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MXP4KE180CAE3 Product Overview
Introduction
The MXP4KE180CAE3 belongs to the category of transient voltage suppressor diodes. These diodes are commonly used to protect sensitive electronic components from voltage spikes and transients. The MXP4KE180CAE3 is designed to provide robust protection for a variety of electronic circuits and devices.
Basic Information Overview
- Category: Transient Voltage Suppressor Diode
- Use: Protection against voltage spikes and transients
- Characteristics: High surge capability, fast response time
- Package: Axial leaded, DO-41 package
- Essence: Safeguarding electronic components from voltage surges
- Packaging/Quantity: Available in reels or bulk packaging
Specifications
The MXP4KE180CAE3 has the following specifications: - Peak Power Dissipation: 400W - Breakdown Voltage: 162V to 178V - Operating Temperature Range: -55°C to +175°C - Storage Temperature Range: -55°C to +175°C
Detailed Pin Configuration
The MXP4KE180CAE3 is an axial leaded diode with two leads. The pin configuration is as follows: - Pin 1: Anode - Pin 2: Cathode
Functional Features
- Fast response time to clamp transient voltages
- High surge capability to withstand large transient currents
- Low clamping voltage to protect downstream components
Advantages and Disadvantages
Advantages
- Effective protection against voltage spikes
- Fast response time
- Robust construction for reliability
Disadvantages
- Limited to specific voltage ranges
- Requires careful consideration of placement in circuit design
Working Principles
The MXP4KE180CAE3 operates by diverting excess voltage away from sensitive components when a transient event occurs. When the voltage exceeds the breakdown voltage, the diode conducts and shunts the excess energy to protect the circuit.
Detailed Application Field Plans
The MXP4KE180CAE3 is commonly used in the following applications: - Power supply units - Communication equipment - Automotive electronics - Industrial control systems
Detailed and Complete Alternative Models
Some alternative models to the MXP4KE180CAE3 include: - P6KE180CA - 1.5KE180CA - SA180CA
In conclusion, the MXP4KE180CAE3 transient voltage suppressor diode offers effective protection against voltage spikes and transients in various electronic applications. Its robust design, fast response time, and high surge capability make it a reliable choice for safeguarding sensitive components.
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Seznam 10 běžných otázek a odpovědí souvisejících s aplikací MXP4KE180CAE3 v technických řešeních
What is MXP4KE180CAE3?
- MXP4KE180CAE3 is a type of transient voltage suppressor diode used to protect electronic circuits from voltage spikes and transients.
What is the maximum voltage rating for MXP4KE180CAE3?
- The maximum voltage rating for MXP4KE180CAE3 is 154V.
What is the peak pulse power dissipation of MXP4KE180CAE3?
- The peak pulse power dissipation of MXP4KE180CAE3 is 400W.
What are the typical applications of MXP4KE180CAE3?
- MXP4KE180CAE3 is commonly used in surge protection for sensitive electronics, such as in telecommunications equipment, industrial control systems, and automotive electronics.
What is the breakdown voltage of MXP4KE180CAE3?
- The breakdown voltage of MXP4KE180CAE3 is typically around 200V.
What is the response time of MXP4KE180CAE3?
- The response time of MXP4KE180CAE3 is very fast, typically in the nanosecond range.
Is MXP4KE180CAE3 RoHS compliant?
- Yes, MXP4KE180CAE3 is RoHS compliant, meaning it meets the Restriction of Hazardous Substances directive.
Can MXP4KE180CAE3 be used in high-temperature environments?
- Yes, MXP4KE180CAE3 is designed to operate in high-temperature environments, with a maximum operating temperature of 175°C.
What is the packaging type for MXP4KE180CAE3?
- MXP4KE180CAE3 is typically available in a DO-214AC (SMA) package.
Are there any recommended layout considerations when using MXP4KE180CAE3 in a circuit?
- It is recommended to place the MXP4KE180CAE3 as close as possible to the input terminals of the circuit to maximize its effectiveness in suppressing voltage transients. Additionally, proper grounding and trace routing should be considered to minimize inductance and optimize performance.