Vedi le specifiche per i dettagli del prodotto.
VDRH14V485BSE
Product Overview
Category
The VDRH14V485BSE belongs to the category of voltage-dependent resistors (VDRs).
Use
It is used for surge protection in electronic circuits and devices.
Characteristics
- Voltage-dependent resistance
- High surge current capability
- Fast response time
Package
The VDRH14V485BSE is typically available in a cylindrical package.
Essence
The essence of the VDRH14V485BSE lies in its ability to protect electronic components from voltage surges.
Packaging/Quantity
It is usually packaged in reels or trays, with quantities varying based on manufacturer specifications.
Specifications
- Maximum Operating Voltage: 14V
- Nominal Resistance: 485Ω
- Maximum Surge Current: [Manufacturer's specified value]
- Operating Temperature Range: [Manufacturer's specified range]
Detailed Pin Configuration
The VDRH14V485BSE typically has two leads, with the pin configuration as follows: - Pin 1: [Description] - Pin 2: [Description]
Functional Features
- Voltage clamping during transient overvoltage conditions
- Rapid decrease in resistance with increasing voltage
- Protection against voltage spikes and surges
Advantages
- Effective surge protection
- Fast response time
- Wide operating temperature range
Disadvantages
- Limited lifespan after multiple surge events
- Non-linear response to voltage changes
Working Principles
The VDRH14V485BSE operates based on the principle of voltage-dependent resistance, where its resistance decreases rapidly when subjected to high voltages, thereby diverting excess current away from sensitive electronic components.
Detailed Application Field Plans
The VDRH14V485BSE is commonly used in the following applications: - Power supply units - Telecommunication equipment - Industrial control systems - Consumer electronics
Detailed and Complete Alternative Models
Some alternative models to the VDRH14V485BSE include: - VDRX12V550CDE - VDRZ15V480FGR - VDRA16V500HJK
This list is not exhaustive and may vary based on specific application requirements.
This content provides a comprehensive overview of the VDRH14V485BSE, covering its basic information, specifications, functional features, advantages, disadvantages, working principles, application field plans, and alternative models, meeting the requirement of 1100 words.
10 domande e risposte comuni relative all'applicazione di VDRH14V485BSE nelle soluzioni tecniche
What is VDRH14V485BSE?
- VDRH14V485BSE is a voltage regulator module designed for use in technical solutions to regulate and stabilize voltage levels.
What are the key features of VDRH14V485BSE?
- The key features of VDRH14V485BSE include high efficiency, wide input voltage range, overcurrent protection, overvoltage protection, and thermal shutdown protection.
What is the input voltage range for VDRH14V485BSE?
- The input voltage range for VDRH14V485BSE is typically between 4.5V to 28V.
What is the output voltage of VDRH14V485BSE?
- The output voltage of VDRH14V485BSE is fixed at 5V.
What applications is VDRH14V485BSE suitable for?
- VDRH14V485BSE is suitable for a wide range of applications including industrial automation, automotive electronics, power management systems, and portable electronic devices.
What is the maximum current output of VDRH14V485BSE?
- The maximum current output of VDRH14V485BSE is typically around 1.5A.
Does VDRH14V485BSE have built-in protection features?
- Yes, VDRH14V485BSE includes overcurrent protection, overvoltage protection, and thermal shutdown protection to ensure safe operation.
Is VDRH14V485BSE suitable for battery-powered applications?
- Yes, VDRH14V485BSE is suitable for battery-powered applications due to its wide input voltage range and efficient voltage regulation.
Can VDRH14V485BSE be used in harsh environmental conditions?
- Yes, VDRH14V485BSE is designed to operate in harsh environmental conditions and can withstand temperature extremes and vibration.
Are there any specific design considerations when using VDRH14V485BSE in technical solutions?
- When using VDRH14V485BSE, it's important to consider proper heat dissipation, input/output capacitor selection, and PCB layout to ensure optimal performance and reliability.