz=22 200 SS>be ——— ueBSesssiiiit=10 SSeSCOC caistaiiiintaiiiimansniiatanaiTTee<br>5  SS See<br>ve 100TTL 2x 2 2 CoCoECre<br>Seo)= 2 CESESS ee mereitt Se meeei Se serite eerieoesiit<br>e op1.0fT|2 [TTTTTP4 6 8 10 tttt20 tTtT 40tytntii60 1310422 CoEECCCCI84932 C Ao CECOconeeSygp22 Sygi2rr5 1 Tec2 5 yqQ2OCee5 492<br>NUMBER OF EQUAL AMPLITUDE HALF CYCLE CURRENT PULSES (N) SQUARE WAVE PULSE DURATION (SECONDS)<br>Fig. 17 — Maximum Non-Repetitive Surge Current Fig. 18 — Maximum Transient Thermal Impedance,<br>Vs. Number of Current Pulses, 1GRIA Series Junction-to-Case Vs. Pulse Duration, 16RIA Series<br>22RIA Series<br>Ptem 40 \<br>AN Is} IN g<br>| ToT ENNALTE<br>a 38 CONTINUOUS “1/7 Y BA DINK1.1 5 be<br>= 0 ; Ay 14 Re SL IN| oieIN KI 33° c/w<br>2 3) 17) WT<br>° 25 CASES| COREE<br>os: 30° - Ab | a Ze 4“a<br>S|BS.: Ne: REN NS NS [ie ove<br>i LL ZA ms IN % ;<br>o 15 - L, rd - —_ = Ro > i.<br>> > bs Re N<br>BLi YZ \_ | [RERSSSSSAN] TT fo<br>85=  7105 se £ cngeee/ a Peegunvespth | ron sPecirc —SSeS S NNGIEIEA<br>7= ° onduction es. i.EI<br>0 4 8 12 16 20 22 10 20 30 40 50 60 70 80 90 100110 125<br>AVERAGE ON-STATE CURRENT (FULL CYCLE) — A MAXIMUM PERMISSIBLE AMBIENT TEMPERATURE — °C<br>Fig. 19 — Continuous Current Rating Nomogram (Phase Angle Controlled Half-Sinusoidal Current<br>Waveforms, 50—400 Hz), 22RIA Series.<br>2rot 55 zn] | | | | AAq TE ET Tf<br>ge 50 Z IN 9 AR<br>3 45 | | | | | r7RIXTd TTT TT TTT 8.a4 | c/wles<br>aee Ne)<br>| | |<br>et 0.C. BLLb7Z| Z| | BNDZZannuel,.C,<br>& N NBZZea lee [o |<br>Sof: lieso " AZ A | oR) ON KS 4+Ss tt tw<br>to Sa<br>iy es BPRS EF] fost<br>8 oy | an nsSET  asNST% 120<br>A Z| PS ><br>awa SESS Toten<br>n/n CET~4R  ESSSE SNOT<br>LG SR ol<br>> 0|77_5 |10 |15 |20 25 30 35woireeseesotee10 20 30 40 50[|60 70[TP80 90 SSSSSQL100 110 125 2° | 074<br>AVERAGE ON-STATE CURRENT (FULL CYCLE) — A MAXIMUM PERMISSIBLE AMBIENT TEMPERATURE — °C<br>Fig. 20 — Continuous Current Rating Nomogram (rectangular Waveforms, 50—400 Hz), 22RIA Series.<br>**----- End of picture text -----**<br>


1ORIA, 16RIA, 22RIA, 25RIA Series 

## 22RIA Series 

**==> picture [500 x 529] intentionally omitted <==**

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n” BER eo SE th 2 oe279,74 ee<br>BLee eRON Te0 ee oree eee,8 22 RATTmn Ltt ////AAAAS tr<br>Stor [L,] Bw747A s/s ose ||ase Hey coo<br>t+ #¥—_ 1} ee Po 2 a SS ES a GD SS ww<br>wi 8 OT ATS coo Pt we 8a 602 oy ti<br>E>b WH) PTE 120 ° EeEE 9 mann WY) ng in<br>“or 2 Ed) A woe TTT z2 me ge te aaniil<br>we to Ll mnnilt we 10 Eee) Zee mer esses:<br>= ee P< te sass<br>w 5 ee 7/// eee ee ee mmenees & 5 Ps CroCeoreotn rooty<br>w e740 manele [|Ae meeeee<br>a mn’ 26 ' fH ig yty nt<br>» CETTE. TT “2 ain tect | LT<br>CONTROLLEDTURNED FULLY RECTIFIER ON  + Conduction Angle +++}il Bal TURNED FULLY ON} Conduction Angle tT<br>1 2 5 10 2 5 107 2 5 103 1 2 5 10 2 5 107 2 5 10?<br>AVERAGE ON-STATE CURRENT (FULL CYCLE) - A AVERAGE ON-STATE CURRENT (FULL CYCLE) - A<br>Fig. 21 — Maximum High Level On-State Power Loss Fig. 22 — Maximum High Level On-State Power Loss<br>Vs. Average On-State Current Vs. Average On-State Current<br>(Sinusoidal Current Waveform), 22RIA Series ( Rectangular Current Waveform) 22RIA Series<br>° 22 RIA...<br>©0130weso L P|| | | Tf ;<br>Sof 120 IS Pasian. TT OTT ETT]<br>Et10 WW EE SSee00>7.00080<br>RS) PO se oe oe os es a<br>NN ti saa oaaae<br>a: 100 SOE SON 5 5CA<br>RNIN 2 Ae<br>: 8 ACEH<br>ZotoT)|ONYN || (2 oeeee)/ Seer<br>a TULA er [fee |) ge LEE<br>< 70 et — 60° 1S. wave Se ae a ss a ee<br>z ail mm 120° | /\ wave || oe A SF A<br>S 60 | Hoo 120° | 1. wave g Tt AR + A<br>aZeof | If Uf [+ — 180°reels]| /\" wave | 5 Ceert Hi rrrPPtT TT<br>2 1 ||<br>x<br>Zoo.ao ohIIE-UTTPe 2Bo CCreNA [Cee]<br>fr) 10 20 30| | 40| | 50 |? 0 RRR04 08 SRE1.2 16 20 24RRR28 3.2 3.6<br>AVERAGE ON-STATE CURRENT (FULL CYCLE) — A INSTANTANEOUS ON-STATE VOLTAGE — V<br>**----- End of picture text -----**<br>


Fig. 23 — Average On-State Current Vs. Maximum Allowable Fig. 24 — Maximum Instantaneous On-State Voltage Case Temperature (Sinusoidal Current Waveform, Vs. Instantaneous On-State Current, 22RIA Series 50 to 400 Hz), 22RIA Series 

10RIA, 16RIA, 22RIA, 25RIA Series 

## 22RIA Series 

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10? F——— FF oo<br>===... See Se eel<br>SS NS NS Se 8 8 0 ee ee eea<br>4 | Rectangulargular gategate pulsepulse Ft+11 + {+ +--+ +H 4} oto<br>>2, (a)(b) ratedRecommendedRecommended di/dt : 10V,loadload 209,lineline t,forfor = O0.5us, th 26ys ENNIN N N <Tpreslo hy aGC Baillalll<br>g 10 < 30% rated di/dt: 10V,659,1,= 15,6, > 64s + Pepe Gy, BA?=<br>g ee ee ee a NS bs S¢ EH<br>2 4 PHa 0 eeENee SHESe NG;oN IN b Y“¢ Ivo.-e CEPCOO<br>8 } ff BR EE ES %y NS eo) > st<br>o<br>3 Wey DNANG NS ll<br>|5 SCTo NaI CASSMy. » q |<br>=2 F E-PEe AAt pFE 88 ESoeSSSEH<br>SEEes ifgt | SE ° }—Ear+ oHTr Pn intra<br>eetRail=a ll<br>10°3 4 10°? 4 10" 4 1 4 10 4 10?<br>Instantaneous Gate Current — A<br>Fig. 25 — Gate Characteristics 22RIA Series<br>400 fT AT ANY RATED LOAD CONDITION AND WITH: 10 FE<br>5 LT [|_| ate Vp pay APPLIED FOLLOWING SURGE SSSstrti SE mSet Seermseaiitsaesiieeaeri<br>é a as areiiii Samet semecti Soest mSemeriseeesiii<br>s g EECCre<br>2 we NOET) 2 Ere<br>Sw aw 2 ia<br>ww> PSS= Ln25 10! Co maraeree1! Conn<br>2 ~ $+ mea aii om seoes ee ascicocctiiiicdeeaiiisemtniimemniiiimeestia GS Ws 8 0 9 es Oa Ma Os Os A a ss |<br>a ele LET eS TT See Ht<br>= Ht EE Be ee<br>Hj [Pi]<br>pt__| TTT Tt ft ttt ith 103COLLIE<br>1.0 2 4 6 8 10 20 40 60 1042 54932 Syg22 Syqt2 5 1 2 5 yg 2 5 492<br>NUMBER OF EQUAL AMPLITUDE HALF CYCLE CURRENT PULSES (N) SQUARE WAVE PULSE DURATION (SECONDS)<br>Fig. 26 — Maximum Non-Repetitive Surge Current Fig. 27 — Maximum Transient Thermal Impedance,<br>Vs. Number of Current Pulses, 22RIA Series Junction-to-Case Vs. Pulse Duration, 22RIA Series<br>25RIA Series<br>[35] Z| aN h z<br>[2] ae| T TT TTT EAXMNUNITT TT TT<br>3 CONTINUOUS \/ NeZ= DINK. Foal 4R<br>SERERESCCEARUNUNZ<4ennel<br>2 -PAAA | | SX] Se P| 821 ©<br>SL|  BSEESA |_| ONBA SENNSEA Net efor<br>CS sSNA TT<br>ro} 15 A La ~ — MS +> 4 N-%<br>7240 POSES<br>£ey2 ZR105 hg Gz Conduction; FOR 180°[OES CONG jemiakei a SeahS\NNG Ss II<br>eq WA Angle AND NATURAL COOLING SN<br>0 5 10 16 20 25 10 20 30 40 50 60 70 80 90 100 110 125<br>AVERAGE ON-STATE CURRENT (FULL CYCLE) — A MAXIMUM PERMISSIBLE AMBIENT TEMPERATURE - °C<br>**----- End of picture text -----**<br>


Fig. 28 — Continuous Current Rating Nomogram (Phase Angle Controlled Half-Sinusoidal Waveforms, 50—400 Hz), 25RIA Series. 

10RIA, 16R1A, 22RIA, 25RIA Series 

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25RIA Series<br>7 60[rat | | ot ft | KET ETT tT ttt tt ie an<br>6gt | | | [| | | JANET TTTTT Tg. em<br>2 50 pt SR ep %s, eelB DIN KIA i 22o2 | ©<br>a.LpE D.C.10° LZx, | Z| — <P S444XAeeC.<br>rez3 OZ60°© POOOKG4 aepryTy= 125°C aSS TORaS eS SkIN  SEEa fon]<br>w /aALLL) CESSESpart Sb cs aNINCL [oa<br>PAE L ParOSSTTP oe<br>> i AND NATURAL COOLING Sh<br>0 5 10 15 20 25 30 35 40 10 20 30 40 50 60 70 80 90 100110 125<br>AVERAGE ON-STATE CURRENT (FULL CYCLE) — A MAXIMUM PERMISSIBLE AMBIENT TEMPERATURE — °C<br>Fig. 29 — Continuous Current Rating Nomogram (Rectangular Waveforms, 50—400 Hz), 25RIA Series.<br>BRASLi eBf PARTNLA<br>53 TAA CTI etter tae tT<br>Be 10" SH AA s3 1"ee Ae ett<br>a EETnae SRStT MVALP TAT go o HHT 2°wit PEErt VALAgape HeTE sos HH<br>HA$3no, = 2 reAyTT [Tee] Ah vATT TTCEH. 120°sooCl° TTT rE2,nV 2 CesTSRS //ve  7I, Aei, 4 eRe=o 180° mneeHH<br>FSR OVS © 10<br>w | TT VATee, mma. ee 7 dee ess mmeanee<br>z | | TAT Te ' TTT z Lg YO tT MmBaeal<br>2- MAUICONTROLLED RECTIFIERITi;+ Conduction Angleth TTT 2 ||P7 TURNEDcontrouteo FULLY RECTIFIER ON + Conductionk- —AngleHuil<br>1 2 5 10 2 5 107 2 5 10? 1 2 5 10 2 5 10? 2 5 10?<br>AVERAGE ON-STATE CURRENT (FULL CYCLE) - A AVERAGE ON-STATE CURRENT (FULL CYCLE) - A<br>Fig. 30 — Maximum High Level On-State Power Loss Vs. Average Fig. 31 — Maximum High Level On-State Power Loss Vs.<br>On-State Current (Sinusoidal Current Waveform), 25RIA Series Average On-State Current (Rectangular Current Waveform)<br>Foor‘SS |PTT TT). 2 beer TA<br>NNq NG ———————aa SS22 == === ===<br>Sofa 110 INRA| NN SSS TT | BsPeeeA Ceeeeeeeeeeet<br>2 ot100 |IANNNSNINN i I co)a eeeee) eeeeeeeeeeee<br>S | ==) SSS<br>O 80 I ° a<br>eCCOIPNENS C) § «EEEEG SSS<br>aL@ LEEE se: | fee} 38sFEE<br>Soot 70 PERT See fn nave a a 8<br>g | | HH [oe] 2 Cee COC<br>2x2vot60HUET1 UTRie== 180°| |" /\|e)Fee‘wave 8z aeJEESTHEB|| re TTERRtT PTR EEReT Th ERTT E S<br>3 30 FLL TEER EEL 0 04INSTANTANEOUSO08 12  ON-STATE16 20  VOLTAGE24 28 — V32 36<br>0AVERAGE10ON-STATE20CURRENT30 (FULL CYCLE)40 —A50 Fig.Vs. 33Instantaneous— MaximumOn-StateInstantaneousCurrent,On-State25RIA VoltageSeriest<br>Fig. 32 — Average On-State Current Vs. Maximum Case<br>Temperature (Rectangular and Sinusoidal Current<br>Waveform, 50—400 Hz), 25RIA Series.<br>**----- End of picture text -----**<br>


10RIA, 16RIA, 22RIA, 25RIA Series 

## 25RIA Series 

**==> picture [487 x 473] intentionally omitted <==**

**----- Start of picture text -----**<br>
10?PEaS Se<br>4 [— Rectangular gate pulse +--+ HHH} 4} Ht 4}<br>5 [Le Recommende sioasi gi rd ioadi. n e o e LTT| NITaA<br>i}2 10 " recom rated divat - TOV. 65 ,1,= 15,6,LT > 6us WISAU A  NDSeotis,% hon N LTT=——soase<br>SESE eS 2G go<br>2 4Pe ti Nee Noy Ye 6 CH<br>8$s ATTS No RRSeo AS SaNNTNs<br>| Coe ms NS NLS l<br>Fy Te a8<br>s TSS<br>E =F—-eFEEHHanaes c=+f FopH SE<br>io"‘FEPe menenSaReeeneneecreH PEESE=a F e arenia| oirml ova<br>103 4 ill10°? 4 10" 4el1 4 10 4 10?<br>Instantaneous Gate Current — A<br>Fig. 34 — Gate Characteristics, 25RIA Series<br>102 Somass a acsiacmmaasiiaa ease SSSsstSe Sees<br>400 6BEES<br>rf EECICT<br>KTP | 2 RE TTICET  oo et<br>AS  PR AT ANYED Vag RATED APPLIED LOAD CONDITIONFOLLOWING SURGE ANO WITH i BOZs BeasiicSsiieesessiisemassTTT eT<br>5 eases eeaaesis<br>ra NeeSI | BS83 CSROSSSoC<br>zaB Os[Sa SoIk {COICOTdeet<br>25 ot)Slee 2g= oeSao atera aecccam anens wereete | am mam marndsean alums anaacdtiausasouresasa staramimamanaravse|<br>Gozes [TF PTT feo) 28)<> (SoeeGSeo eeeanne tess)<br>=2 a el r Saat SSS SSSesi SSSsltiSsSascaee e<br>i 100 ed Semati BERESTBSmaTiiimaaatimemerinineaasn<br>= ee JaueillSoedHliBtMatiiismelitimemtiiiimeestul<br>9 | oT TET PP TTT 103 CELI TH<br>1.0 2 4 6 8 10 20 40 60 1042 54932 Syq22 Syg12 5 y 2 5 yg 2 5 492<br>NUMBER OF EQUAL AMPLITUDE HALF CYCLE CURRENT PULSES (N) SQUARE WAVE PULSE DURATION (SECONDS)<br>**----- End of picture text -----**<br>


Fig. 35 — Maximum Non-Repetitive Surge Current Vs. Number of Current Pulses, 25RIA Series 

Fig. 36 — Maximum Transient Thermal Impedance, Junction-to-Case Vs. Pulse Duration, 25RIA Series