- 您现在的位置:买卖IC网 > PDF目录97874 > EC103D175 Thyristor Product Catalog PDF资料下载
参数资料
| 型号: | EC103D175 |
| 英文描述: | Thyristor Product Catalog |
| 中文描述: | 晶闸管产品目录 |
| 文件页数: | 84/224页 |
| 文件大小: | 2697K |
| 代理商: | EC103D175 |
第1页第2页第3页第4页第5页第6页第7页第8页第9页第10页第11页第12页第13页第14页第15页第16页第17页第18页第19页第20页第21页第22页第23页第24页第25页第26页第27页第28页第29页第30页第31页第32页第33页第34页第35页第36页第37页第38页第39页第40页第41页第42页第43页第44页第45页第46页第47页第48页第49页第50页第51页第52页第53页第54页第55页第56页第57页第58页第59页第60页第61页第62页第63页第64页第65页第66页第67页第68页第69页第70页第71页第72页第73页第74页第75页第76页第77页第78页第79页第80页第81页第82页第83页当前第84页第85页第86页第87页第88页第89页第90页第91页第92页第93页第94页第95页第96页第97页第98页第99页第100页第101页第102页第103页第104页第105页第106页第107页第108页第109页第110页第111页第112页第113页第114页第115页第116页第117页第118页第119页第120页第121页第122页第123页第124页第125页第126页第127页第128页第129页第130页第131页第132页第133页第134页第135页第136页第137页第138页第139页第140页第141页第142页第143页第144页第145页第146页第147页第148页第149页第150页第151页第152页第153页第154页第155页第156页第157页第158页第159页第160页第161页第162页第163页第164页第165页第166页第167页第168页第169页第170页第171页第172页第173页第174页第175页第176页第177页第178页第179页第180页第181页第182页第183页第184页第185页第186页第187页第188页第189页第190页第191页第192页第193页第194页第195页第196页第197页第198页第199页第200页第201页第202页第203页第204页第205页第206页第207页第208页第209页第210页第211页第212页第213页第214页第215页第216页第217页第218页第219页第220页第221页第222页第223页第224页
AN1007
Application Notes
http://www.teccor.com
AN1007 - 2
2002 Teccor Electronics
+1 972-580-7777
Thyristor Product Catalog
Figure AN1007.3
Waveform Across Static Switch
A typical example would be in the application of this type circuit
for the control of 5 A resistive load with 120 V rms input voltage.
Choosing a value of 100
for R1 and assuming a typical value of
1 V for the gate to MT1 (VGT) voltage, we can solve for VP by the
following:
VP = IGT (RL + R1) + VGT
Note: RC is not included since it is negligible.
VP = 0.025 (24 + 100) + 1.0 = 4.1 V
Additionally the turn-on angle is
[
θ = 1.4°]
The power lost by the turn-on angle is essentially zero. The
power dissipation in the gate resistor is very minute. A 100
,
0.25 W rated resistor may safely be used. The small turn-on
angle also ensures that no appreciable RFI is generated.
The relay circuit shown in Figure AN1007.1 and Figure AN1007.2
has several advantages in that it eliminates contact bounce,
noise, and additional power consumption by an energizing coil
and can carry an in-rush current of many times its steady state
rating.
The control device S1 indicated can be either electrical or
mechanical in nature. Light-dependent resistors and light- acti-
vated semiconductors, optocoupler, magnetic cores, and mag-
netic reed switches are all suitable control elements. Regardless
of the switch type chosen, it must have a voltage rating equal to
or greater than the peak line voltage applied. In particular, the
use of hermetically sealed reed switches as control elements in
combination with triacs offers many advantages. The reed switch
can be actuated by passing DC current through a small coiled
wire or by the proximity of a small magnet. In either case, com-
plete electrical isolation exists between the control signal input,
which may be derived from many sources, and the switched
power output. Long life of the triac/reed switch combination is
ensured by the minimal volt-ampere switching load placed on the
reed switch by the triac triggering requirements. The thyristor rat-
ings determine the amount of load power that can be switched.
Normally Closed Circuit
With a few additional components, the thyristor can provide a
normally closed static switch function. The critical design portion
of this static switch is a clamping device to turn off/eliminate gate
drive and maintain very low power dissipation through the clamp-
ing component plus have low by-pass leakage around the power
thyristor device. In selecting the power thyristor for load require-
ments, gate sensitivity becomes critical to maintain low power
requirements. Either sensitive SCRs or sensitive logic triacs must
be considered, which limits the load in current capacity and type.
However, this can be broader if an extra stage of circuitry for gat-
ing is permitted.
Figure AN1007.4 illustrates an application using a normally
closed circuit driving a sensitive SCR for a simple but precise
temperature controller. The same basic principle could be applied
to a water level controller for a motor or solenoid. Of course, SCR
and diode selection would be changed depending on load current
requirements.
Figure AN1007.4
Normally Closed Temperature Controller
A mercury-in-glass thermostat is an extremely sensitive measur-
ing instrument, capable of sensing changes in temperature as
small as 0.1 °C. Its major limitation lies in its very low current-
handling capability for reliability and long life, and contact current
should be held below 1 mA. In the circuit of Figure AN1007.4, the
S2010LS2 SCR serves as both current amplifier for the Hg ther-
mostat and as the main load switching element.
With the thermostat open, the SCR will trigger each half cycle
and deliver power to the heater load. When the thermostat
closes, the SCR can no longer trigger and the heater shuts off.
Maximum current through the thermostat in the closed position is
less than 250 A rms.
Figure AN1007.5 shows an all solid state, optocoupled, normally
closed switch circuit. By using a low voltage SBS triggering
device, this circuit can turn on with only a small delay in each half
cycle and also keep gating power low. When the optocoupled
transistor is turned on, the gate drive is removed with only a few
milliamps of bypass current around the triac power device. Also,
by use of the BS08D and 0.1 F, less sensitive triacs and alter-
nistors can be used to control various types of high current loads.
120 V rms (170 V peak)
VP-
1 V rms or 1.6 V peak MAX
VP+
VT+
VT-
θ
Sin
1
–
4.1
170VPK
---------------------
=
1000 W Heater Load
120 V ac
60 CPS
D2015L
CR1—CR4
CR4
CR3
CR1
CR2
S2010LS2
0.1 F
R1
510 k
SCR1
Twist Leads to Minimize
Pickup
Hg in Glass Thermostat
相关PDF资料 |
PDF描述 |
|---|---|
| EC103D1 | Sensitive SCRs |
| EC103D | Sensitive SCRs |
| EC103D2 | Sensitive SCRs |
| EC103D3 | Sensitive SCRs |
| EC103M1 | PC 8C 8#20 PIN RECP |
相关代理商/技术参数 |
参数描述 |
|---|---|
| EC103D1AP | 功能描述:SEN SCR 400V .8A 12A TO92 RoHS:否 类别:分离式半导体产品 >> SCR - 单个 系列:- 其它有关文件:X00619 View All Specifications 产品目录绘图:SCR TO-92 Package 标准包装:1 系列:- SCR 型:灵敏栅极 电压 - 断路:600V 电压 - 栅极触发器 (Vgt)(最大):800mV 电压 - 导通状态 (Vtm)(最大):1.35V 电流 - 导通状态 (It (AV))(最大):500mA 电流 - 导通状态 (It (RMS))(最大):800mA 电流 - 栅极触发电流 (Igt)(最大):200µA 电流 - 维持(Ih):5mA 电流 - 断开状态(最大):1µA 电流 - 非重复电涌,50、60Hz (Itsm):9A,10A 工作温度:-40°C ~ 125°C 安装类型:通孔 封装/外壳:TO-226-3、TO-92-3(TO-226AA)成形引线 供应商设备封装:TO-92-3 包装:剪切带 (CT) 产品目录页面:1554 (CN2011-ZH PDF) 其它名称:497-9067-1 |
| EC103D1RP | 功能描述:SCR 400V .8A 12uA RoHS:否 制造商:STMicroelectronics 最大转折电流 IBO:480 A 额定重复关闭状态电压 VDRM:600 V 关闭状态漏泄电流(在 VDRM IDRM 下):5 uA 开启状态 RMS 电流 (It RMS): 正向电压下降:1.6 V 栅触发电压 (Vgt):1.3 V 最大栅极峰值反向电压:5 V 栅触发电流 (Igt):35 mA 保持电流(Ih 最大值):75 mA 安装风格:Through Hole 封装 / 箱体:TO-220 封装:Tube |
| EC103D1WX | 制造商:NXP Semiconductors 功能描述:1000 制造商:NXP Semiconductors 功能描述:EC103D1W/SC-73/REEL7// - Tape and Reel 制造商:NXP Semiconductors 功能描述:SCR SENS GATE 400V SC-73 制造商:NXP Semiconductors 功能描述:SCRs 400v Sc-73 Scr Sens Gate |
| EC103D2 | 功能描述:SCR 400V .8A 50uA Sensing RoHS:否 制造商:STMicroelectronics 最大转折电流 IBO:480 A 额定重复关闭状态电压 VDRM:600 V 关闭状态漏泄电流(在 VDRM IDRM 下):5 uA 开启状态 RMS 电流 (It RMS): 正向电压下降:1.6 V 栅触发电压 (Vgt):1.3 V 最大栅极峰值反向电压:5 V 栅触发电流 (Igt):35 mA 保持电流(Ih 最大值):75 mA 安装风格:Through Hole 封装 / 箱体:TO-220 封装:Tube |
| EC103D275 | 功能描述:SCR 400V .8A 50uA RoHS:否 制造商:STMicroelectronics 最大转折电流 IBO:480 A 额定重复关闭状态电压 VDRM:600 V 关闭状态漏泄电流(在 VDRM IDRM 下):5 uA 开启状态 RMS 电流 (It RMS): 正向电压下降:1.6 V 栅触发电压 (Vgt):1.3 V 最大栅极峰值反向电压:5 V 栅触发电流 (Igt):35 mA 保持电流(Ih 最大值):75 mA 安装风格:Through Hole 封装 / 箱体:TO-220 封装:Tube |
发布紧急采购,3分钟左右您将得到回复。