Part Number Hot Search : 
UT54ACS P18CA 1N400 18000 VM1A1 34283G2 KP110 E1A102MR
Product Description
Full Text Search
 

To Download TPD4151K Datasheet File

  If you can't view the Datasheet, Please click here to try to view without PDF Reader .  
 
 


  Datasheet File OCR Text:
  tpd 4151k 2014 - 04- 0 7 1 toshiba intelligent power device high voltage monolithic silicon power ic tpd 4151k the tpd 4151k is a dc brushless motor driver using high - voltage pwm con trol. it is fabricated using a high - voltage soi process. the device contains pwm circuit, 3 - phase decode logic, level shift high - side driver, low - side driver, igbt outputs, frds, over - current and under - voltage protection circuits, and a thermal shutdown ci rcuit. it is easy to control a dc brush less motor by applying a signal from a motor controller and a hall amp/ hall ic to the tpd 4151k . features ? high voltage power side and low voltage signal si de terminal are sepa rated. ? bootstrap circuit s give simple high - side supply. ? bootstrap diode s are built in. ? pwm and 3 - phase decoder circuit are built in. ? outputs rotation pulse signals. ? 3 - phase bridge output using igbts. ? frds are built in. ? incorporating over - current and under - voltage protection, and thermal shutdown. ? package: 26 - pin dip . ? compatible with hall amp input and hall ic input. this product has a mos structure and is sensitive to electrostatic discharge. when handling this product, ensure that the environment is protected against electrostat ic discharge. hdip26 - p- 1332 - 2.0 0 weight : 3.8 g (typ.) start of commercial production 2013 - 01
tpd 4151k 2014 - 04- 0 7 2 pin assignment marking tpd4123k lot code. (weekly code) part no. (or abbreviation code) tpd 4151k country of origin
tpd 4151k 2014 - 04- 0 7 3 block diagram under - voltage protect - ion under - voltage protect - ion under - voltage protect - ion low - side driver pwm 3- ph ase distribution logic thermal shutdown over - current protection level shift high - side driver triangular wave 6 v regulator v cc v reg hu+ hv+ hw+ v s r ref os is2 is1 gnd v bb u v w 11 10 3 4 5 6 14 13 12 17 24 23 18 21 25 26 20 1/16 bsu 7 bsv bsw hall amp 22 hu - hv - hw - fr 8 fg 9 rs 15 under - voltage protection 2
tpd 4151k 2014 - 04- 0 7 4 pin descri ption pin no. symbol pin description 1 gnd ground pin. 2 hu+ u- phase hall amp signal input pin. (hall ic can be used.) 3 hu- u- phase hall amp signal input pin. (hall ic can be used.) 4 hv+ v - phase hall amp signal input pin. (hall ic can be used.) 5 hv - v - phase hall amp signal input pin. (hall ic can be used.) 6 hw+ w - phase hall amp signal input pin. (hall ic can be used.) 7 hw - w - phase hall amp signal input pin. (hall ic can be used.) 8 fr forward /reverse selection pin. 9 fg rotation pulse output p in. 10 v reg 6 v regulator output pin. 11 v cc control power supply pin. 12 os pwm triangular wave oscillation frequency setup pin. (connect a capacitor to this pin.) 13 r ref pwm triangular wave oscillation frequency setup pin. (connect a resistor to thi s pin.) 14 v s speed control signal input pin. (pwm reference voltage input pin.) 15 rs over current detection pin. 16 gnd ground pin. 17 bsu u- phase bootstrap capacitor connecting pin. 18 u u- phase output pin. 19 nc unused pin, which is not connected to the chip internally. 20 is1 igbt emitter/frd anode pin. 21 v v - phase output pin. 22 bsv v - phase bootstrap capacitor connecting pin. 23 v bb high - voltage power supply input pin. 24 bsw w - phase bootstrap capacitor connecting pin. 25 w w - phase output pin. 26 is2 igbt emitter/frd anode pin.
tpd 4151k 2014 - 04- 0 7 5 internal circuit diagrams i nternal circuit diagram of hu+, hu - , hv+, hv - , hw+, hw - input pins i nternal circuit diagram of v s pin i nternal circuit diagram of fg pin i nternal circuit diagram of rs pin i nternal circuit diagram of fr pin v cc hu+, hu - , hv+, hv - , hw+, hw - , 4 k 2 k 19.5 v to internal circuit v cc v s 4 k 19.5 v to internal circuit 25 k 225 k 250k to internal circuit fg f r 4 k 2 k 19.5 v v cc v reg 200k to internal circuit rs 4 k 202 k 19.5 v to interna l circuit v reg 5pf 200 k v cc
tpd 4151k 2014 - 04- 0 7 6 timing chart note : hall amp input logic high (h) refers to h *+ > h*-. ( *:u / v / w ) truth table hall amp input u phase v phase w phase fr hu hv hw high side lo w side high side low side high side low side fg h h l h on off off on off off l h h l l on off off off off on h h h h l off off on off off on l h l h l off on on off off off h h l h h off on off off on off l h l l h off off off on on off h h l l l o ff off off off off off l h h h h off off off off off off l l h l h off on on off off off h l h l l off on off off on off l l h h l off off off on on off h l l h l on off off on off off l l l h h on off off off off on h l l l h off off on off off on l l l l l off off off off off off l l h h h off off off off off off l note : hall amp input logic high (h) refers to h *+ > h*-. (*: u / v / w ) hu hv hw vu vv vw fg output voltage hall amp input rotation pulse
tpd 4151k 2014 - 04- 0 7 7 absolute maximum ratings (ta = 25 c) characteristics symbol rating unit power supply voltage v bb 250 v v cc 20 v output current (dc) i out 1 a output current (pulse) i out p 2 a input voltage (except v s ) v in - 0.5 to v reg + 0.5 v input voltage (only v s ) v v s 8.2 v v reg current i reg 50 ma fg voltage v fg 20 v fg current i fg 20 ma power dissipation (tc = 2 5c ) p c 23 w operating junction temperature t jop r - 40 to 135 c junction temperature t j 150 c storage temperature t stg - 55 to 150 c in case that the ic is erroneously connected to 200 vac power supply , it can withstand a voltage of up to 315 v for 1 min under t he condition of v s < 1.1 v. note: using continuously under heavy loads (e.g. the application of high temperature/current/voltage and the significant change in temperature, etc.) may cause this product to decrease in the reliability significantly even if the operating conditions (i.e. operating temperature/current/voltage, etc.) are within the absolute maximum ratings and the operating ranges. please design the appropriate reliability upon reviewing the toshiba semiconductor reliability handbook (handl ing precautions/ derating concept and methods ) and individual reliability data (i.e. reliability test report and estimated failure rate, etc).
tpd 4151k 2014 - 04- 0 7 8 electrical characteristics (ta = 25 c) characteristics symbol test condition min typ. max unit operating po wer supply voltage v bb D 50 141 185 v v cc D 13.5 15 17.5 current dissipation i bb v bb = 185 v duty cycle = 0 % D D 0.5 ma i cc v cc = 15 v duty cycle = 0 % D 2.0 10 i b s (on) v bs = 15 v, high side on D 210 470 a i b s (off) v bs = 15 v, high side off D 200 415 hall amp in put sensitivity vhsens(ha) D 50 D D mv p-p hall amp input current ihb (ha) D - 2 0 2 a hall amp common input voltage cmv i n (ha) D 0 D 8 v hall amp hysteresis width ' v in (ha) D 8 30 62 mv hall amp input voltage l h vlh(ha) D 4 15 31 hall amp input voltage h l vhl(ha) D - 31 - 15 - 4 output saturation voltage v c e sat h v cc = 15 v , i c = 0.5 a , high side 2.1 2.8 v v c e sat l v cc = 15 v , i c = 0.5 a , low side 2.1 2.8 frd forward voltage v f h i f = 0.5 a , high side 2.1 2.7 v v f l i f = 0.5 a , low side 2.1 2.7 bsd forward voltage v f (bsd) i f = 500 a 0.8 1.2 v pwm on - duty cycle pwmmin D 0 % pwmmax D 100 pwm on - duty cycle, 0 % vv s 0 % pwm = 0 % 1.7 2.1 2.5 v pwm on - duty cycle, 100 % vv s 100 % pwm = 100 % 4.9 5.4 6.1 v pwm on - duty voltage range vv s w vv s 100 % ? vv s 0 % 2.8 3.3 3.8 v output all - off voltage vv s off output all off 1.1 1.3 1.5 v regulator voltage v reg v cc = 15 v , i reg = 30 ma 5 6 7 v speed control voltage range v s D 0 6.5 v fg output saturation voltage v fgsat v cc = 15 v , i fg = 5 m a 0.5 v current control voltage v r D 0.46 0.5 0.54 v current control delay time dt D 4.5 6.5 s thermal shutdown temperature tsd D 135 185 c thermal shutdown hysteresis ' tsd D 50 c v cc under - voltage protection v cc uvd D 10 11 12 v v cc under - voltage protection recovery v cc uvr D 10.5 11.5 12.5 v v bs under - voltage protection v bs uvd D 9 10 11 v v bs under - voltage protection recovery v bs uvr D 9.5 10.5 11.5 v refresh operating on voltage t rfon refresh operation on 1.1 1.3 1.5 v refresh opera ting off voltage t rfoff refresh operation off 3.1 3.8 4.6 v triangular wave frequency f c r = 27 k , c = 1000 pf 16.5 20 25 khz output - on delay time t on v bb = 141 v , v cc = 15 v , i c = 0.5 a 1.8 3 s output - off delay time t off v bb = 141 v , v cc = 15 v , i c = 0.5 a 1.4 3 s frd reverse recovery time t rr v bb = 141 v , v cc = 15 v , i c = 0.5 a 200 ns
tpd 4151k 2014 - 04- 0 7 9 application circuit example 3- phase distribution logic under - voltage protec t- ion under - voltage protec t- ion low - side driver pwm thermal shutdown over - current protection level shift high - side driver triangular wave 6 v regulator r ref os 23 26 20 hall amp 22 fr fg 15 v cc v reg hu+ hv+ hw+ v s is 2 is 1 gnd v bb u v w r 2 c 4 rotation pulse speed instruction bsu c 6 c 5 15 v r 1 m bsv bsw r 3 c 1 c 2 c 3 24 18 25 1/16 2 3 4 5 6 7 11 8 10 9 14 17 21 13 rs under - voltage protection under - voltage protec t- ion c c r r c c c r 12 r
tpd 4151k 2014 - 04- 0 7 10 external parts typical external parts are shown in the following table. part typica l purpose remarks c 1 , c 2 , c 3 25 v/2.2 f bootstrap capacitor (note 1) r 1 0.62 1 % (1 w) current detection (note 2) c 4 25 v /1000 pf 5 % pwm frequency setup (note 3) r 2 27 k 5 % pwm frequency setup (note 3) c 5 25 v/10 f control power supply stability (note 4) c 6 25 v /0.1 f v reg p ower supply stability (note 4) r 3 5.1 k fg pin pull - up resistor (note 5) note 1: the required bootstrap capacitance value varies according to the motor drive conditions. although the ic can operate at above the v bs undervoltage level, it is however reco mmended that the capacitor voltage be greater than or equal to 13.5 v to keep the power dissipation small . the capacitor is biased by v cc and must be sufficiently derated accordingly. note 2: the following formula shows the detection current: i o = v r y r 1 (v r = 0.5 v typ.) do not exceed a detection current of 1 a when using the ic. note 3: with the combination of c 4 and r 2 shown in the table, the pwm frequency is around 20 khz. the ic intrinsic error factor is around 10 % . the pwm frequency is broadly expre ssed by the following formula. (in this case, the stray capacitance of the printed circuit board needs to be considered.) f c = 0.65 y { c 4 u (r 2 + 4.25 k )} [hz] r 2 creates the reference current of the pwm triangular wave charge/discharge circuit. if r 2 is set too small it exceeds the current capacity of the ic internal circuits and the triangular wave distorts. set r 2 to at least 9 k . note 4: when using the ic, adjustment is required in accordance with the use environment. when mounting, place as close to the base of the ic leads as possible to improve noise elimination. note 5: the fg pin is open drain. if the fg pin is not used, connect to the gnd. note 6: if noise is detected on the input signal pin, add a capacitor between inputs . note 7: a hall de vice should use an indium antimony system. i t recommend that the peak hall device voltage should set more than 300mv. handling precautions (1) when switching the power supply to the circuit on/off, ensure that v s vv s off (all igbt outputs off). at that time, either the v cc or the v bb can be turned on/off first. note that if the power supply is switched off as described above, the ic may be destroyed if the current regeneration route to the v bb power supply is bloc ked when the v bb line is disconnected by a relay or similar while the motor is still running. (2) the ic has a forward/reverse rotation control pin (fr). to change the rotation direction, switch the fr pin after the motor is stopped in the state that the v s voltage is lower than or equal to 1.1 v. when the fr pin is switched while the motor is rotating, the following malfunctions may occur. a shoot - through current may flow between the upper arm and lower arm in the output stage (igbt) at that moment when t he motor is switched. an over current may flow into the area where the over current protection circuit cannot detect it. (3 ) the triangular wave oscillator circuit, with externally connected c 4 and r 2 , charges and discharges minute amounts of current. ther efore, subjecting the ic to noise when mounting it on the board may distort the triangular wave or cause malfunction. to avoid this, attach external parts to the base of the ic leads or isolate them from any tracks or wiring which carries large current. (4 ) the pwm of this ic is controlled by the on/off state of the high - side igbt. (5 ) if a motor is locked where v bb voltage is low and duty is 100 % , it may not be possible to reboot after the load is released as a result of the high side being on immediately prior to the motor being locked. this is because, over time, the bootstrap voltage falls, the high - side voltage decrease protection operates and the high - side output becomes off. in this case, since the level shift pulse necessary to turn the high side on cannot be generated, reboot is not possible. a level shift pulse is generated by
tpd 4151k 2014 - 04- 0 7 11 either the edge of a hall sensor output or the edge of an internal pwm signal, but neither edge is available due to the motor lock and duty 100 % command. in order to reboot after a lock, the high - side power voltage must return to a level 0.5 v (typ.) higher than the voltage decrease protection level, and a high - side input signal must be introduced. as a high - side input signal is created by the aforementioned level shift pulse , it is possible to reboot by reducing pwm duty to less than 100 % or by forcing the motor to turn externally and creating an edge at a hall sensor output. in order to ensure reboot after a system lock, the motor specification must be such that maximum dut y is less than 100 %. description of protection function (1) over - current protection the ic incorporates an over - current protection circuit to protect itself against over current at startup or when a motor is locked. this protection function detects voltage g enerated in the current - detection resistor connected to the rs pin. when this voltage exceeds v r (= 0.5 v typ.), the high - side igbt output, which is on, temporarily shuts down after a delay time, preventing any additional current from flowing to the ic. th e next pwm on signal releases the shutdown state. (2) under - voltage protection the ic incorporates under - voltage protection circuits to prevent the igbt from operating in unsaturated mode when the v cc voltage or the v bs voltage drops. when the v cc power s upply falls to the ic internal setting v cc uvd (= 11 v typ.) , all igbt outputs shut down regardless of the input. this protection function has hysteresis. when the v cc power supply reaches 0.5 v higher than the shutdown voltage ( v cc uvr ( = 11 . 5 v typ.) ) , the ic is automatically restored and the igbt is turned on/off again by the input. when the v bs supply voltage drops v bs uvd (= 10 v typ.), the high - side igbt output shuts down. when the v bs supply voltage reaches 0.5 v higher than the shutdown voltage (v bs uvr (= 10.5 v typ.) ) , the igbt is turned on/off again by the input signal. (3) thermal shutdown the ic incorporates a thermal shutdown circuit to protect itself against excessive rise in temperature. when the temperature of this chip rises to the internal set ting tsd due to external causes or internal heat generation, all igbt outputs shut down regardless of the input. this protection function has hysteresis ? tsd ( = 50 c typ.). when the chip temperature falls to tsd ? tsd, the chip is automatically restored and the igbt is turned on/off again by the input. because the chip contains just one temperature - detection location, when the chip heats up due to the igbt for example, the distance between the detection location and the igbt (the source of the heat) can cause differences in the time taken for shutdown to occur. therefore, the temperature of the chip may rise higher than the initial thermal shutdown temperature . duty on over - current setting value pwm reference voltage duty off t off t on t on d elay time over - current shutdown retry triangle wave output current
tpd 4151k 2014 - 04- 0 7 12 description of bootstrap capacitor charging and its capacitance the ic uses bootstrapping for the power supply for high - side drivers. the bootstrap capacitor is charged by turning on the low - side igbt of the same arm (approximately 1/5 of pwm cycle) while the high - side igbt controlled by pwm is off. (for ex ample, to drive at 20 khz, it takes approximately 10 s per cycle to charge the capacitor.) when the v s voltage exceeds 3.8 v (55 % duty), the low - side igbt is continuously in the off state. this is because when the pwm on - duty becomes larger, the arm is s hort - circuited while the low - side igbt is on. even in this state, because pwm control is being performed on the high - side igbt, the regenerative current of the diode flows to the low - side frd of the same arm, and the bootstrap capacitor is charged. note th at when the on - duty is 100 %, diode regenerative current does not flow; thus, the bootstrap capacitor is not charged. when driving a motor at 100 % duty cycle, take the voltage drop at 100 % duty (see the figure below) into consideration to determine the c apacitance of the bootstrap capacitor. capacitance of the bootstrap capacitor = current dissipation (max) of the high - side driver u maximum drive time /( v cc ? v f (bsd) + v f (frd) ? 13.5 ) [f] v f (bsd) : bootstrap diode forward voltage v f (frd) : first re covery diode forward voltage consideration must be made for aging and temperature change of the capacitor . v s range igbt operation a both high and low - side off. b charging range. low - side igbt refreshing on the phase t he high- side igbt in pwm . c no charging range. high - side at pwm according to the timing chart . low - side no refreshing. safe operating area note: the above safe operating area s are at tj = 135 c (figure 1) . 1.4 0 185 peak winding current (a) power supply voltage v bb (v) figure 1 soa at tj = 135 c 0 low - side on duty cycle 80 % c triangular wave duty cycle 100 % (v s : 5.4 v) high - side duty on pwm reference voltage duty cycle 55 % (v s : 3.8 v) duty cycle 0 % (v s : 2.1 v) vvsoff (v s : 1.3 v) gnd b a
tpd 4151k 2014 - 04- 0 7 13 current dissipation i cc (ma) frd forward voltage v f l (v) junct ion temperature t j ( c) v cesat h C t j igbt saturation voltage v cesat h (v) junction temperature t j ( c) v cesat l C t j igbt saturation voltage v cesat l (v) junction temperature t j ( c) v f h C t j frd forward voltage v f h (v) junction temperature t j ( c) v f l C t j control power supply voltage v cc (v) i cc C v cc control power supply voltage v cc (v) v reg C v cc regulator voltage v reg (v) 1.2 ? 50 3.2 2.8 2.4 2.0 1.6 0 50 100 150 i c = 700 ma i c = 500 ma i c = 300 ma v cc = 15 v 150 i c = 700 ma i c = 500 ma i c = 300 ma ? 5 0 3.2 2.8 2.4 2.0 1.6 0 50 100 v cc = 15 v 1.2 1.6 ? 50 0 50 100 150 2.0 2.4 2.8 i f = 700 ma i f = 500 ma i f = 300 ma 2.2 2.6 1.8 150 ? 50 0 50 100 i f = 700 ma i f = 5 00 ma i f = 300 ma 1.6 2.0 2.4 2.8 2.2 2.6 1.8 1.0 12 3.0 1.5 2.0 2.5 14 16 18 t j = ? 40c t j =25 c t j =135 c 18 5.0 12 5.5 6.0 6.5 14 16 7.0 t j = ? 40c t j =25 c t j =135 c i reg = 30 ma
tpd 4151k 2014 - 04- 0 7 14 output - off delay time t off ( s) output - on delay time t on ( s) t off C t j 0 3.0 1.0 2.0 ? 50 0 50 100 150 v bb = 141 v v cc = 15 v i c = 0.5 a high - side low - side t on C t j ? 50 0 50 100 150 0 3.0 1.0 2.0 under - voltage protection operating voltage v bs uv (v) under - voltage protection operating voltage v cc uv (v) junction temperature t j ( c) t on C t j junction temperature t j ( c) junction temperature t j ( c) v s C t j pwm on - duty set - up voltage v s (v) junction temperature t j ( c) v cc uv C t j junction temperature t j ( c) v bs uv C t j junction temperature t j ( c) v r C t j current control operating voltage v r (v) v bb = 141 v v cc = 15 v i c = 0.5 a high - side low - side ? 50 0 50 100 150 0 6.0 2.0 4.0 v s 100% v s w v s 0% v cc = 15 v ? 50 0 50 100 150 12.5 10.0 12.0 10.5 11.5 11.0 v cc uvd v cc uvr v bs uv C t j ? 50 0 50 100 150 11.5 9.0 11.0 9.5 10.5 10.0 v bs uvd v bs uvr v r C t j ? 50 0 50 100 150 1.0 0 0.8 0.2 0.6 0.4 v cc = 15 v
tpd 4151k 2014 - 04- 0 7 15 i bs (off) C v bs turn - on loss w ton ( j) control power su pply voltage v bs (v) i bs (on) C v bs current dissipation i bs (on ) ( a) control power supply voltage v bs (v) current dissipation i bs ( off ) ( a) junction temperature t j ( c) v f (bsd) C t j bsd forward voltage v f (bsd) (v) junction temperature t j ( c) turn - off loss w toff ( j) junction temperature t j ( c) w toff C t j w ton C t j hall amplifier hysteresis width dvi n (ha) (mv) junction temperature t j ( c) dv in (ha) C t j 50 12 450 150 250 350 14 16 18 t j = ? 4 0 c t j =25 c t j =135 c 18 50 12 150 250 350 14 16 450 t j = ? 40c t j =25 c t j =135 c 0.6 ? 50 0 50 100 150 0.7 0.8 0.9 1.0 i f = 700 a i f = 500 a i f = 300 a 10 ? 50 60 50 40 30 20 0 50 100 150 0 ? 50 25 20 15 10 5 0 50 100 150 i c = 700 ma i c = 500 ma i c = 300 ma 0 ? 50 10 8 6 4 2 0 50 100 150 i c = 300 ma i c = 500 ma i c = 700 ma
tpd 4151k 2014 - 04- 0 7 16 test circuits igbt saturation voltage (u - phase low side) frd forward voltage (u - phase low side) 1 gnd 2 hu+ 3 hu - 4 hv+ 5 hv - 6 hw+ 7 hw - 8 fr 9 fg 10 v reg 17 bsu 18 u 19 nc 20 is1 21 v 22 bsv 23 v bb 24 bsw 25 w 26 is2 vm 2.5 v hu+ = 0 v hv+ = 5 v 0.5 a 1000 pf 27 k 11 v cc 12 os 13 r ref 14 v s 15 rs 16 gnd vm 0.5 a 1 gnd 2 hu+ 3 hu - 4 hv+ 5 hv - 6 hw+ 7 hw - 8 fr 9 fg 10 v reg 11 v cc 12 os 13 r ref 14 v s 15 rs 16 gnd 17 bsu 18 u 19 nc 20 is1 21 v 22 bsv 23 v bb 24 bsw 25 w 26 is2 hw+ = 0 v v cc = 15 v v s = 6.1 v
tpd 4151k 2014 - 04- 0 7 17 v cc current dissipation regulator voltage vm 27 k 1000 pf v cc = 15 v 30 ma 1 gnd 2 hu+ 3 hu - 4 hv+ 5 hv - 6 hw+ 7 hw - 8 fr 9 fg 10 v reg 11 v cc 12 os 13 r ref 14 v s 16 gnd 17 bsu 18 u 19 nc 20 is1 21 v 22 bsv 23 v bb 24 bsw 25 w 26 is2 15 rs im v cc = 15 v 27 k 1000 pf 1 gnd 2 hu+ 3 hu - 4 h v+ 5 hv - 6 hw+ 7 hw - 8 fr 9 fg 10 v reg 11 v cc 12 os 13 r ref 14 v s 15 rs 16 gnd 17 bsu 18 u 19 nc 20 is1 21 v 22 bsv 23 v bb 24 bsw 25 w 26 is2
tpd 4151k 2014 - 04- 0 7 18 output on/off delay time (u - phase low side) input( hv+ ) im t on t off 10 % 10 % 90 % 90 % im 27 k 1000 pf 2.5 v hu+ = 0 v hv+ = pg hw+ = 0 v v cc = 15 v v s = 6.1 v u = 141 v 282 2.2 f 1 gnd 2 hu+ 3 hu - 4 hv+ 5 hv - 6 hw+ 7 hw - 8 fr 9 fg 10 v reg 11 v cc 12 os 13 r ref 14 v s 15 rs 16 gnd 17 bsu 18 u 19 nc 20 is1 21 v 22 bsv 23 v bb 24 bsw 25 w 26 is2
tpd 4151k 2014 - 04- 0 7 19 pwm on - duty setup voltage (u -phase high side) note: sweeps the v s pin voltage and monitors the u pin. when output is turned off from on, the pwm = 0 %. when output is full on, the pwm = 100 %. vm 27 k 1000 pf 2.5 v hu+ = 5 v hv+ = 0 v hw+ = 0 v v cc = 15 v v s = 6.1 v 0 v 2 k 15 v v bb = 18 v 1 gnd 2 hu+ 3 hu - 4 hv+ 5 hv - 6 hw+ 7 hw - 8 fr 9 fg 10 v reg 11 v cc 12 os 13 r ref 14 v s 15 rs 16 gnd 17 bsu 18 u 19 nc 20 is1 21 v 22 bsv 23 v bb 24 bsw 25 w 26 is2 0 v 6.1 v
tpd 4151k 2014 - 04- 0 7 20 v cc under voltage protection operat ing /recovery volta ge (u - phase low side) note: sweeps the v cc pin voltage from 15 v and monitors the u pin voltage. the v cc pin voltage when output is off defines the under - voltage protection operating voltage. also sweeps from 6 v to increase. the v cc pin voltage when output is on defines the under voltage protection recovery voltage. v bs under - voltage protection operati ng /recovery voltage (u -phase high side) note: sweeps the bsu pin voltage from 15 v to decrease and monitors the v bb pin voltage. the bsu pin voltage when output is off defines the under voltage protection operating voltage. also swe eps the bsu pin voltage from 6v to increase and change the hu pin voltage at 5v 0v 5v each time. it repeats similarly output is on. t he bsu pin voltage when output is on defines the under voltage protection recovery voltage. vm u = 18 v 2 k 27 k 1000 pf 6 v 15 v v cc = 15 v 6 v v s = 6.1 v 2.5 v hu+ = 0 v hv+ = 5 v hw+ = 0 v 1 gnd 2 hu+ 3 hu - 4 hv+ 5 hv - 6 hw+ 7 hw - 8 fr 9 fg 10 v reg 11 v cc 12 os 13 r ref 14 v s 15 rs 16 gnd 17 bsu 18 u 19 nc 20 is1 21 v 22 bsv 23 v bb 24 bsw 25 w 26 is2 vm 2.5 v hu+ = 5 v hv+ = 0 v hw+ = 0 v v cc = 15 v v s = 6.1 v 2 k v bb = 18 v 6 v 15 v 27 k 1000 pf 1 gnd 2 hu+ 3 hu - 4 hv+ 5 hv - 6 hw+ 7 hw - 8 fr 9 fg 10 v reg 11 v cc 12 os 13 r ref 14 v s 15 rs 16 gnd 17 bsu 18 u 19 nc 20 is1 21 v 22 bsv 23 v bb 24 bsw 25 w 26 is2 bsu = 15 v 6 v
tpd 4151k 2014 - 04- 0 7 21 current control operating vo ltage (u -phase high side) note: sweeps the is/r s pin voltage and monitors the u pin voltage. the is/r s pin voltage when output is off defines the current control operating voltage. v bs current d issipation (u -phase high side) vm 27 k 1000 pf 2.5 v hu+ = 5 v hv+ = 0 v hw+ = 0 v v cc = 15 v v s = 6.1 v 2 k 15 v v bb = 18 v is/rs = 0 v 0.6 v 1 g nd 2 hu+ 3 hu - 4 hv+ 5 hv - 6 hw+ 7 hw - 8 fr 9 fg 10 v reg 11 v cc 12 os 13 r re f 14 v s 15 rs 16 gnd 17 bsu 18 u 19 nc 20 is1 21 v 22 bsv 23 v bb 24 bsw 25 w 26 is2 im 27 k 1000 pf 2.5 v hv+ = 0 v hw+ = 0 v v cc = 15 v bsu = 15 v 1 gnd 2 hu+ 3 hu - 4 hv+ 5 hv - 6 hw+ 7 hw - 8 fr 9 fg 10 v reg 11 v cc 12 os 13 r ref 14 v s 15 rs 16 gn d 17 bsu 18 u 19 nc 20 is1 21 v 22 bsv 23 v bb 24 bsw 25 w 26 is2 hu+ = 5 v/0 v v s = 6.1v
tpd 4151k 2014 - 04- 0 7 22 bsd forward voltage (u -phase) vm 500 a 1 gnd 2 hu+ 3 hu - 4 h v+ 5 hv - 6 hw+ 7 hw - 8 fr 9 fg 10 v reg 11 v cc 12 os 13 r ref 14 v s 15 rs 16 g nd 17 bsu 18 u 19 nc 20 is1 21 v 22 bsv 23 v bb 24 bsw 25 w 26 is2
tpd 4151k 2014 - 04- 0 7 23 turn - on/off loss (lo w side igbt + high side frd) input( hv+ ) igbt (c - e voltage) (u - gnd) power supply current w t off w t on im l vm 27 k 1000 pf 2.5 v hu+ = 0 v hv+ = pg hw+ = 0 v v cc = 15 v v s = 6.1 v v bb /u = 141 v 5 mh 1 gnd 2 hu+ 3 hu - 4 hv+ 5 hv - 6 hw+ 7 hw - 8 fr 9 fg 10 v reg 11 v cc 12 os 13 r ref 14 v s 15 rs 16 gnd 17 bsu 18 u 19 nc 20 is1 21 v 22 bsv 23 v bb 24 bsw 25 w 26 is2 2.2 f
tpd 4151k 2014 - 04- 0 7 24 package dimensions hdip26 - p - 1332 - 2.0 0 unit: mm weight: 3.8 g (typ.)
tpd 4151k 2014 - 04- 0 7 25 restrict ions on product use ? toshiba corporation, and its subsidiaries and affiliates (collectively "toshiba"), reserve the right to make changes to the i nformation in this document, and related hardware, software and systems (collectively "product") without noti ce. ? this document and any information herein may not be reproduced without prior written permission from toshiba. even with toshiba's written permission, reproduction is permissible only if reproduction is without alteration/omission. ? though toshiba wo rks continually to improve product's quality and reliability, product can malfunction or fail. customers are responsible for complying with safety standards and for providing adequate designs and safeguards for their hardware, softwar e and systems which mi nimize risk and avoid situations in which a malfunction or failure of product could cause loss of human life, bodily injury or damage to property, including data loss or corruption. before customers use the product, create designs including t he product, or incorporate the product into their own applications, customers must also refer to and comply with (a) the latest versions of all relevant toshiba information, including without limitation, this document, the specifications, the data sheets and applic ation notes for product and the precautions and conditions set forth in the "toshiba semiconductor reliability handbook" and (b) the instructions for the application with which the product will be used with or for. customers are solely responsible for all as pec ts of their own product design or applications, including but not limited to (a) determining the appropriateness of the use of this produ ct in such design or applications; (b) evaluating and determining the applicability of any information contained in thi s document, or in charts, diagrams, programs, algorithms, sample application circuits, or any other referenced documents; and (c) validating all operat ing parameters for such designs and applications. toshiba assumes no liability for customers' product des ign or applications. ? product is neither intended nor warranted for use in equipments or systems that require extraordinarily high levels of quality and/or reliability, and/or a malfunction or failure of which may cause loss of human life, bodily injury, serious property damage and/or serious public impact ( " unintended use " ). except for specific applications as expressly stated in this document, unintended use includes, without limitation, equipment used in nuclear facilities, equipment used in the aerospa ce industry, medical equipment, equipment used for automobiles, trains, ships and other transportation, traffic signaling equipment, equipment used to control combustions or ex plosions, safety devices, elevators and escalators, devices related to electric power, and equipment used in finance - related fields. if you use product for unintended use, toshiba assumes no liability for product. for details, please contact your toshiba sales representative. ? do not disassemble, analyze, reverse - engineer, alter, mod ify, translate or copy product, whether in whole or in part. ? product shall not be used for or incorporated into any products or systems whose manufacture, use, or sale is prohibited unde r any applicable laws or regulations. ? the information contained he rein is presented only as guidance for product use. no responsibility is assumed by toshiba for any infringement of patents or any other intellectual property rights of third parties that may result from the use of product. n o license to any intellectual p roperty right is granted by this document, whether express or implied, by estoppel or otherwise. ? absent a written signed agreement, except as provided in the relevant terms and conditions of sale for product, and to the maximum extent allowable by law, t oshiba (1) assumes no liability whatsoever, including without limitation, indirect, consequential, special, or incidental damages or loss, including without limitation, loss of profits, loss of opportunities, business interruption and loss of data, and (2) disclaims any and all express or implied warranties and conditions related to sale, use of product, or information, including warranties or conditions of merchantability, fitness for a particular purpose, accuracy of information, or noninfringement. ? do not use or otherwise make available product or related software or technology for any military purposes, including without limitation, for the design, development, use, stockpiling or manufacturing of nuclear, chemical, or biological weapons or mis sile tec hnology products (mass destruction weapons). product and related software and technology may be controlled under the applicable export laws and regulations including, without limitation, the japanese foreign exchange and foreign trade law and the u.s. expo rt administration regulations. export and re - export of product or related software or technology are strictly prohibited except in compliance with all applicable export laws and regulations. ? please contact your toshiba sales representative for details as to environmental matters such as the rohs compatibility of product. please use product in compliance with all applicable laws and regulations that regulate the inclusion or use of controlled su bstances, including without limitation, the eu rohs directive. toshiba assumes no liability for damages or losse s occurring as a resul t of noncompliance w ith applicable laws and regulations.


▲Up To Search▲   

 
Price & Availability of TPD4151K

All Rights Reserved © IC-ON-LINE 2003 - 2022  

[Add Bookmark] [Contact Us] [Link exchange] [Privacy policy]
Mirror Sites :  [www.datasheet.hk]   [www.maxim4u.com]  [www.ic-on-line.cn] [www.ic-on-line.com] [www.ic-on-line.net] [www.alldatasheet.com.cn] [www.gdcy.com]  [www.gdcy.net]


 . . . . .
  We use cookies to deliver the best possible web experience and assist with our advertising efforts. By continuing to use this site, you consent to the use of cookies. For more information on cookies, please take a look at our Privacy Policy. X