Glossary

2.3 Applications of the First Law

3 min readjuly 23, 2024

Energy analysis using the First Law is crucial for understanding how systems conserve and transfer energy. This concept applies to closed systems like piston-cylinders and open systems like turbines, helping us calculate changes in , heat, and work.

, , and heat pumps are practical applications of energy analysis. By using the First Law, we can determine their efficiency or coefficient of performance, which is essential for optimizing these devices in real-world scenarios.

Energy Analysis using the First Law

Energy balances in systems

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  • states energy is conserved in a
    • Change in internal energy (ΔU\Delta U) equals sum of heat added to system (QQ) and on system (WW)
    • Mathematical representation: ΔU=Q+W\Delta U = Q + W
  • For (no mass flow across boundaries):
    • ΔU=QW\Delta U = Q - W, where WW is work done by system (piston-cylinder device)
  • For (mass flow across boundaries):
    • First Law modified to include energy associated with mass flow
    • ΔU=QW+mihimehe\Delta U = Q - W + \sum m_i h_i - \sum m_e h_e, where mim_i and mem_e are masses entering and exiting system, and hih_i and heh_e are respective specific enthalpies (turbine, compressor)

Heat engines and refrigerators

  • Heat engines convert thermal energy into mechanical work
    • Efficiency (η\eta) of heat engine: η=WnetQH=1QCQH\eta = \frac{W_{net}}{Q_H} = 1 - \frac{Q_C}{Q_H}, where WnetW_{net} is net work output, QHQ_H is heat input from hot reservoir, and QCQ_C is heat rejected to cold reservoir (internal combustion engine, steam turbine)
  • Refrigerators and heat pumps transfer heat from cold reservoir to hot reservoir
    • Coefficient of Performance (COP) for refrigerator: COPR=QCWnetCOP_R = \frac{Q_C}{W_{net}} (household refrigerator, air conditioner)
    • Coefficient of Performance (COP) for heat pump: COPHP=QHWnetCOP_{HP} = \frac{Q_H}{W_{net}} (geothermal heat pump, reverse cycle air conditioner)
  • Apply First Law to determine , work, and efficiency or COP for these devices

Thermodynamic Cycles and Efficiency

Efficiency of thermodynamic cycles

  • : idealized, reversible cycle operating between two thermal reservoirs
    • Consists of four processes: isothermal expansion, adiabatic expansion, isothermal compression, and adiabatic compression
    • : ηCarnot=1TCTH\eta_{Carnot} = 1 - \frac{T_C}{T_H}, where TCT_C and THT_H are absolute temperatures of cold and hot reservoirs
  • : practical vapor power cycle used in steam power plants
    • Consists of four processes:
      1. Isentropic compression (pump)
      2. Constant-pressure heat addition (boiler)
      3. Isentropic expansion (turbine)
      4. Constant-pressure heat rejection (condenser)
    • Rankine cycle efficiency: ηRankine=WnetQin=WtWpQin\eta_{Rankine} = \frac{W_{net}}{Q_{in}} = \frac{W_t - W_p}{Q_{in}}, where WtW_t is turbine work, WpW_p is pump work, and QinQ_{in} is heat input in boiler

Performance of real-world systems

  • Real-world systems involve irreversibilities and energy losses, such as:
    • Friction (bearings, seals)
    • Heat transfer across finite temperature differences (heat exchangers)
    • Unrestrained expansion (throttling valves)
  • Irreversibilities reduce efficiency of real-world systems compared to ideal, reversible systems
  • To analyze real-world systems:
    1. Identify sources of irreversibility and energy losses
    2. Apply First Law, accounting for these losses
    3. Calculate actual efficiency or COP of system
  • Strategies to improve efficiency:
    • Minimize irreversibilities (reduce friction, optimize heat transfer)
    • Recover waste heat for useful purposes (cogeneration, regeneration)
    • Use high-performance materials and components (advanced alloys, ceramics)

Key Terms to Review (20)

Adiabatic process: An adiabatic process is a thermodynamic process in which no heat is exchanged between the system and its surroundings. This means that any change in the internal energy of the system is entirely due to work done on or by the system, making it a critical concept in understanding various thermodynamic cycles and processes.
Carnot Cycle: The Carnot cycle is an idealized thermodynamic cycle that represents the most efficient way to convert heat into work, consisting of two isothermal and two adiabatic processes. This cycle serves as a benchmark for all real heat engines, highlighting the limits of efficiency based on the temperatures of the heat reservoirs involved.
Carnot Efficiency: Carnot efficiency is the maximum theoretical efficiency of a heat engine operating between two temperature reservoirs, derived from the second law of thermodynamics. This concept sets an upper limit on the efficiency of all real heat engines, emphasizing the importance of reversible processes and the temperature difference between the heat source and sink in achieving optimal performance.
Closed System: A closed system is a type of thermodynamic system that can exchange energy, but not matter, with its surroundings. This means that while energy in the form of heat or work can enter or leave the system, the total mass remains constant as no substances can cross its boundaries. Understanding closed systems is essential for analyzing energy conservation and various thermodynamic processes.
Cop - coefficient of performance: The coefficient of performance (COP) is a measure of the efficiency of a heating or cooling system, defined as the ratio of useful heating or cooling provided to the work input required to operate the system. A higher COP indicates a more efficient system, where less energy is consumed for the same amount of heating or cooling. This term is crucial in evaluating energy use in devices such as refrigerators, air conditioners, and heat pumps, linking it closely to the principles of energy conservation and thermodynamic efficiency.
Enthalpy: Enthalpy is a thermodynamic property that represents the total heat content of a system, defined as the sum of its internal energy and the product of its pressure and volume. This concept is crucial in understanding how energy is exchanged in processes, especially in the context of thermodynamic systems and the transformations they undergo.
First Law of Thermodynamics: The First Law of Thermodynamics states that energy cannot be created or destroyed, only transformed from one form to another. This principle emphasizes the conservation of energy within a closed system, illustrating how energy transfers and transformations impact thermodynamic processes and systems.
Heat Engines: Heat engines are devices that convert thermal energy into mechanical work by taking in heat from a high-temperature source and releasing some of that heat to a lower temperature sink. This process is governed by the principles of thermodynamics, particularly the first and second laws, which dictate the efficiency and limitations of how heat can be transformed into work.
Heat Transfer: Heat transfer is the process of thermal energy moving from one object or system to another due to a temperature difference. This fundamental concept connects various phenomena, including how systems reach thermodynamic equilibrium and how energy is conserved in different processes.
Internal Energy: Internal energy is the total energy contained within a thermodynamic system, encompassing kinetic and potential energies of all the molecules in the system. This energy is crucial in determining the state of the system and plays a key role in thermodynamic processes, including heat transfer and work done on or by the system.
Isothermal process: An isothermal process is a thermodynamic process in which the temperature of the system remains constant while heat is exchanged with the surroundings. This constant temperature implies that any internal energy changes in the system are fully compensated by heat transfer, making it an essential concept in understanding how systems behave under thermal equilibrium and the laws governing energy conservation.
Open System: An open system is a type of thermodynamic system that can exchange both matter and energy with its surroundings. This characteristic allows for the flow of mass and energy, enabling various processes to occur, such as chemical reactions, heat transfer, and fluid movement, all of which are essential in understanding fundamental thermodynamic principles.
Q = mcΔt: The equation $$q = mcΔt$$ expresses the relationship between heat transfer, mass, specific heat capacity, and temperature change. It helps in understanding how much heat energy is required to change the temperature of a substance. In this context, 'q' represents the heat absorbed or released, 'm' is the mass of the substance, 'c' is the specific heat capacity, and 'Δt' is the change in temperature. This formula is crucial for analyzing energy changes in various processes, including heating, cooling, and phase changes.
Rankine Cycle: The Rankine Cycle is a thermodynamic cycle that converts heat into work, typically used in steam power plants. It involves the processes of heating, phase change, and cooling of a working fluid, usually water, to generate mechanical energy that can be converted into electricity. This cycle is vital in understanding how energy is transformed and utilized in various applications, linking thermal efficiency and energy conversion principles.
Refrigerators: Refrigerators are devices that transfer heat from a lower temperature region to a higher temperature region, utilizing the principles of thermodynamics to keep items cool. They operate on the refrigeration cycle, which involves the compression, condensation, expansion, and evaporation of a refrigerant. This process allows refrigerators to maintain a cold environment inside while releasing heat to the surroundings, showcasing important applications of energy conservation and heat transfer.
Surroundings: Surroundings refer to everything outside a thermodynamic system that can interact with the system and influence its properties. Understanding the surroundings is crucial as they play a key role in energy transfers and thermodynamic processes, often affecting temperature, pressure, and phase changes within the system.
System: A system in thermodynamics refers to a specific portion of matter or space that is being studied, which is separated from its surroundings by a defined boundary. This boundary can be real or imaginary, and it helps in analyzing energy and mass transfer between the system and its surroundings, facilitating the application of fundamental laws and principles such as energy conservation, entropy changes, and transformations of internal energy and enthalpy.
Thermal Efficiency: Thermal efficiency is a measure of how well a system converts heat energy into useful work. It's expressed as a ratio of the work output of the system to the heat input, highlighting how effectively a thermal system operates. Understanding thermal efficiency is crucial for evaluating energy performance in various thermodynamic applications, including engines and power cycles.
Work Done: Work done refers to the energy transferred when a force is applied to an object, causing it to move a certain distance in the direction of that force. This concept is essential for understanding how energy interacts with systems, particularly when examining changes in internal energy and the application of energy conservation principles.
δu = q - w: The equation δu = q - w expresses the First Law of Thermodynamics, which states that the change in internal energy (δu) of a system is equal to the heat added to the system (q) minus the work done by the system (w). This principle highlights the conservation of energy, showing how energy can be transferred into or out of a system in the form of heat or work, ultimately affecting the system's internal energy.
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