Diode Bridge GBU808
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Diode Bridge GBU808

$11.80

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Diode Bridge GBU808

*8A

*800V

*Single Phase

*Rectifier IC Chip

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Description

Diode Bridge GBU808

The Diode Bridge GBU808 is an 8 Amp, 800 Volt bridge rectifier, commonly used to convert alternating current (AC) to direct current (DC).
The Diode Bridge GBU808 is a single-phase bridge rectifier, meaning it’s designed for use with a two-wire AC input. 

The Diode Bridge GBU808 is known for its robust construction and ability to handle high currents, making it suitable for various industrial and commercial applications. 

Here’s a more detailed breakdown:
  • Function: It functions as a bridge rectifier, converting AC input to DC output. 
  • Current Rating: It can handle a forward current of 8 Amps. 
  • Voltage Rating: It can withstand a peak reverse voltage of 800 Volts. 
  • Construction: It’s typically a 4-pin, through-hole mounted component. 
  • Applications: It’s used in power supplies, motor controls, welding equipment, and other electronic circuits requiring efficient rectification and high voltage capability. 
  • Operating Temperature: The GBU808 can operate within a temperature range of -55°C to +150°C. 
A diode bridge, also known as a bridge rectifier, is an electrical circuit that converts alternating current (AC) into direct current (DC).

It uses four or more diodes arranged in a bridge configuration to achieve full-wave rectification. This means it converts both the positive and negative parts of the AC waveform into positive (or negative) voltage. 

Here’s a more detailed explanation:
  • Function:

    The primary function of a diode bridge is to take an AC input (like from a wall outlet) and produce a DC output, which is used to power many electronic devices. 

  • How it works:

    In a diode bridge, four diodes are arranged in a way that during the positive half-cycle of the AC input, two diodes conduct, and during the negative half-cycle, the other two diodes conduct, ensuring that current always flows in the same direction through the load (the component or circuit that uses the DC power). 

  • Full-wave rectification:

    This process, called full-wave rectification, means that both halves of the AC waveform are used to produce DC, resulting in a more efficient and smoother DC output compared to half-wave rectification. 

  • Applications:
    Diode bridges are widely used in power supplies for electronic devices, battery chargers, and various other applications where DC power is needed. 
Additional information
Weight 0.01 kg
Dimensions 5 × 5 × 0.5 cm
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The 1N5408 is a common general-purpose rectifier diode. It's designed to allow electric current to flow primarily in one direction, making it crucial for converting alternating current (AC) to direct current (DC). Think of it like a one-way valve for electricity. It belongs to the 1N540x series of power diodes, known for their ability to handle relatively high current and voltage. Here are its key characteristics and common uses: Key Features
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  • High Forward Current Capacity: It's rated for an average rectified forward current () of 3 Amperes (A). This indicates it can handle a significant amount of current flowing through it in the correct direction.
  • High Surge Current Capability: The 1N5408 can handle non-repetitive peak forward surge currents () of up to 200A for short durations, protecting circuits from sudden power spikes.
  • Low Forward Voltage Drop: When conducting, it has a relatively low forward voltage drop () of approximately 1.0V to 1.2V at its rated current. A lower voltage drop means less power is lost as heat.
  • Standard Recovery: It's a "standard recovery" diode, meaning its switching speed is relatively slow compared to fast recovery diodes. This makes it suitable for power rectification at lower frequencies (like 50/60 Hz AC).
  • DO-201 Package: It typically comes in a DO-201 axial-leaded package, which is a through-hole component with leads extending from both ends, allowing for easy mounting on circuit boards.
  • Wide Operating Temperature Range: It can operate and be stored in a wide temperature range, typically from -65°C to +175°C.
  Applications The robust nature of the 1N5408 makes it a staple in various electronic designs:
  • Power Supplies and Rectifiers: This is its primary application. It efficiently converts AC input voltage into pulsating DC, which can then be smoothed by capacitors to provide a stable DC output for electronic devices. This includes full-wave and half-wave rectifier circuits.
  • Battery Chargers: Used to convert AC wall power into DC for charging batteries.
  • Voltage Regulation Circuits: Helps in maintaining a stable output voltage by rectifying current.
  • Protection Circuits: Its ability to block reverse current makes it useful for reverse polarity protection, preventing damage to sensitive components if the power supply is connected incorrectly.
  • Freewheeling Diode: Used in inductive circuits (like those with relays or motors) to provide a path for stored energy to dissipate when the current is switched off, preventing voltage spikes that could damage other components.
  • Voltage Doubler Circuits: Can be used in circuits designed to effectively double the input voltage.
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The 1N4007 is a very common and versatile silicon rectifier diode. It's part of the 1N400x series of general-purpose diodes, with the "7" indicating its specific voltage rating. Key Characteristics
  • Rectifier Diode: Its primary function is to convert alternating current (AC) into pulsating direct current (DC) by allowing current to flow in only one direction.
  • High Reverse Voltage Rating: The 1N4007 can withstand a peak repetitive reverse voltage () of 1000V. This makes it suitable for high-voltage applications.
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  • Forward Voltage Drop: When conducting in the forward direction, it has a relatively low forward voltage drop () of approximately 0.7V to 1.1V. This voltage drop represents the power lost within the diode.
  • Surge Current Capability: It can handle a non-repetitive peak surge current () of up to 30A for short durations, which is useful for handling initial power-on surges.
  • Package Type: It typically comes in a DO-41 axial-lead package, which is a small, cylindrical plastic package with leads on both ends.
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How it Works Like all diodes, the 1N4007 is a PN-junction device. It consists of a P-type semiconductor and an N-type semiconductor joined together.
  • Forward Bias: When a positive voltage is applied to the anode (P-side) and a negative voltage to the cathode (N-side), the diode is forward-biased. If the applied voltage exceeds the forward voltage drop (around 0.7V for silicon diodes), the diode conducts, allowing current to flow from anode to cathode.
  • Reverse Bias: When a negative voltage is applied to the anode and a positive voltage to the cathode, the diode is reverse-biased. In this state, the diode acts like an open switch, blocking current flow. The 1N4007 is designed to withstand up to 1000V in this reverse-biased state before breaking down.
Common Applications The 1N4007's robust characteristics make it popular in a wide range of electronic circuits, including:
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    • Half-wave and Full-wave Rectifiers: Essential for converting AC power from the mains (like in household appliances) to DC power for electronic devices.
    • Bridge Rectifiers: Used to convert the entire AC waveform into pulsating DC, achieving more efficient rectification.
  • Power Supplies: Used for rectifying the AC input in power supply units to provide DC voltage to various components.
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    • Reverse Polarity Protection: Prevents damage to circuits if the power supply is connected with incorrect polarity.
    • Freewheeling Diodes (Flyback Diodes): Protect sensitive components from voltage spikes generated by inductive loads (like relays, motors, and solenoids) when their magnetic field collapses.
    • Voltage Spike Suppression: Helps to suppress transient voltage spikes that can occur due to switching events or lightning, safeguarding delicate electronics.
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  • Current Flow Regulation: Can be used in simple current limiting or flow control applications.
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The Metal Case Diode Bridge KBPC5010 is a specific type of bridge rectifier, a crucial electronic component used to convert alternating current (AC) into direct current (DC). It is widely employed in various power supply applications. Here's a breakdown of its key features and what each part of its name signifies: What is a Bridge Rectifier? A bridge rectifier is a circuit of four (or more) diodes in a specific configuration that allows for full-wave rectification. This means it efficiently converts both the positive and negative half-cycles of an AC input into a pulsating DC output. Compared to simpler half-wave rectifiers, bridge rectifiers are more efficient and provide a smoother DC output.
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KBPC5010 Explained
  • KBPC: This is typically a series designation for a family of single-phase bridge rectifiers with specific package styles.
  • 50: This number indicates the maximum average forward rectified current (Io) the device can handle, which in this case is 50 Amperes (A). This high current rating makes it suitable for demanding applications.
  • 10: This number typically refers to the voltage class, often indicating a maximum repetitive peak reverse voltage (VRRM) of 1000 Volts (V) (where '10' often means 10 x 100V). This high voltage rating allows it to handle substantial AC input voltages.
Metal Case Design The "metal case" is a significant feature. The metal housing serves as a heat sink, which is essential for dissipating the heat generated by the diodes during operation, especially when handling high currents. This helps maintain optimal operating temperatures, ensuring the device's reliability and longevity. The case often has a central mounting hole for easy attachment to an external heat sink for even better thermal management. The internal components are usually encapsulated with epoxy resin for electrical insulation and flame resistance. Key Specifications and Features
  • Conversion: Converts single-phase AC to pulsating DC.
  • Current Rating: Up to 50 Amperes (A) average forward current.
  • Voltage Rating: Up to 1000 Volts (V) repetitive peak reverse voltage.
  • Surge Current Capability: Often capable of handling high non-repetitive surge currents (e.g., 400A or 450A for a short duration), which is crucial for handling initial power-on transients.
  • Low Forward Voltage Drop: Minimizes power loss and improves efficiency.
  • High Reliability: Designed for robust performance in various environments.
  • Mounting: Typically features through-hole mounting with a screw hole for chassis or heatsink mounting.
  • Terminals: Often uses 0.25" (6.35 mm) Faston terminals for easy connection. Some variants (like KBPC5010W) might have wire leads.
  • Operating Temperature: Wide operating junction temperature range, often from -40°C to +150°C.
Common Applications Due to its high current and voltage capabilities, the KBPC5010 is commonly found in:
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  • Battery chargers: Converting AC power to DC for charging batteries.
  • Motor control circuits: Providing DC power for electric motors.
  • Industrial control systems: Used in various industrial applications requiring AC-to-DC conversion.
  • Input rectifiers for variable frequency drives (VFDs).
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    • Microwave ovens: To detect if the door is closed before operating.
    • Washing machines: For door interlocks and water level detection.
    • Refrigerators: To turn the light on/off when the door opens/closes.
    • Printers: To detect paper jams or the position of paper.
  • Automotive Industry:
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    • Brake pedals: To activate brake lights.
    • Seat belt mechanisms: To detect if a seat belt is fastened.
  • Industrial Automation:
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    • Machine safety guards: To ensure guards are correctly positioned before machinery operates.
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  • Spring Plunger: A plunger supported by a spring, allowing for a certain degree of "overtravel" beyond the actuation point without damaging the switch.
Other variations include sealed micro switches for harsh environments (resistant to dust and moisture) and subminiature types for extremely compact applications.
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Universal light with barriers for any door design automation. The range can be reduced to 30% in bad weather conditions: fog, rain, dust, etc. Compatible with all models of gate openers, such as single swing, double swing, and sliding gates. When someone passes the infrared region, the detector will send an alarm signal to the control board(which is not included).
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