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BZD27C160PHR3G Product Overview
Introduction
The BZD27C160PHR3G belongs to the category of Zener diodes and is commonly used for voltage regulation and protection in electronic circuits. This entry provides a comprehensive overview of the product, including its basic information, specifications, pin configuration, functional features, advantages and disadvantages, working principles, application field plans, and alternative models.
Basic Information Overview
- Category: Zener Diode
- Use: Voltage regulation and protection in electronic circuits
- Characteristics: High power dissipation capability, precise voltage regulation, low leakage current
- Package: SOD123FL
- Essence: Zener diode with a voltage rating of 160V
- Packaging/Quantity: Tape & Reel (3000 pieces)
Specifications
- Voltage Rating: 160V
- Power Dissipation: 1.5W
- Zener Voltage Tolerance: ±5%
- Operating Temperature Range: -65°C to +150°C
- Storage Temperature Range: -65°C to +175°C
Detailed Pin Configuration
The BZD27C160PHR3G Zener diode has a standard SOD123FL package with two pins. The anode is connected to pin 1, and the cathode is connected to pin 2.
Functional Features
- Precise voltage regulation under varying load conditions
- Low reverse leakage current
- High power dissipation capability
- Fast response time to transient voltage spikes
Advantages and Disadvantages
Advantages
- Reliable voltage regulation
- High power handling capability
- Compact SOD123FL package
- Wide operating temperature range
Disadvantages
- Limited voltage tolerance range
- Sensitive to excessive current and voltage spikes
Working Principles
The BZD27C160PHR3G operates based on the Zener effect, where it maintains a constant voltage across its terminals when reverse-biased. This allows it to regulate the voltage in electronic circuits and protect sensitive components from overvoltage conditions.
Detailed Application Field Plans
The BZD27C160PHR3G is widely used in various applications, including: - Power supply units - Voltage regulators - Overvoltage protection circuits - Electronic instrumentation - Automotive electronics
Detailed and Complete Alternative Models
Some alternative models to the BZD27C160PHR3G include: - BZX84C160 - MMBZ27C160 - P6SMB160A
In conclusion, the BZD27C160PHR3G Zener diode offers precise voltage regulation and protection capabilities, making it suitable for a wide range of electronic applications.
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Énumérez 10 questions et réponses courantes liées à l'application de BZD27C160PHR3G dans les solutions techniques
What is BZD27C160PHR3G?
- BZD27C160PHR3G is a high-performance, low-resistance, and fast-recovery diode designed for various technical applications.
What are the key features of BZD27C160PHR3G?
- The key features include a low forward voltage drop, high surge current capability, and fast reverse recovery time.
In what technical solutions can BZD27C160PHR3G be used?
- BZD27C160PHR3G can be used in power supplies, voltage clamping circuits, reverse polarity protection, and snubber circuits.
What is the maximum voltage rating of BZD27C160PHR3G?
- The maximum voltage rating is typically 160V.
What is the typical forward voltage drop of BZD27C160PHR3G?
- The typical forward voltage drop is around 0.7V at a specified current.
Is BZD27C160PHR3G suitable for high-frequency applications?
- Yes, BZD27C160PHR3G is suitable for high-frequency applications due to its fast recovery time.
Can BZD27C160PHR3G handle high surge currents?
- Yes, BZD27C160PHR3G has a high surge current capability, making it suitable for applications with transient overcurrent conditions.
What is the operating temperature range of BZD27C160PHR3G?
- The operating temperature range is typically -55°C to 150°C.
Does BZD27C160PHR3G require any special heat sinking or thermal considerations?
- Depending on the application and power dissipation, proper heat sinking or thermal management may be required.
Are there any recommended layout considerations when using BZD27C160PHR3G in a circuit?
- It is recommended to minimize trace lengths and keep the diode close to the load to reduce parasitic inductance and optimize performance.