Abstract
1.1. INTRODUCTION TO THERMODYNAMICS, FLUID FLOW,
AND HEAT TRANSFER
Thermodynamics, fluid flow, and heat transfer not only play an important role
in science and engineering but also in everyday life. For example, gasoline
vehicles operate on the Otto cycle, residential air-conditioners are developed
based on the vapor-compression refrigeration cycle, steam turbines are the
central unit in traditional power plants, and flow meters and pipe flows are
inherent in both industrial and residential applications.
ANALYSIS OF EXPERIMENTAL DATA
Page: 15-35 (21)
Author: Yun Wang*
DOI: 10.2174/9781681089195123010005
PDF Price: $15
Abstract
2.1 INTRODUCTION
In an experiment, one major task is to conduct measurements for collecting
data. A large number of measurement data can be the direct outcome of
experimental work. In general, the more data the better. Statistics is a popular
valuable tool for experimentalists to conduct data analysis and eventually draw
conclusions from data processing. The mean of a data sample is usually used
as the final result for a measurement. The standard deviation of the sample
measures the confidence of the final result and is usually used as additional
information. In addition, each measurement needs to be independent so that
the data set is equally weighed. Statistics may be used in experimental design
and plan. Indeed, before conducting an experiment, several aspects need to be
considered in preparation, including the selection of apparatus, relevant
mathematical correlations, and uncertainty estimate of the final results.
Selecting the proper apparatus is essential to any experimental work. For
example, temperature measurement requires thermometers. There are several
types of thermometers with various ranges and resolutions. A high-resolution
apparatus is usually expensive and requires training before use. However, low-resolution apparatuses usually lead to a large standard deviation or uncertainty
in the final result. In engineering applications, uncertainty needs to be within
tolerance to avoid component mismatch or design failures. Understanding how
the apparatus’ resolution is related to the measurement error or uncertainty and
how the error or uncertainty propagates to the final value is thus fundamentally
important for experimental design, which will be introduced in this chapter.
Abstract
3.1. INTRODUCTION
Heat transfer is a subject that deals with the generation, use, conversion, and
exchange of thermal energy between a system and its surroundings. At the
molecular level, we can visualize thermal energy by the motion of particles and
quantify it by the overall kinetic energy of all the particles. Heat transfer can
then be explained as an exchange of the kinetic energy among particles via
collisions or interactions. In a gas, the particles move faster, on average, under
higher temperatures and transfer their kinetic energy to particles at lower
temperatures through collisions. In a solid, the particles vibrate faster under
higher temperatures and transfer their kinetic energy to particles at lower
temperatures through molecular interactions.
Abstract
4.1. INTRODUCTION
Power plants or generating stations are facilities for generating electric power,
which has become essential to our present lifestyle. Electric power supports
many of our daily activities, including lighting, air circulation, HVAC, TV
watching, cell phones, computers, elevators, etc. The generated power is
delivered using complex systems of wires, towers, underground stations,
transformers, control stations, etc., to consumer sites such as homes,
apartments, stores, industry, and schools. These interconnected systems are
known as grids.
PIPE FLOW AND FLOW METERING
Page: 81-101 (21)
Author: Yun Wang*
DOI: 10.2174/9781681089195123010008
PDF Price: $15
Abstract
5.1 INTRODUCTION
Flow and volume measurement of incompressible fluids are prevalent in many
engineering processes. Flows in a pipe network, also called pipe flow, are
widely encountered in industry and our daily activities. For example, water is
delivered to homes via the pipelines of a water distribution infrastructure. In
power plants, numerous pipe flows are used to transport liquid, vapor, and two-phase flows: steam produced in boilers is transported in pipes to steam turbines
for energy conversion. Boiler feed water (BFW) is pumped to a boiler via a
BFW pipe.
EFFICIENCIES IN POWER PLANT
Page: 102-120 (19)
Author: Yun Wang*
DOI: 10.2174/9781681089195123010009
PDF Price: $15
Abstract
6.1 INTRODUCTION
In thermodynamics, several major devices related to energy conversion are
introduced, including the internal combustion engines (ICE), steam turbine,
boiler, heat exchanger, and heat pump. Thermal efficiency is a dimensionless
performance measure of these devices. In general, thermal efficiency is the
fraction of energy addition in the form of heat or thermal energy converted to
useful output, as shown in Fig. (6.1), given as a percentage value. The
nominally Otto-cycle ICE in automobiles can reach about 30% efficiency at
the flywheel. Rankine-cycle steam turbine thermal efficiency can be as high as
41%. In heat pump cycles where heat rejection in the high-temperature side is
the useful output, the efficiency is usually defined as the ratio of the rejected
heat to the compressor work input, commonly called the coefficient of
performance (COP). Refrigeration moves heat from a confined space and
dissipates it in the atmosphere. Heat pumps move heat from one spot (often
from the atmosphere or underground) to a home of business. Residential
refrigerators and air conditioners are based on a vapor-compression
mechanical refrigeration cycle. The former generally has a COP over 1 in
practice, while the latter may have a COP over 3 to 5. The COP of heat pumps
is generally higher than that of their refrigerator counterparts.
Abstract
7.1 INTRODUCTION
Wind tunnels provide controlled air streams to study aerodynamic and fluid
flow phenomena. They are frequently used to replicate the actions of an object
flying or moving in an air stream, such as airplanes or vehicles. Table 7.1 lists
several types of wind tunnels. Most wind tunnels are designed to have a
uniform velocity profile in the test section at a low turbulence level. The testing
object is placed in the test section for flow visualization and quantitative
measurements such as lift and drag forces. To create an air flow, electric fans
are usually used to blow air in or out of the tunnel. In large wind tunnels for
testing real-size airplanes, rockets, or cars, powerful fans are required to
generate a wind speed comparable with real conditions.
OTTO AND DIESEL CYCLES
Page: 138-159 (22)
Author: Yun Wang*
DOI: 10.2174/9781681089195123010012
PDF Price: $15
Abstract
8.1. INTRODUCTION
Otto and Diesel cycle engines play an important role in our transportation and energy
use. They are typically reciprocating heat engines that convert the thermal energy from
fuel combustion to mechanical energy in the form of piston movement. The mechanical
energy further drives a vehicle over a distance. The Otto and diesel cycle engines are
the most common engine in passenger cars, light trucks, and other applications where
small (10 Hp) to medium power (500 Hp) is required. Some large turbo supercharged
radial aircraft engines reach 5,000 Hp. Applications of small power, such as
lawnmowers and hand-held devices like trimmers and chain saws, require a level of
100-1,000 W power. Typical values of their thermal efficiency are 30-35% for Otto
cycle engines and 30-40% for Diesel engines. Small utility-type engines may have
~20% efficiency due to simple design and control. While the basic principles of these
reciprocating engines have not changed significantly since invention, advances in fuel
induction, ignition systems, and exhaust emission controls have improved economy
and performance and reduced pollution.
REFRIGERATION
Page: 160-176 (17)
Author: Yun Wang*
DOI: 10.2174/9781681089195123010013
PDF Price: $15
Abstract
9.1. INTRODUCTION
Refrigerators and air conditioners are popular and important devices in our
daily lives. The former provides a low-temperature environment to store food
and drink, while the latter reduces the indoor temperature to a comfortable
level. In nature, we observe that heat flows from a higher temperature toward
a lower temperature. To reverse the heat flow from a low to high temperature,
mechanical work needs to be added to enable mechanical refrigeration, by
which a low-temperature environment is created for food saving or air
conditioning. The most important feature of mechanical refrigeration is its high
efficiency, usually called the coefficient of performance (COP): the COP of
residential refrigerators is usually above one, and air conditioners can achieve
even five. While other refrigeration methods have been developed, based on
different physical principles, such as vortex tubes and thermoelectric coolers,
their efficiencies, in general, are much less than one, and we use them for
special applications where their other characteristics make them attractive.
REPORT PREPARATION
Page: 177-189 (13)
Author: Yun Wang*
DOI: 10.2174/9781681089195123010014
PDF Price: $15
Abstract
10.1. OVERVIEW
To formally document a laboratory experiment, a written technical report is
prepared. However, it should be noted that detailed lab notes compiled during
the experiment are essential, so they can be used later in the full written report.
The overall goal for any laboratory report is to summarize an experiment
efficiently for an intended audience. Therefore, knowing who will read the
laboratory report (e.g. researchers in a similar field in a technical journal,
business leaders in a company as an internal white paper, or the general public
for mass consumption) will dictate the style, the tone and the level of technical
jargon needed in the written work. After identifying the target audience, the
lab report should explain the purpose of the experiment, the research questions
answered, the experimental procedures, the data observed, the analysis method
and the results.
Introduction
Practical Handbook of Thermal Fluid Science is an essential guide for engineering students to practical experiments and methods in fluid mechanics. It presents the topic of practical fluid physics in a simple, clear manner by introducing the fundamentals of carrying out experiments and operational analysis of systems that are based on fluid flow. The information enables readers to relate principles in thermal fluid science with the real world operation of important instruments that greatly impact our daily life, such as power generators, air conditioners, refrigerators, engines, flow meters, airplanes, among others. Key Features: - A simple organized chapter layout that focuses on fundamental and practical information about thermal fluid science experiments and equipment - Provides an introduction to essential knowledge for analysis and evaluation of practical systems and major inventions - Presents information about analysis of operating data for power plant efficiency - Detailed chapters for studying and testing wind tunnels, sphere heating/cooling, pipe flow, engines, and refrigerators/heat pumps are provided - Experimental data of Venturi and orifice plate flow meters are provided to show step by step calibration and experimentation. - Presents information on report preparation - Includes multiple appendices to consolidate practical information for readers for quick reference.