L'image peut être une représentation.
Voir les spécifications pour les détails du produit.
1N4741A B0G

1N4741A B0G

Product Overview

Category

The 1N4741A B0G belongs to the category of Zener diodes.

Use

It is commonly used for voltage regulation and protection in electronic circuits.

Characteristics

  • Zener voltage: 10V
  • Power dissipation: 1W
  • Package type: DO-41
  • Operating temperature range: -65°C to +200°C
  • Forward voltage: 1.2V
  • Reverse current: 5μA

Package

The 1N4741A B0G is typically available in a DO-41 package.

Essence

This Zener diode is essential for maintaining stable voltage levels in various electronic applications.

Packaging/Quantity

It is usually packaged in reels or tubes, with quantities varying based on manufacturer specifications.

Specifications

  • Zener voltage: 10V
  • Power dissipation: 1W
  • Maximum forward voltage: 1.2V
  • Maximum reverse current: 5μA
  • Operating temperature range: -65°C to +200°C
  • Package type: DO-41

Detailed Pin Configuration

The 1N4741A B0G Zener diode typically has two pins, with the cathode identified by a band around one end of the diode.

Functional Features

  • Voltage regulation: The Zener diode maintains a constant voltage across its terminals, providing stability in electronic circuits.
  • Overvoltage protection: It can protect sensitive components by diverting excess voltage away from them.

Advantages

  • Precise voltage regulation
  • Compact size
  • Wide operating temperature range

Disadvantages

  • Limited power dissipation capability
  • Susceptible to damage from overcurrent conditions

Working Principles

The 1N4741A B0G operates based on the Zener effect, where it allows current to flow in reverse when the voltage reaches its breakdown voltage, effectively regulating the voltage across its terminals.

Detailed Application Field Plans

The 1N4741A B0G is widely used in: - Voltage regulators - Power supplies - Overvoltage protection circuits - Signal clamping circuits

Detailed and Complete Alternative Models

Some alternative models to the 1N4741A B0G include: - 1N4733A - 1N4734A - 1N4735A - 1N4736A

In conclusion, the 1N4741A B0G Zener diode is a crucial component in electronic circuits, providing precise voltage regulation and overvoltage protection. Its compact size and wide operating temperature range make it suitable for various applications in the electronics industry.

[Word count: 411]

Énumérez 10 questions et réponses courantes liées à l'application de 1N4741A B0G dans les solutions techniques

  1. What is the 1N4741A B0G?

    • The 1N4741A B0G is a 10V, 1W Zener diode commonly used in electronic circuits for voltage regulation and protection.
  2. What are the typical applications of the 1N4741A B0G?

    • It is commonly used in voltage regulator circuits, overvoltage protection circuits, and as a reference voltage source.
  3. What is the maximum power dissipation of the 1N4741A B0G?

    • The maximum power dissipation of the 1N4741A B0G is 1 watt.
  4. What is the voltage tolerance of the 1N4741A B0G?

    • The voltage tolerance of the 1N4741A B0G is +/- 5%.
  5. What is the operating temperature range of the 1N4741A B0G?

    • The operating temperature range of the 1N4741A B0G is typically -65°C to +200°C.
  6. How do I identify the cathode and anode of the 1N4741A B0G?

    • The cathode of the 1N4741A B0G is typically marked with a band or line on the body of the diode.
  7. Can the 1N4741A B0G be used in reverse bias?

    • Yes, the 1N4741A B0G can be used in reverse bias for certain applications such as voltage reference circuits.
  8. What is the forward voltage drop of the 1N4741A B0G?

    • The forward voltage drop of the 1N4741A B0G is typically around 1.2V.
  9. Is the 1N4741A B0G suitable for high-frequency applications?

    • The 1N4741A B0G is not recommended for high-frequency applications due to its inherent limitations.
  10. Are there any common failure modes associated with the 1N4741A B0G?

    • Common failure modes include exceeding the maximum power dissipation, exceeding the maximum current, and exposure to excessive voltage transients.