Part Details for SR105-T by Diodes Incorporated
Results Overview of SR105-T by Diodes Incorporated
- Distributor Offerings: (1 listing)
- Number of FFF Equivalents: (7 replacements)
- CAD Models: (Request Part)
- Number of Functional Equivalents: (10 options)
- Part Data Attributes: (Available)
- Reference Designs: (Not Available)
Tip: Data for a part may vary between manufacturers. You can filter for manufacturers on the top of the page next to the part image and part number.
Applications
Industrial Automation
Energy and Power Systems
Renewable Energy
SR105-T Information
SR105-T by Diodes Incorporated is a Rectifier Diode.
Rectifier Diodes are under the broader part category of Diodes.
A diode is a electrical part that can control the direction in which the current flows in a device. Consider factors like voltage drop, current capacity, reverse voltage, and operating frequency when selecting a diode. Read more about Diodes on our Diodes part category page.
Price & Stock for SR105-T
| Part # | Distributor | Description | Stock | Price | Buy | |
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Quest Components | RECTIFIER DIODE, SCHOTTKY, 1 ELEMENT, 1A, 50V V(RRM), SILICON, DO-41 | 8360 |
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$0.1200 / $0.3000 | Buy Now |
Part Details for SR105-T
SR105-T CAD Models
SR105-T Part Data Attributes
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SR105-T
Diodes Incorporated
Buy Now
Datasheet
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Compare Parts:
SR105-T
Diodes Incorporated
Rectifier Diode, Schottky, 1 Element, 1A, 50V V(RRM), Silicon, DO-41,
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| Rohs Code | Yes | |
| Part Life Cycle Code | Obsolete | |
| Ihs Manufacturer | DIODES INC | |
| Package Description | O-PALF-W2 | |
| Reach Compliance Code | compliant | |
| ECCN Code | EAR99 | |
| HTS Code | 8541.10.00.80 | |
| Application | GENERAL PURPOSE | |
| Case Connection | ISOLATED | |
| Configuration | SINGLE | |
| Diode Element Material | SILICON | |
| Diode Type | RECTIFIER DIODE | |
| JEDEC-95 Code | DO-41 | |
| JESD-30 Code | O-PALF-W2 | |
| Moisture Sensitivity Level | 1 | |
| Number of Elements | 1 | |
| Number of Phases | 1 | |
| Number of Terminals | 2 | |
| Output Current-Max | 1 A | |
| Package Body Material | PLASTIC/EPOXY | |
| Package Shape | ROUND | |
| Package Style | LONG FORM | |
| Peak Reflow Temperature (Cel) | 260 | |
| Qualification Status | Not Qualified | |
| Rep Pk Reverse Voltage-Max | 50 V | |
| Surface Mount | NO | |
| Technology | SCHOTTKY | |
| Terminal Form | WIRE | |
| Terminal Position | AXIAL |
Alternate Parts for SR105-T
This table gives cross-reference parts and alternative options found for SR105-T. The Form Fit Function (FFF) tab will give you the options that are more likely to serve as direct pin-to-pin alternates or drop-in parts. The Functional Equivalents tab will give you options that are likely to match the same function of SR105-T, but it may not fit your design. Always verify details of parts you are evaluating, as these parts are offered as suggestions for what you are looking for and are not guaranteed.
| Part Number | Manufacturer | Composite Price | Description | Compare |
|---|---|---|---|---|
| SR105 | RFE International Inc | Check for Price | Rectifier Diode, Schottky, 1 Element, 1A, 50V V(RRM) | SR105-T vs SR105 |
| SR105 | Microchip Technology Inc | Check for Price | Rectifier Diode, Schottky, 1 Phase, 1 Element, 1A, 50V V(RRM), Silicon, DO-41 | SR105-T vs SR105 |
| SR105 | PanJit Semiconductor | Check for Price | Rectifier Diode, Schottky, 1 Element, 1A, 50V V(RRM) | SR105-T vs SR105 |
| SR105B0 | Taiwan Semiconductor | Check for Price | Rectifier Diode, Schottky, 1 Element, 1A, 50V V(RRM), Silicon, DO-204AL, ROHS COMPLIANT, PLASTIC, DO-41, 2 PIN | SR105-T vs SR105B0 |
| SR105 | Mospec Semiconductor Corp | Check for Price | Rectifier Diode, Schottky, 1 Element, 1A, 50V V(RRM) | SR105-T vs SR105 |
| SR105-TP-HF | Micro Commercial Components | Check for Price | Rectifier Diode, Schottky, 1 Element, 1A, 50V V(RRM), Silicon, DO-41, HALOGEN FREE AND ROHS COMPLIANT, PLASTIC PACKAGE-2 | SR105-T vs SR105-TP-HF |
| SR105 | Jinan Gude Electronic Device Co Ltd | Check for Price | Rectifier Diode, Schottky, 1 Element, 1A, 50V V(RRM) | SR105-T vs SR105 |
SR105-T Frequently Asked Questions (FAQ)
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A good PCB layout for the SR105-T should ensure that the input and output pins are separated as much as possible to minimize electromagnetic interference (EMI). Additionally, the PCB should have a solid ground plane and a low-impedance path for the output current. It's also recommended to use a small footprint and a low-inductance layout to minimize parasitic inductance.
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To ensure the reliability of the SR105-T in high-temperature applications, it's essential to follow the recommended operating temperature range and derate the device's power dissipation accordingly. Additionally, the device should be mounted on a heat sink or a thermally conductive substrate to dissipate heat efficiently. It's also recommended to use a thermal interface material (TIM) to improve heat transfer between the device and the heat sink.
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The SR105-T has built-in ESD protection, but it's still essential to follow proper ESD handling procedures during assembly and testing. The device should be handled in an ESD-controlled environment, and ESD-sensitive devices should be grounded or connected to a static-dissipative mat. Additionally, the device's pins should not be touched or exposed to static electricity during handling or testing.
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To troubleshoot issues with the SR105-T, it's essential to follow a systematic approach. First, verify that the device is properly connected and configured according to the datasheet. Next, check the input voltage and current, as well as the output voltage and current. Use an oscilloscope to check for oscillations or voltage droop. If the issue persists, check the PCB layout and ensure that it meets the recommended layout guidelines. Finally, consult the datasheet and application notes for troubleshooting guidance.
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When using the SR105-T in a high-reliability or safety-critical application, it's essential to follow a rigorous design and testing process. The device should be selected based on its reliability and failure rate data, and the design should be validated through extensive testing and simulation. Additionally, the device should be used within its recommended operating conditions, and the system should be designed to detect and respond to faults or failures. It's also recommended to consult with a reliability engineer or a safety expert to ensure that the design meets the required safety and reliability standards.