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JAN1N4126C-1
Product Overview
Category
The JAN1N4126C-1 belongs to the category of semiconductor devices, specifically a Zener diode.
Use
It is commonly used for voltage regulation and protection in electronic circuits.
Characteristics
- Voltage regulation
- Reverse breakdown voltage: 6.8V
- Power dissipation: 500mW
- Operating temperature range: -65°C to +175°C
Package
The JAN1N4126C-1 is typically available in a DO-35 glass axial package.
Packaging/Quantity
It is usually supplied in reels or tubes with varying quantities depending on the manufacturer.
Specifications
- Reverse breakdown voltage: 6.8V
- Zener impedance: 40Ω
- Maximum reverse current: 5mA
- Maximum power dissipation: 500mW
- Operating temperature range: -65°C to +175°C
Detailed Pin Configuration
The JAN1N4126C-1 Zener diode has two pins, anode, and cathode. The anode is connected to the positive terminal, while the cathode is connected to the negative terminal.
Functional Features
- Voltage regulation: It maintains a constant output voltage when it is operated in the breakdown region.
- Protection: It protects sensitive components in a circuit by limiting the voltage across them.
Advantages and Disadvantages
Advantages
- Precise voltage regulation
- Compact size
- Low cost
Disadvantages
- Limited power dissipation capability
- Sensitivity to temperature variations
Working Principles
The JAN1N4126C-1 Zener diode operates based on the principle of the Zener effect, where it maintains a nearly constant voltage across its terminals when it is reverse-biased and operated in the breakdown region.
Detailed Application Field Plans
The JAN1N4126C-1 is widely used in various electronic applications such as: - Voltage regulators - Overvoltage protection circuits - Signal clamping circuits - Voltage reference circuits
Detailed and Complete Alternative Models
Some alternative models to the JAN1N4126C-1 Zener diode include: - 1N4732A - BZX55C6V8 - LM336Z-5.0 - 1N5226B
In conclusion, the JAN1N4126C-1 Zener diode is a versatile semiconductor device that finds extensive use in voltage regulation and protection applications across various electronic circuits.
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Seznam 10 běžných otázek a odpovědí souvisejících s aplikací JAN1N4126C-1 v technických řešeních
What is the JAN1N4126C-1 diode used for?
- The JAN1N4126C-1 diode is commonly used for voltage regulation, surge protection, and rectification in various technical solutions.
What are the key specifications of the JAN1N4126C-1 diode?
- The JAN1N4126C-1 diode typically has a voltage rating of 150V, a forward current of 200mA, and a fast switching speed.
How does the JAN1N4126C-1 diode provide surge protection?
- The JAN1N4126C-1 diode can clamp transient voltage spikes to a safe level, protecting sensitive components in a circuit from damage.
In what types of circuits is the JAN1N4126C-1 diode commonly used?
- The JAN1N4126C-1 diode is often used in power supply circuits, voltage regulation circuits, and electronic equipment requiring surge protection.
Can the JAN1N4126C-1 diode be used for reverse polarity protection?
- Yes, the JAN1N4126C-1 diode can be employed to prevent damage from reverse polarity connections in circuits.
What is the temperature range for the JAN1N4126C-1 diode?
- The JAN1N4126C-1 diode typically operates within a temperature range of -65°C to 175°C.
Is the JAN1N4126C-1 diode suitable for high-frequency applications?
- While it can function at moderate frequencies, the JAN1N4126C-1 diode may not be ideal for very high-frequency applications due to its inherent capacitance.
What are the mounting options for the JAN1N4126C-1 diode?
- The JAN1N4126C-1 diode is available in various package types, including axial lead, surface mount, and through-hole configurations.
Does the JAN1N4126C-1 diode require a heat sink for certain applications?
- In high-power or high-temperature applications, a heat sink may be recommended to ensure optimal performance and reliability.
Are there any common failure modes associated with the JAN1N4126C-1 diode?
- Common failure modes include thermal breakdown under excessive current or voltage stress, as well as potential damage from transient overvoltage events. Proper design and application considerations can mitigate these risks.