Display Through-hole ELD-525SYGWA/S530-E2 Features * Industrial standard size. * Low power consumption. * Categorized for luminous intensity. *The product itself will remain with RoHS Compliant version. *Compliance with EU REACH. *Compliance with Pb free. Description * The ELD-525SYGWA/S530-E2 is a 13.6 mm (0.54") digit height seven-segment display. * The display provides excellent reliability in bright ambient light. * The device is made with white segments and gray surface. Applications * Home appliances * Instrument panels * Digital readout displays 1 Copyright (c) 2010, Everlight All Rights Reserved. Release Date : Dec. 4, 2016 Issue No : DDF-0002122 Rev.3 www.everlight.com DATASHEET Display Through-hole ELD-525SYGWA/S530-E2 Device Selection Guide Chip Materials Emitted Color Resin Color AlGaInP Brilliant Yellow Green White Diffusion Absolute Maximum Ratings (Ta=25) Parameter Symbol Rating Unit Reverse Voltage VR 5 V Forward Current IF 25 mA IFP 60 mA Power Dissipation Pd 60 mW Operating Temperature Topr -40 ~ +85 Storage Temperature Tstg Soldering Temperature Tsol -40 ~ +100 Reflow Soldering : 260 for 5 sec. Peak Forward Current (Duty 1/10 @1KHz) Hand Soldering : 350 for 3 sec. Electro-Optical Characteristics (Ta=25) Parameter Symbol Min. Typ. Max. Unit Condition Luminous Intensity*1 Iv 2.8 4.5 ----- mcd IF=10mA Peak Wavelength p ----- 575 ----- nm IF=20mA Dominant Wavelength d ----- 573 ----- nm IF=20mA Spectrum Radiation Bandwidth ----- 20 ----- nm IF=20mA Forward Voltage VF IR ----- 2.0 2.4 V IF=20mA ----- ----- 100 A VR=5V Reverse Current Note: 1. Luminous Intensity is a average value which is measured one 7-segment. 2. Tolerance of Luminous Intensity: 10 3. Tolerance of Forward Voltage: 0.1V 2 Copyright (c) 2010, Everlight All Rights Reserved. Release Date : Dec. 4, 2016 Issue No : DDF-0002122 Rev.3 www.everlight.com DATASHEET Display Through-hole ELD-525SYGWA/S530-E2 Typical Electro-Optical Characteristics Curves Forward Current vs. Forward Voltage (Ta=25) Forward Current (mA) Relative luminous intensity () Spectrum Distribution (Ta=25) Wavelength p (nm) Forward Voltage (V) Forward Current (mA) Forward Current Derating Curve Ambient Temperature (C ) 3 Copyright (c) 2010, Everlight All Rights Reserved. Release Date : Dec. 4, 2016 Issue No : DDF-0002122 Rev.3 www.everlight.com DATASHEET Display Through-hole ELD-525SYGWA/S530-E2 Package Dimension & Internal Circuit Diagram Note: Tolerances unless mentioned 0.25mm. Unit = mm 4 Copyright (c) 2010, Everlight All Rights Reserved. Release Date : Dec. 4, 2016 Issue No : DDF-0002122 Rev.3 www.everlight.com DATASHEET Display Through-hole ELD-525SYGWA/S530-E2 Packing Materials Label Explanation D525SYGWA/S530-E2 CPN: Customer's Product Number P/N: Product Number QTY: Packing Quantity CAT: Luminous Intensity Rank HUE: Reference REF: Reference LOT No: Lot Number REFERENCE: Volume Label code Packing Process 20 PCS/TUBE 5 36 Tubes/Box 4 Boxes/Carton Copyright (c) 2010, Everlight All Rights Reserved. Release Date : Dec. 4, 2016 Issue No : DDF-0002122 Rev.3 www.everlight.com DATASHEET Display Through-hole ELD-525SYGWA/S530-E2 Precautions for Use 1. Soldering Condition 1.1 Maximum Body Case Temperature Profile for evaluation of DIP Soldering Profile Note: Preheat Temperature 100 C Time 60 seconds max. Other Bath Temperature 260C Bath Time 5 seconds max. DIP Soldering 1 time All parameters are maximum body case temperature values and cannot be considered as a soldering profile. The body case temperature was measured by soldering a thermal couple to the soldering point of LEDs. 2. Soldering Iron Each terminal is to go to the tip of soldering iron temperature less than 350 for 3 seconds within once in less than the soldering iron capacity 25W. Leave two seconds and more intervals, and do soldering of each terminal. Be careful because the damage of the product is often started at the time of the hand solder. 6 Copyright (c) 2010, Everlight All Rights Reserved. Release Date : Dec. 4, 2016 Issue No : DDF-0002122 Rev.3 www.everlight.com DATASHEET Display Through-hole ELD-525SYGWA/S530-E2 DISCLAIMER 1. EVERLIGHT reserves the right(s) on the adjustment of product material mix for the specification. 2. The Product meet EVERLIGHT published specification for a period of twelve(12 ) months from date of shipment. 3. The graphs shown in this datasheet are representing typical data only and do not show guaranteed values. 4. When using this product, please observe the absolute maximum ratings and the instructions for using outlined in these specification sheets. EVERLIGHT assumes no responsibility for any damage resulting from the use of the product which does not comply with the absolute maximum ratings and the instructions included in these specification sheets. 5. These specification sheets include materials protected under copyright of EVERLIGHT. Reproduction in any form is prohibited without obtaining EVERLIGHT's prior consent. 6. This product is not intended to be used for military, aircraft, automotive, medical, life sustaining or life saving applications or any other application which can result in human injury or death. Please contact authorized Everlight sales agent for special application request. 7. ESD (Electrostatic Discharge) The products are sensitive to static electricity or surge voltage. ESD can damage a die and its reliability. When handling the products, the following measures against electrostatic discharge are strongly recommended: Eliminating the charge Grounded wrist strap, ESD footwear, clothes, and floors Grounded workstation equipment and tools ESD table/shelf mat made of conductive materials Proper grounding is required for all devices, equipment, and machinery used in product assembly. Surge protection should be considered when designing of commercial products. If tools or equipment contain insulating materials such as glass or plastic, the following measures against electrostatic discharge are strongly recommended: Dissipating static charge with conductive materials Preventing charge generation with moisture Neutralizing the charge with ionizers 8. The LEDs should be operated with forward bias. The driving circuit must be designed so that the LEDs are not subjected to forward or reverse voltage while it is off. If reverse voltage is continuously applied to the LEDs, it may cause migration resulting in LED damage. 7 Copyright (c) 2010, Everlight All Rights Reserved. Release Date : Dec. 4, 2016 Issue No : DDF-0002122 Rev.3 www.everlight.com