Concentrated Solar Power Systems

☀️Concentrated Solar Power Systems Unit 4 – Heat Transfer Fluids & Thermal Storage

Heat transfer fluids and thermal storage are crucial components in concentrated solar power systems. They enable efficient energy capture, transport, and storage, allowing for continuous power generation even when the sun isn't shining. This unit covers the fundamentals of heat transfer, types of heat transfer fluids, and thermal storage materials. It also explores selection criteria, system design, performance metrics, safety considerations, and emerging technologies in this rapidly evolving field.

Fundamentals of Heat Transfer

  • Heat transfer involves the exchange of thermal energy between systems or within a system
  • Three primary modes of heat transfer: conduction, convection, and radiation
    • Conduction occurs through direct contact between substances (solids, liquids, or gases)
    • Convection involves the transfer of heat via the movement of fluids or gases
    • Radiation is the transfer of energy through electromagnetic waves without requiring a medium
  • Thermal conductivity is a material property that quantifies the ability to conduct heat
  • Fourier's law describes heat conduction and relates heat flux to the temperature gradient and thermal conductivity
  • Newton's law of cooling describes convective heat transfer and relates the rate of heat loss to the temperature difference and convective heat transfer coefficient
  • The Stefan-Boltzmann law describes radiative heat transfer and relates the total radiant heat power to the fourth power of the absolute temperature and emissivity
  • Thermal resistance is a measure of a material's ability to resist heat flow and is influenced by the material's properties and geometry

Types of Heat Transfer Fluids

  • Heat transfer fluids (HTFs) are used to transport thermal energy in concentrated solar power (CSP) systems
  • Commonly used HTFs include:
    • Molten salts (nitrate salts, chloride salts)
    • Synthetic oils (Therminol VP-1, Dowtherm A)
    • Water/steam
    • Air
    • Supercritical fluids (supercritical CO2)
  • Molten salts have high thermal stability, low vapor pressure, and good heat transfer properties
  • Synthetic oils have a wide operating temperature range and good thermal stability but lower thermal conductivity compared to molten salts
  • Water/steam is readily available and has high specific heat capacity but requires high pressures for high-temperature applications
  • Air is abundant and non-toxic but has low heat transfer coefficients and requires large heat exchangers
  • Supercritical fluids have high heat transfer coefficients and low viscosity but require high operating pressures

Properties of Thermal Storage Materials

  • Thermal storage materials are used to store excess thermal energy for later use in CSP systems
  • Key properties of thermal storage materials include:
    • High specific heat capacity to store more energy per unit mass
    • High thermal conductivity for efficient heat transfer
    • High density to minimize storage volume
    • Chemical and thermal stability over the operating temperature range
    • Low cost and wide availability
  • Sensible heat storage materials store energy by increasing their temperature (concrete, molten salts, rocks)
  • Latent heat storage materials store energy through phase change at a constant temperature (phase change materials like paraffin wax, salt hydrates)
  • Thermochemical storage materials store energy through reversible chemical reactions (metal hydrides, carbonates)
  • Dual-media storage systems combine a solid storage medium (rocks, ceramics) with a heat transfer fluid (air, molten salt) for improved heat transfer

Heat Transfer Fluid Selection Criteria

  • HTF selection depends on various factors related to the specific CSP application and operating conditions
  • Operating temperature range is a crucial factor, as the HTF must remain stable and maintain its properties over the desired temperature range
  • Thermal stability is essential to prevent HTF degradation and ensure long-term performance
  • Compatibility with materials of construction (piping, heat exchangers, storage tanks) to minimize corrosion and material degradation
  • Low vapor pressure to reduce the need for pressurization and minimize leakage risks
  • High specific heat capacity and thermal conductivity for efficient heat transfer and storage
  • Low viscosity to minimize pumping power requirements and improve heat transfer coefficients
  • Environmental and safety considerations, such as toxicity, flammability, and ecological impact
  • Cost and availability of the HTF, considering both initial investment and long-term operational costs

Thermal Storage System Design

  • Thermal storage systems are designed to store excess thermal energy and dispatch it when needed
  • Two-tank direct storage systems use separate hot and cold storage tanks, with the HTF serving as both the heat transfer and storage medium (molten salt systems)
  • Two-tank indirect storage systems use a separate HTF and storage medium, requiring additional heat exchangers (oil-based systems with molten salt storage)
  • Single-tank thermocline systems use a single tank with a thermal gradient, where hot and cold fluids are separated by buoyancy forces (molten salt or dual-media systems)
  • Packed-bed thermal storage uses a solid storage medium (rocks, ceramics) with a heat transfer fluid flowing through the bed
  • Thermal storage capacity is determined by the system's size, storage medium properties, and operating temperature range
  • Insulation and tank design are critical to minimize heat losses and maintain thermal stratification
  • Heat exchangers are designed to optimize heat transfer between the HTF and storage medium while minimizing pressure drops and thermal stresses

Efficiency and Performance Metrics

  • Thermal storage efficiency is a key performance metric, defined as the ratio of energy recovered to energy stored
  • Round-trip efficiency accounts for both charging and discharging processes and includes heat losses and parasitic energy consumption
  • Exergy efficiency considers the quality of stored energy and its ability to perform useful work
  • Capacity factor is the ratio of actual energy output to the maximum possible output over a given period
  • Dispatchability is the ability to provide energy on demand and is enhanced by thermal storage
  • Thermal cycling stability refers to the ability of the storage system to maintain performance over repeated charging and discharging cycles
  • Heat transfer effectiveness quantifies the performance of heat exchangers in the storage system
  • Pumping power and pressure drop should be minimized to reduce parasitic energy consumption and improve overall system efficiency

Safety and Environmental Considerations

  • HTF leakage and spills can pose safety and environmental risks, requiring proper containment and mitigation measures
  • Flammability and autoignition temperatures of HTFs must be considered in system design and operation
  • Toxicity and ecological impact of HTFs should be evaluated, and appropriate handling and disposal procedures must be followed
  • High-temperature molten salts can cause severe burns and require specialized personal protective equipment
  • Pressure relief valves and emergency shutdown systems are essential to prevent overpressurization and minimize the consequences of equipment failures
  • Regular maintenance and inspection of storage tanks, piping, and heat exchangers are necessary to ensure safe and reliable operation
  • Environmental impact assessments should consider the entire life cycle of the thermal storage system, including material sourcing, manufacturing, operation, and decommissioning
  • Proper training and safety protocols for personnel involved in the operation and maintenance of thermal storage systems are crucial
  • Advanced HTFs, such as nanofluids and ionic liquids, are being investigated to enhance heat transfer properties and thermal stability
  • Phase change materials (PCMs) with high energy density and tunable melting points are being developed for latent heat storage applications
  • Thermochemical storage systems using reversible chemical reactions are being explored for high-density, long-duration storage
  • Supercritical CO2 power cycles are being investigated for their potential to improve CSP system efficiency and reduce storage costs
  • Integrated thermal storage solutions, such as thermocline systems with dual-media storage, are being optimized for cost-effectiveness and performance
  • Advanced insulation materials, such as aerogels and vacuum insulation panels, are being developed to minimize heat losses in storage tanks and piping
  • Intelligent control strategies and predictive maintenance techniques are being implemented to optimize storage system operation and extend component lifetimes
  • Hybridization of CSP with other renewable energy technologies, such as photovoltaics and wind power, is being explored to enhance dispatchability and grid integration


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© 2024 Fiveable Inc. All rights reserved.
AP® and SAT® are trademarks registered by the College Board, which is not affiliated with, and does not endorse this website.