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- 1. Losses And Heat Dissipated Solid State Power Devices Design of Cooling System Presented by SAIF U REHMAN (K21EL048 Submitted to Engr. Kalsoom Bhagat
- 2. Losses And Heat Dissipated Solid State Power Devices Losses and heat dissipation in solid-state power devices are important considerations in the design and operation of electronic systems. Solid-state power devices include components like transistors, diodes, and integrated circuits that are used for various power applications. The primary sources of losses and heat dissipation in these devices are: 1. Conduction Losses 2. Switching Losses 3. Dynamic Losses 4. Junction Temperature Rise
- 3. Conduction Losses • These losses occur when the device is in the on-state (conducting). • In a conducting state, there is a finite resistance within the device, and current passing through it leads to power dissipation according to Ohm's law (P = I^2 * R). • Conduction losses are directly proportional to the current flowing through the device and the resistance of the device.
- 4. Switching Losses These losses occur during the switching transitions of the device (turning it on or off). Switching losses include: Turn-On Losses : When a solid-state device switches from the off-state to the on-state, there is a brief period where both voltage and current are high simultaneously. This results in power losses. Turn-Off Losses : Similar to turn-on losses, but occurring when the device switches from the on-state to the off-state. Turn-off losses are typically associated with the energy stored in the device's capacitance and inductance.
- 5. Dynamic Losses Junction Temperature Rise • Dynamic Losses: These losses are associated with the dynamic behavior of the device and can include things like reverse recovery losses in diodes and gate drive losses in MOSFETs. Dynamic losses depend on the specific behavior of the device during its switching transitions. • Junction Temperature: Rise: As power is dissipated within the device, its temperature can rise. Excessive temperature can degrade the device's performance and even lead to failure. It's essential to monitor and control the junction temperature to ensure the device operates within its specified limits.
- 6. Techniques To Manage Losses In Solid State Power Devices • Heat Sinking • Thermal Management • Gate Drive Optimization • Current Rating and Selection • Switching Frequency Control
- 7. Design of Cooling System Designing an effective cooling system is essential for preventing overheating and depends on the specific application and requirements. Whether you are designing a cooling system for a computer, an industrial process, a car engine, or a building, the basic principles remain the same. Here's a general outline of how to design a cooling system: Determine Cooling Requirements: • Identify the heat load: Calculate or measure the amount of heat that needs to be removed from the system. This is typically measured in watts or BTUs (British Thermal Units) per hour. • Define temperature requirements: Determine the desired temperature range for the system or component that needs to be cooled.
- 8. CONTD. Select Cooling Method: • Air Cooling: Uses air to dissipate heat. Common in electronics and some industrial applications. • Liquid Cooling: Uses a liquid coolant to absorb and transport heat. Common in engines and high- performance computing. • Phase-Change Cooling: Uses a refrigeration cycle to remove heat. Common in refrigeration and HVAC systems. • Passive Cooling: Relies on natural convection or heat sinks to dissipate heat without active components like fans or pumps. Calculate Heat Transfer Requirements: • Calculate the required heat transfer rate (Q) based on the heat load and temperature requirements. Use the formula: Q = mcΔT where Q is the heat load, m is the mass flow rate of the coolant, c is the specific heat capacity of the coolant, and ΔT is the temperature difference.
- 9. CONTD . Choose Cooling Components: Based on your selected cooling method, choose the appropriate cooling components: • Fans: For air cooling, select fans with the right airflow and static pressure ratings. • Heat Sinks: Consider heat sinks for components that generate significant heat, such as CPUs or power devices. • Liquid Cooling Components: If using liquid cooling, select pumps, radiators, water blocks, and tubing. • Refrigeration Systems: For specialized applications, such as medical equipment or industrial processes, consider refrigeration-based cooling systems.
- 10. CONTD. Calculate Heat Transfer Requirements: • Calculate the required heat transfer rate (Q) based on the heat load and temperature requirements. Use the formula: Q = mcΔT where Q is the heat load, m is the mass flow rate of the coolant, c is the specific heat capacity of the coolant, and ΔT is the temperature difference. Choose a Cooling Medium: • Select an appropriate cooling medium (air, water, refrigerant, etc.) based on the application and temperature requirements. Design Cooling Path: • Design the physical layout of the cooling system, including the routing of coolant lines, placement of heat exchangers, and positioning of fans or blowers.
- 11. CONTD. Safety and Maintenance: • Ensure that the cooling system is safe to operate and meets all relevant safety standards. • Establish a maintenance schedule to clean and inspect components, replace coolant, and address any wear or damage. Documentation: • Create detailed documentation of the cooling system design, including schematics, flow diagrams, component specifications, and operating procedures. The specific details of the cooling system design will vary widely depending on the application, so it's essential to tailor the design to your specific needs and constraints.