Zero Voltage Switch with Adjustable Ramp U217B/ U217B-FP Description The integrated circuit, U217B, is designed as a zerovoltage switch in bipolar technology. It is used to control resistive loads at mains by a triac in zero-crossing mode. A ramp generator allows to realize power control function by period group control, whereas full wave logic guarantees that full mains cycles are used for load switching. Features Direct supply from the mains Current consumption 0.5 ma Very few external components Full wave drive no dc current component in the load circuit egative output current pulse typ. 100 ma short circuit protected Simple power control Ramp generator Reference voltage Applications Full wave power control Temperature regulation Power blinking switch Package: DIP8, SO8 Block Diagram 95 10872 D 1 BYT86/800 (250 V~) R 2 (R sync ) R 1 18 k 2 W oad 1000 W C 2 2.2 F/ R 4 100 k R 5 1 Ramp generator 2 8 5 Synchronization Supply 7 GD C 1 100 F/ 16 V TIC 236 V M = 230 V~ MT2 max 15 k 100 k 3 4 + + Comparator Full wave logic Pulse amplifier 6 100 R 3 G MT1 min R 6 Reference voltage 1.25 V 58 k Figure 1. Block diagram with typical circuit, period group control 0 to 100% 1 (11)
General Description The integrated circuit, U217B, is a triac controller for the zero crossing mode. It is meant to control power in switching resistive loads of mains supply. Information regarding supply sync. is provided at Pin 8 via resistor R Sync. To avoid dc load on the mains, full wave logic guarantees that complete mains cycles are used for load switching. A fire pulse is released when the inverted input of the comparator is negative (Pin 4) with respect to the non inverted input (Pin 3) and internal reference voltage. A ramp generator with free selectable duration is possible with capacitor C 2 at Pin 2 which provides not only symmetrical pulse burst control (figure 3), but also control with superimposed proportional band (figure 10). Ramp voltage available at capacitor C 2 is decoupled across emitter follower at Pin l. To maintain the lamp flicker specification, ramp duration is adjusted according to the controlling load. In practice, interference should be avoided (temperature control). Therefore in such cases a two point control is preferred to proportional control. One can use internal reference voltage for simple applications. In that case Pin 3 is inactive and connected to Pin 7 (GD), figure 9. 95 11306 Firing Pulse Width t p, (Figure 4) This depends on the latching current of the triac and its load current. The firing pulse width is determined by the zero crossing identification which can be influenced with the help of sync. resistance, R sync, (figure 6). t p = 2 arc. sin I V M P 22 whereas I = atching current of the triac V M = Mains supply, effective P = Power load (user s power) Total current consumption is influenced by the firing pulse width, which can be calculated as follows: R sync V 2 tp M 2 sin ( 2 ) 0.6 V 49 3.5 10 5 k A t ( ms ) p 10.00 1.00 0.10 V mains = 230 V I ( ma) 1 Ramp control 200 100 50 0.01 10 100 1000 10000 96 11939 P ( W ) Figure 4. V S 2 C 2 2000 V 1 1.4 V Figure 2. Pin 1 internal network t Final voltage V min R Sync ( k ) 1600 1200 800 400 V M =230V AC T amb =25 C 7.3 V T V S(Pin5) 95 11307 Initial voltage V max 95 9978 0 0 300 600 900 1200 t p ( s ) 1500 Figure 3. Figure 5. 2 (11)
Triac Firing Current (Pulse) This depends on the triac requirement. It can be limited with gate series resistance which is calculated as follows: R Gmax 7.5 V V Gmax I Gmax I P = I Gmax T t p whereas: V G = Gate voltage I Gmax = Max. gate current I p = Average gate current t p = Firing pulse width T = Mains period duration 36 Supply Voltage The integrated circuit U217B (which also contains internal voltage limiting) can be connected via the diode (D 1 ) and the resistor (R 1 ) with the mains supply. An internal climb circuit limits the voltage between Pin 5 and 7 to a typical value of 9.25 V. Series resistance R 1 can be calculated (figures 7 and 8) as follows: R 1max = 0.85 V min V Smax ; P 2 I (R1) = (V M V S ) 2 tot 2 R 1 I tot = I S + I P + I x whereas V M = Mains voltage V S = imiting voltage of the IC I tot = Total current consumption I S = Current requirement of the IC (without load) I x = Current requirement of other peripheral components P (R1) = Power dissipation at R 1 R ( k ) 1 50 40 30 20 V Mains =230V P R1 ( W ) 6 5 4 3 2 V Mains =230V 10 1 0 0 3 6 9 12 15 0 0 3 6 9 12 15 95 10114 I tot ( ma ) 95 10116 I tot ( ma ) Figure 6. Figure 7. 3 (11)
Absolute Maximum Ratings Reference point Pin 7 Parameters Symbol Value Unit Supply current Pin 5 I S 30 ma Sync. current Pin 8 I Sync. 5 ma Output current ramp generator Pin 1 I O 3 ma Input voltages Pin 1, 3, 4, 6 Pin 2 Pin 8 Power dissipation T amb = 45 C V I V I ±V I V S 2 to V S 7.3 T b =45 C P tot 400 mw T amb = 100 C 125 Junction temperature T j 125 C Operating-ambient temperature range T amb 0 to 100 C Storage temperature range T stg 40 to + 125 C Thermal Resistance Parameters Symbol Maximum Unit Junction ambient R thja 200 K/W Electrical Characteristics V S = 8.5 V, T amb = 25 C, reference point Pin 7, unless otherwise specified Parameters Test Conditions / Pin Symbol Min Typ Max Unit Supply voltage limitation I S = 5 ma Pin 5 V S 8.6 9.25 9.9 V Supply current Pin 5 I S 500 A Voltage limitation I 8 = ± 1 ma Pin 8 ± V I 7.5 8.7 V Synchronous current Pin 8 ±I sync 0.12 ma Zero detector ±I sync 35 A Output pulse width V M = 230 V, R sync = t P 260 s R sync = 470 k 460 Output pulse current V 6 = 0 V Pin 6 I O 100 ma Comparator Input offset voltage Pin 3,4 V I0 5 15 mv Input bias current Pin 4 I IB 1 A Common mode input Pin 3,4 V IC 1 (V S 1) V voltage Threshold internal V 3 = 0 V Pin 4 V T 1.25 V reference Ramp generator, Pin 1, figure 1 Period I S = 1 ma, I sync =1 ma, C 1 = 100 F, C 2 = 1 F, R 4 = 100 k T 1.5 s Final voltage V 1 0.9 1.40 1.80 V Initial voltage 6.8 7.3 7.8 Charge current V 2 = 0 V, I 8 = 1 ma Pin 2 I 2 13 17 26 A V 4 (11)
Applications V M = 230 V ~ R oad 270 k BYT86/800 VDR 56 18 k 1.5 W 8 7 6 5 +5 V U217B CY21 1 2 3 4 56 k 47 F/ 39 k I I 1.5 ma V I 95 11308 Figure 8. Power switch 95 11309 2.2 F/ C 2 (250 V~) R 2 (R sync ) D 1 R 1 BYT86/800 18 k/ 2 W oad 1000 W R 8 470 k TC/M87 B value = 3988 R (25) 100 k R 9 150 BC237 R 6 100 k R 4 100 k R 5 1) 1 3 4 Ramp generator + 2 8 5 Comparator Synchronization Full wave logic Supply Pulse amplifier 7 6 C 1 100 R 3 V M = 230 V~ R p R 7 130 k Reference voltage 1.25 V Figure 9. Temperature control 15 to 35 C with sensor monitoring TC Sensor M 87 Fabr. Siemens R( 25 ) =100 k/b =3988 R (15) = 159 k R( 35 ) = 64.5 k R 1) 5 determines the proportional range 5 (11)
0.5... 2.2 kw 270 k BYT86/800 V M = 230 V ~ 100 nf/ 250 V ~ 82 56 18 k/ 1.5 W 8 7 6 5 U217B 1 2 3 4 150 k 110 k 47 F/ 16V 0.47 F/ 95 11310 Figure 10. Power blinking switch with f 2.7 Hz, duty cycle 1:1, power range 0.5 to 2.2 kw 6 (11)
oad 0.35... 1.5 kw R 1 510 k BYT86/800 T 14148 R 4 680 k V M = 230 V ~ R 5 R 2 680 k I H = 50 ma 62 R 3 13 k/2 W 14148 R 10 910 k 8 7 6 5 U217B 1 2 3 4 C 3 R 6 9.1 k R 7 12 k R 15 25 k R 16 R 9 12 k 10 nf TC 33 k C 1 2.2 F C 5 100 F/ 12 V C 4 47 F R 8 56 k C2 1 F 95 11311 Figure 11. Room temperature control with definite reduction (remote control) for a temperature range 5 to 30 C 7 (11)
oad/ 1000 W BYT51G V M = 230 V ~ VDR 56 18 k 1.5 W 8 7 6 5 U217B (680 k 1 2 3 4 500 k (2 M 10 nf 68 F/ 50 k (200 k TC 95 11312 Figure 12. Two point temperature control for a temperature range 15 to 30 C 8 (11)
oad/400 W V M = 230 V~ R sync 430 k 92 R 3 D 1 BYT51G R 1 18 k/ 1.5 W 8 7 6 5 U217B 1 2 3 4 TC D 2 14148 200 k R 6 27 k R 15 / 50 k 330 k R 5 R 7 / 8.2 k C 2 R 4 / 39 k C 3 33 F/ C 1 68 F/ 150 nf 95 11313 Figure 13. Two-point temperature control for a temperature range 18 to 32 C and hysteresis of ± 0.5 C at 25 C 9 (11)
Dimension in mm Package: DIP8 94 8873 Package: SO8 94 8862 10 (11)
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