lce series www.anova-semi.com revision: a jun-25-2010 p . 1 low capacitance stand-off voltage: 6.5 to 28 v peak pulse power: 1500 w note: axial lead transient voltage suppressors features do-201 glass passivated chip 1500 w peak pulse power capability with a 10/1000 s waveform, repetitive rate (duty cycle):0.01 % low leakage excellent clamping capability very fast response time rohs compliant mechanical data case: molded plastic epoxy: ul 94v-0 rate flame retardant lead: solderable per mil-std-750, method 2026 guranteed polarity: color band denotes tvs cathode end mounting position: any maximum ratings(t a =25 unless otherwise noted) parameter symbol value unit peak power dissipation with a 10/1000s waveform (1) p pp 1500 w power dissipation on infinite heatsink at t l = 75 c(fig.2) p d 6.5 w peak pulse current wih a 10/1000s waveform(fig.2) (1) i pp see next table a operating junction and storage temperature range t j , t stg C55 to +150 c (1)non-repetitive current pulse per fig.3 and derated above t a = 25 c per fig.2 0.042 0.038 [ 1.07 0.97 ] 0.209 0.189 [ 5.30 4.79 ] min min dia. dia. dimensions : inch [ mm ] 0.375 0.285 [ 9.53 7.24 ] 1.000 [25.40] 1.000 [25.40]
lce series www.anova-semi.com revision: a jun-25-2010 p . 2 0 30 0.1 20 0.1 13 0 100 0 100 ## 0.2 10000 0.14 10000 0.1 25 100 75 100 175 25 175 0 0 0 0.2 100 0.5 76 1 50 1.5 33 2 23 3 13 4 10 ratings and characteristics curves (t a =25 unless otherwise noted) fig. 1 - peak pulse power rating curve fig. 2 - power derating curve surge current fig. 3 - pulse waveform fig. 4 - ac line protection application 0 50 100 0 1 2 3 4 peak pulse current , (% ) time , (ms) t j = 25 c pulse width (td) is defined as the point where the peak current decays to 50 % of ipp 10/1000 sec. waveform as defined by r.e.a. peak value (ipp) half value = ipp 2 td tr=10 s 0.1 1 10 100 0.1 1 10 100 1000 10000 peak pulse power,p pk , (kw) pulse width, t d ( s ) 0 25 50 75 100 0 25 50 75 100 125 150 175 percentage of rated power (%) lead temperature ,t l ( ) peak power (single pulse) t j = initial temperature power dissipation low capacitance tvs application note: device must be used with two units in parallel, opposite in polarity as shown in circuit for ac signal line protection .
lce series www.anova-semi.com revision: a jun-25-2010 p . 3 min (v) max (v) i t (ma) lce6.5 6.5 7.22 8.82 10 1000 12.3 100 100 75 1 100 lce6.5a 6.5 7.22 7.98 10 1000 11.2 100 100 75 1 100 lce7.0 7.0 7.78 9.51 10 500 13.3 100 100 75 1 100 lce7.0a 7.0 7.78 8.60 10 500 12.0 100 100 75 1 100 lce7.5 7.5 8.33 10.20 10 250 14.3 100 100 75 1 100 lce7.5a 7.5 8.33 9.21 10 250 12.9 100 100 75 1 100 lce8.0 8.0 8.89 10.90 1 100 15.0 100 100 75 1 100 lce8.0a 8.0 8.89 9.83 1 100 13.6 100 100 75 1 100 lce8.5 8.5 9.44 11.50 1 50 15.9 94 100 75 1 100 lce8.5a 8.5 9.44 10.40 1 50 14.4 100 100 75 1 100 lce9.0 9.0 10.00 12.20 1 10 16.9 89 100 75 1 100 lce9.0a 9.0 10.00 11.10 1 10 15.4 97 100 75 1 100 lce10 10.0 11.10 13.60 1 5 18.8 80 100 75 1 100 lce10a 10.0 11.10 12.30 1 5 17.0 88 100 75 1 100 lce11 11.0 12.20 14.90 1 5 20.1 74 100 75 1 100 lce11a 11.0 12.20 13.50 1 5 18.2 82 100 75 1 100 lce12 12.0 13.30 16.30 1 5 22.0 68 100 75 1 100 lce12a 12.0 13.30 14.70 1 5 19.9 75 100 75 1 100 lce13 13.0 14.40 17.60 1 5 23.8 63 100 75 1 100 lce13a 13.0 14.40 15.90 1 5 21.5 70 100 75 1 100 lce14 14.0 15.60 19.10 1 5 25.8 58 100 75 1 100 lce14a 14.0 15.60 17.20 1 5 23.2 65 100 75 1 100 lce15 15.0 16.70 20.40 1 5 26.9 56 100 75 1 100 lce15a 15.0 16.70 18.50 1 5 24.4 61 100 75 1 200 lce16 16.0 17.80 21.80 1 5 28.8 52 100 75 1 200 lce16a 16.0 17.80 19.70 1 5 26.0 57 100 75 1 200 lce17 17.0 18.90 23.10 1 5 30.5 49 100 75 1 200 lce17a 17.0 18.90 20.90 1 5 27.6 54 100 75 1 200 lce18 18.0 20.00 24.40 1 5 32.2 46 100 75 1 200 lce18a 18.0 20.00 22.10 1 5 29.2 51 100 75 1 200 lce20 20.0 22.20 27.10 1 5 35.8 42 100 75 1 200 lce20a 20.0 22.20 24.50 1 5 32.4 46 100 75 1 200 lce22 22.0 24.40 29.80 1 5 39.4 38 100 75 1 200 lce22a 22.0 24.40 26.90 1 5 35.5 42 100 75 1 200 lce24 24.0 26.70 32.60 1 5 43.0 35 100 75 1 200 lce24a 24.0 26.70 29.50 1 5 38.9 39 100 75 1 200 lce26 26.0 28.90 35.30 1 5 46.6 32 100 75 1 200 lce26a 26.0 28.90 31.90 1 5 42.1 36 100 75 1 200 lce28 28.0 31.10 38.00 1 5 50.1 30 100 75 1 200 lce28a 28.0 31.10 34.40 1 5 45.5 33 100 75 1 200 lce30a 30.0 33.30 36.80 1 1 48.4 31 100 75 1 100 lce33a 33.0 36.70 40.60 1 1 53.3 28 100 75 1 100 lce36a 36.0 40.00 44.20 1 1 58.1 26 100 75 1 100 lce40a 40.0 44.40 49.10 1 1 64.5 23 100 75 1 100 lce43a 43.0 47.80 52.80 1 1 69.4 22 100 75 1 100 lce45a 45.0 50.00 55.30 1 1 72.7 21 100 75 1 100 lce48a 48.0 53.30 58.90 1 1 77.4 19 100 75 1 100 lce51a 51.0 56.70 62.70 1 1 82.4 18 100 75 1 100 lce54a 54.0 60.00 66.30 1 1 87.1 17 100 100 1 125 lce58a 58.0 64.40 71.20 1 1 93.6 16 100 100 1 125 lce60a 60.0 66.70 73.70 1 1 96.8 16 100 100 1 125 lce64a 64.0 71.10 78.60 1 1 103.0 15 100 100 1 125 lce70a 70.0 77.80 86.00 1 1 113.0 13 100 125 1 150 lce75a 75.0 83.30 92.10 1 1 121.0 12 100 125 1 150 lce85a 85.0 94.40 104.00 1 1 129.0 12 100 125 1 150 LCE90a 90.0 100.00 111.00 1 1 146.0 10 100 125 1 150 inverse blocking leakage current iib @vwib (ma) peak inverse voltage vpib (v) part number stand-off voltage vwm (v) breakdown voltage v br @ i t maximum reverse leakage ir @vwm (ua) electrical characteristics(t a =25 unless otherwise noted) maximum junction capacitance @0 v (pf) working inverse blocking voltage vwib (v) maximum reverse surge current ipp (a) maximum clamping voltage vc @ipp
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