TD3042 Zero-Volt Switching Triac Driver DESCRIPTION The TD3042 consists of a single input LED optically coupled to a zero-volt crossing triac driver. The TD3042 provides high input-to-output isolation and is designed to drive high-powered triacs. Typical uses include interfacing logic level control signals to equipment powered from 110Vac and 220Vac lines. FEATURES APPLICATIONS • Zero-volt switching • Home appliances • 400V blocking voltage • Motor/ Drive controls • High input-to-output isolation (5kVrms MIN) • Solid state relays • Trigger current 10mA MAX • Solenoid / Valve control • High dV/dt (1kV/us MIN, 2kV/us TYP) • Temperature Control OPTIONS/SUFFIXES* ABSOLUTE MAXIMUM RATINGS* • -S Surface Mount Leadform Option (50 pcs / tube) • -TR Tape and Reel Option (1000 pcs / reel) • -V Signifies VDE approval • -H 0.4" Lead Spacing (see mechanical dimension) NOTE: Suffixes listed above are not included in marking on device for part number identification. SCHEMATIC DIAGRAM 1 6 2 5* Zero Volt Crossing Circuit 3 1. Anode 2. Cathode 3. N/C 4. MAIN Terminal 5. N/C* 6. MAIN Terminal PARAMETER UNIT MIN TYP MAX Storage Temperature °C -55 125 Operating Temperature °C -40 85 Continuous Input Current mA 50 Transient Input Current mA 400 Reverse Input Control Voltage V 6 Total Power Dissipation mW 330 Soldering Temperature (10s) ºC 260 *The values indicated are absolute stress ratings. Functional operation of the device is not implied at these or any conditions in excess of those defined in electrical characteristics section of this document. Exposure to Absolute Ratings may cause permanent damage to the device and may adversely affect reliability. 4 *DO NOT CONNECT Triac Substrate © 2009 Solid State Optronics • San José, CA www.ssousa.com • +1.408.293.4600 APPROVALS • UL and C-UL Approved File # E201932 • VDE Approved, Lic # 40011225 Page 1 of 5 TD3042 rev 1.41 (06/01/2009) TD3042 Zero-Volt Switching Triac Driver ELECTRICAL CHARACTERISTICS - 25°C PARAMETER UNIT MIN TYP MAX 1.2 1.5 TEST CONDITIONS INPUT SPECIFICATIONS LED Forward Voltage V LED Reverse Voltage V Reverse Leakage Current µA 6 If = 10mA 12 Ir = 10uA 10 Vr = 4V OUTPUT SPECIFICATIONS Blocking Voltage V Peak Blocking Current nA On-state Voltage Critical Rate of Rise 400 V (See Note 1 below) V/ µs 1,000 Io = 1uA 60 500 Vdrm = Rated 1.8 3 Itm = 100mA If = 0mA 2,000 COUPLED SPECIFICATIONS Isolation Voltage Trigger Current V 5000 T = 1 minute mA (See Note 2 below) Inhibit Voltage V Isolation Resistance GΩ Holding Current µA Leakage Current µA 5 10 Main terminal voltage = 3V 20 If = 5mA 50 DC 500V 100 1 If = Rated, Vdrm = Rated, Off State Note 1: This is for static dV/dt. Test circuit below Note 2: Resistive load. For inductive loads, higher drive current is recommended. STATIC dV/dt TEST CIRCUIT 400V Vdc RTEST R = 1 kΩ CTEST 200pF PULSE INPUT MERCURY WETTED RELAY D.U.T. X100 SCOPE PROBE Vmax = 400 V APPLIED VOLTAGE WAVEFORM 252 V dv/dt = 0 VOLTS 0.63 Vmax RC = 252 RC RC © 2009 Solid State Optronics • San José, CA www.ssousa.com • +1.408.293.4600 Page 2 of 5 TD3042 rev 1.41 (06/01/2009) TD3042 Zero-Volt Switching Triac Driver PERFORMANCE DATA VTM,ON-STATE VOLTAGE (VOLTS) Ta,AMBIENT TEMPERATURE (°C) Ta,AMBIENT TEMPERATURE (°C) Fig.5 Trigger Current versus Temperature IFT , NORMALIZED IDRM2 NORMALIZED Fig.4 IDRM2 ,Leakage in Inhibit State versus Temperature Fig.3 Leakage with LED Off versus Temperature IDRM1,PEAK BLOCKING CURRENT (nA) Fig.2 Inhibit Voltage versus Temperature VINH, NORMALIZED ITM,ON-STATE CURRENT (mA) Fig.1 On-State Characteristics Ta,AMBIENT TEMPERATURE (°C) © 2009 Solid State Optronics • San José, CA www.ssousa.com • +1.408.293.4600 Ta,AMBIENT TEMPERATURE (°C) Page 3 of 5 TD3042 rev 1.41 (06/01/2009) TD3042 Zero-Volt Switching Triac Driver MECHANICAL DIMENSIONS 6 PIN DUAL IN-LINE PACKAGE (Through Hole) 6 PIN SURFACE MOUNT DEVICE (SMD) -H Suffix 0.4" Lead Spacing TOLERANCE :+ 0.25mm Unit in (mm) © 2009 Solid State Optronics • San José, CA www.ssousa.com • +1.408.293.4600 Page 4 of 5 TD3042 rev 1.41 (06/01/2009) TD3042 Zero-Volt Switching Triac Driver DISCLAIMER Solid State Optronics (SSO) makes no warranties or representations with regards to the completeness and accuracy of this document. SSO reserves the right to make changes to product description, specifications at any time without further notice. SSO shall not assume any liability arising out of the application or use of any product or circuit described herein. Neither circuit patent licenses nor indemnity are expressed or implied. Except as specified in SSO's Standard Terms & Conditions, SSO disclaims liability for consequential or other damage, and we make no other warranty, expressed or implied, including merchantability and fitness for particular use. LIFE SUPPORT POLICY SSO does not authorize use of its devices in life support applications wherein failure or malfunction of a device may lead to personal injury or death. Users of SSO devices in life support applications assume all risks of such use and agree to indemnify SSO against any and all damages resulting from such use. Life support devices are defined as devices or systems which, (a) are intended for surgical implant into the body, or (b) support or sustain life, and (c) whose failure to perform when used properly in accordance with instructions for use can be reasonably expected to result in significant injury to the user, or (d) a critical component in any component of a life support device or system whose failure can be reasonably expected to cause failure of the life support device or system, or to affect its safety or effectiveness. © 2009 Solid State Optronics • San José, CA www.ssousa.com • +1.408.293.4600 Page 5 of 5 TD3042 rev 1.41 (06/01/2009)