ENERGY ENGINEERING AND MANAGEMENT FOR BUILDING SYSTEMS
by William J. Coad
1: Pure versus applied science
2: The engineering design process
3: Design parameters
4: Evaluation functions
5: The influence of "fads" on design
6: The value of simplicity in design
7: Specialty devices in engineered systems
8: No details are minor
9: The new technology may be closer than we realize
10: A re-examination of engineering education
11: Education: the primary ingredient in the solution of the energy dilemna
12: The professional's role in energy management
13: A chronology of building systems technology, 1929 through 1979
14: Can we afford engineering?
15: A primer on energy
16: A definition of energy
17: Energy is a unique commodity
18: Energy transportation
19: Infinite source
20: An energy resource standard
21: Energy economics is a needed science
22: The energy hypothesis
23: A case history study illustrating the need for energy economics in design
24: A proposed format for organizing the study of building energy economics
25: Return to regionalism in building design
26: Infinite sink?
27: Second law concepts
28: Energy management
29: Building automation systems
30: The laundry list
31: Energy audits
32: The structure of electric utility rates
33: Local building codes and energy conservation
34: The value of standards to society
35: The potential for the computer in the design of building environment systems
36: A reevaluation of computer use
37: The computer as a tool for energy analysis
38: Computer applications for systems design and analysis
39: Energy effective machinery can be self-financing (a case history)
40: Investment optimization: a methodology for life cycle cost analysis
41: Single equation for cogeneration financial feasibility determination
42: Selecting an energy source and conversion system
43: The myth of free steam
44: An oil-fired integrated plant design
45: The status of total energy
46: Hydronic systems overview
47: Integrated decentralized chilled water system
48: A case study of an integrated decentralized chilled water system
49: Preheating outdoor air with transfer fluid systemsa
50: A state of the art update in steam technology
51: Vapor lock in refrigeration systems
52: Correct use of the fan curve
53: Analysis of fan/system characteristics and applications
54: The relationships between system balance and energy use
55: Planned versus failure maintenance
56: Lack of effective maintenance causes excessive energy consumption
57: Designing for reliability
58: Consumer concerns relating to durability, reliability, and serviceability
59: Thermodynamic versus system efficiency
60: Thermal effectiveness of a vapor compression cycle
61: Energy-effectiveness factor