Presentation is loading. Please wait.

Presentation is loading. Please wait.

Lesson 3 ENERGY, WORK, AND HEAT DEFINE the following: – Heat – Latent heat – Sensible heat – Units used to measure heat DEFINE the following thermodynamic.

Published byNoreen Hodge Modified over 8 years ago

Similar presentations

Presentation on theme: "Lesson 3 ENERGY, WORK, AND HEAT DEFINE the following: – Heat – Latent heat – Sensible heat – Units used to measure heat DEFINE the following thermodynamic."— Presentation transcript:

1 Lesson 3 ENERGY, WORK, AND HEAT DEFINE the following: – Heat – Latent heat – Sensible heat – Units used to measure heat DEFINE the following thermodynamic properties: – Specific enthalpy – Entropy

2 Energy The capacity of a system to perform work or produce heat Categories – Potential Energy – Kinetic Energy – Specific Internal Energy – Specific P-V Energy – Enthalpy – Work – Heat – Entropy

3 Potential Energy Energy of position PE = mgz/g c where PE = potential energy (ft-lbf) m = mass (lbm) z = height above some reference level (ft) g = acceleration due to gravity (32.17 ft/sec 2 ) g c = gravitational constant = 32.17 ft-lbm/lbf-sec 2

4 Kinetic Energy Energy of motion KE = mv 2 /2g c where: KE = kinetic energy (ft-lbf) m = mass (lbm) v = velocity (ft/sec) g c = gravitational constant = 32.17 ft-lbm/lbf-sec 2

5 Specific Internal Energy Internal energy per unit mass Equal to total internal energy (U) divided by the total mass (m). u = U/m where: u = specific internal energy (Btu/lbm) U = internal energy (Btu) m = mass (lbm) Internal energy includes – Energy due to rotation, vibration, translation, and interactions among molecules – Can not be measured or evaluated directly

6 Specific P-V Energy Energy per unit mass. Equals the total Pressure times the Volume of a liquid divided by the total mass m Also equals the product of the pressure P and the specific volume v, and is written as Pv Pv = PV/m where: P = pressure (lbf/ft 2 ) V = volume (ft 3 ) n = specific volume (ft 3 /lbm) V m m = mass (lbm)

7 Enthalpy A property of a substance, like pressure, temperature, and volume, Cannot be measured directly Normally given with respect to some reference value. Usually used in connection with an "open" system problem in thermodynamics Specific enthalpy (h) h = u + Pv where u is the specific internal energy (Btu/lbm) P is the pressure of the system (lbf/ft 2 ) v is the specific volume (ft 3 /lbm) of the system.

8 Work Energy in transit Not a property of a system – it is a process done by or on a system Defined as the action of a force on an object through a distance W = Fd where: W = work (ft-lbf) F = force (lbf) d = displacement (ft)

9 Heat Like work, is energy in transit Occurs at the molecular level as a result of a temperature difference Denoted by the letter Q Heat transferred per unit mass denoted by q q = Q/m where: q = heat transferred per unit mass (Btu/lbm) Q = heat transferred (Btu) m = mass (lbm)

10 Heat (continued) Sensible Heat - The heat added to or removed from a substance to produce a change in its temperature Latent Heat - The amount of heat added to or removed from a substance to produce a change in phase. – Latent Heat of Fusion - the amount of heat added or removed to change phase between solid and liquid. – Latent Heat of Vaporization - the amount of heat added or removed to change phase between liquid and vapor

11 Heat Capacity The ratio of the heat (Q) added to or removed from a substance to the change in temperature (ΔT) produced Denoted by C p Specific heat (c p ) is heat capacity of a substance per unit mass Applies when the heat is added or removed at constant pressure

12 Heat Capacity (continued) C p = Q/ΔT c p = Q/mΔT c p = q/ΔT where: C p = heat capacity at constant pressure (Btu/°F) c p = specific heat at constant pressure (Btu/lbm-°F) Q = heat transferred (Btu) q = heat transferred per unit mass (Btu/lbm) m = mass (lbm) ΔT = temperature change (°F)

13 Entropy (S) A property of a substance Quantifies the energy of a substance that is no longer available to perform useful work ΔS = ΔQ/T abs Δ s = Δq/T abs where: Δ S = the change in entropy of a system during some process (Btu/°R) ΔQ = the amount of heat transferred to or from the system during the process (Btu) T abs = the absolute temperature at which the heat was transferred (°R) Δs = the change in specific entropy of a system during some process (Btu/lbm -oR) Δq = the amount of heat transferred to or from the system during the process (Btu/lbm)

14 Power Power - The time rate of doing work. Units are energy per unit time – English system - ft-lbf/sec or ft-lbf/hr – Horse Power - hp – British thermal units per hour - Btu/hr – Electrical units - watts (W) or kilowatts (kW)

15 Energy and Power Equivalencies 1 ft-lbf = 1.286 x 10 -3 Btu = 3.766 x 10 -7 kW-hr 1 Btu = 778.3 ft-lbf = 2.928 x 10 -4 kW-hr 1 kW-hr = 3.413 x 10 3 Btu = 2.655 x 10 6 ft-lbf 1 hp-hr = 1.980 x 10 6 ft-lbf 1 Joule = 778 ft lbf/Btu 1 ft-lbf/sec = 4.6263 Btu/hr = 1.356 x 10 -3 kW 1 Btu/hr = 0.2162 ft-lbf/sec = 2.931 x 10 -4 kW 1 kW = 3.413 x 10 3 Btu/hr = 737.6 ft-lbf/sec 1 hp = 550.0 ft-lbf/sec

Download ppt "Lesson 3 ENERGY, WORK, AND HEAT DEFINE the following: – Heat – Latent heat – Sensible heat – Units used to measure heat DEFINE the following thermodynamic."

Similar presentations

PTT 201/4 THERMODYNAMICS SEM 1 (2012/2013) 1. light Energy can exist in numerous forms: Thermal Mechanical Kinetic Potential Electric Magnetic Chemical.

PTT 201/4 THERMODYNAMICS SEM 1 (2012/2013) 1. light Energy can exist in numerous forms: Thermal Mechanical Kinetic Potential Electric Magnetic Chemical.
18 Heat and the First Law of Thermodynamics Heat Capacity and Specific Heat Change of Phase and Latent Heat Joule’s Experiment and the First Law of Thermodynamics.

18 Heat and the First Law of Thermodynamics Heat Capacity and Specific Heat Change of Phase and Latent Heat Joule’s Experiment and the First Law of Thermodynamics.
What is energy?. Chain of energy Newton’s Laws 1.An object in motion will stay in motion (or rest at rest) unless acted on by an outside force. (Inertia)

What is energy?. Chain of energy Newton’s Laws 1.An object in motion will stay in motion (or rest at rest) unless acted on by an outside force. (Inertia)
Energy in Thermal Processes

Energy in Thermal Processes
Physics Lab 2008-Energy. Linear Work  The act of exerting a force through a distance in the direction of the force (constant)  W = F  x cos   F =

Physics Lab 2008-Energy. Linear Work  The act of exerting a force through a distance in the direction of the force (constant)  W = F  x cos   F =
Solid Liquid Gas Q = mL f Q = mL v fusion Vaporization When a change of phase occurs, there is only a change in potential energy of the molecules. The.

Solid Liquid Gas Q = mL f Q = mL v fusion Vaporization When a change of phase occurs, there is only a change in potential energy of the molecules. The.
Thermal Force Unit 1.4.

Thermal Force Unit 1.4.
QFocus. QFocus pt 2 QFocus pt 3 You can design, build, and refine a device that works to convert one form of energy into another form of energy.

QFocus. QFocus pt 2 QFocus pt 3 You can design, build, and refine a device that works to convert one form of energy into another form of energy.
PM3125 Content of Lectures 1 to 6: Heat transfer: Source of heat

PM3125 Content of Lectures 1 to 6: Heat transfer: Source of heat
Thermodynamics I: Energy & Heat Transfer Objectives Comprehend the various forms of energy including potential/kinetic, thermal, and mechanical Comprehend.

Thermodynamics I: Energy & Heat Transfer Objectives Comprehend the various forms of energy including potential/kinetic, thermal, and mechanical Comprehend.
Objectives Review thermodynamics

Objectives Review thermodynamics
Chapter 11 Energy in Thermal Processes. Energy Transfer When two objects of different temperatures are placed in thermal contact, the temperature of the.

Chapter 11 Energy in Thermal Processes. Energy Transfer When two objects of different temperatures are placed in thermal contact, the temperature of the.
Igneous Petrology Course Lecturer: Matt Genge, Meteorite Researcher, Previously worked at The Natural History Museum. Lectures: Part I (4 weeks) Igneous.

Igneous Petrology Course Lecturer: Matt Genge, Meteorite Researcher, Previously worked at The Natural History Museum. Lectures: Part I (4 weeks) Igneous.
Heat Engines Coal fired steam engines. Petrol engines Diesel engines Jet engines Power station turbines.

Heat Engines Coal fired steam engines. Petrol engines Diesel engines Jet engines Power station turbines.
THERMODYNAMICS I INTRODUCTION TO NAVAL ENGINEERING.

THERMODYNAMICS I INTRODUCTION TO NAVAL ENGINEERING.
Chapter 5 Temperature and Heat Another Kind of Energy.

Chapter 5 Temperature and Heat Another Kind of Energy.
Objectives Learn basics about AHUs Review thermodynamics - Solve thermodynamic problems and use properties in equations, tables and diagrams.

Objectives Learn basics about AHUs Review thermodynamics - Solve thermodynamic problems and use properties in equations, tables and diagrams.
Thermodynamic Properties of Water PSC 151 Laboratory Activity 7 Thermodynamic Properties of Water Heat of Fusion of Ice.

Thermodynamic Properties of Water PSC 151 Laboratory Activity 7 Thermodynamic Properties of Water Heat of Fusion of Ice.
Chapter 12 Temperature and Heat Temperature – Average kinetic energy of molecules. Heat – Transfer of energy due to temperature difference; flows from.

Chapter 12 Temperature and Heat Temperature – Average kinetic energy of molecules. Heat – Transfer of energy due to temperature difference; flows from.
ENERGY The measure of the ability to do work Conservation of energy -energy can change forms but can not be destroyed -the total amount of energy in the.

ENERGY The measure of the ability to do work Conservation of energy -energy can change forms but can not be destroyed -the total amount of energy in the.

Similar presentations

Ads by Google