Energy use in production: a long-term analysis
Gespeichert in:
| 1. Verfasser: | |
|---|---|
| Format: | Abschlussarbeit Buch |
| Sprache: | English |
| Veröffentlicht: |
2002
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| Schlagworte: | |
| Online-Zugang: | Inhaltsverzeichnis |
| Beschreibung: | IV, 190 Bl. graph. Darst. |
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Datensatz im Suchindex
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| adam_text | Contents i_
Contents
Contents i
Figures iv
Tables iv
Symbols iv
1. INTRODUCTION 1
1.1 Power blackouts in the Knowledge Economy 1
1.2 Three levels of analyzing production 3
1.3 Outline of the argument 7
2. THE PHYSICAL PERSPECTIVE ON THE ECONOMY AND ITS
LIMITATIONS 9
2.1 Introduction 9
2.2 A brief history of energy in economics 9
2.2.1 Energy in economic theory 9
2.2.2 Energetic approaches to economic and cultural development 11
2.2.3 Energetic laws of evolution and systems development 14
2.2.4 Biophysical economics 16
2.2.5 Problems of energetic approaches to the economy 16
2.3 Thermodynamic concepts and economic applications 17
2.3.1 The first and second laws of thermodynamics 17
2.3.2 Economic applications of thermodynamic concepts 21
2.3.3 Exergy as an encompassing thermodynamic variable 24
2.4 Thermodynamics of open systems 30
2.4.1 Open systems and the self organization of dissipative structures 30
2.4.2 On the relationship between self organization and evolutionary change 32
2.5 Implications of thermodynamic concepts for production and economic
evolution 35
2.5.1 The necessity of exergy as an input into production 35
2.5.2 The output side: on the ubiquity of joint production 38
2.5.3 Exergy as a driving force of economic evolution? 39
2.6 Conclusions: the limits of the physical perspective and the need for a
more encompassing approach 40
3. PRODUCTION AS A SEQUENTIAL PROCESS 43
3.1 Introduction 43
3.2 Activity analysis: abstract models of inputs and outputs 43
Contents j|_
3.3 Sequential production models in management theories, engineering and
economics 45
3.3.1 Sequential production models in management theories 45
3.3.2 Classifications of production operations in engineering 47
3.3.3 Economics meets engineering: the engineering production function 53
3.3.4 Sequential production models in economics 55
3.4 Property vectors, operations and techniques: a sequential framework
for analyzing production processes 57
3.4.1 The workpiece as the object of production 57
3.4.2 Operations: input combinations change the properties of the workpiece 60
3.4.3 Production processes as sequences of operations 62
3.5 From operations to factors of production 63
3.5.1 Factor services as inputs into operations 63
3.5.2 The categories of factors of production 66
3.5.3 Knowledge underlies all factors of production 69
3.6 Conclusions 70
4. MORE THAN HEAT AND LIGHT: THE SERVICES PROVIDED BY
ENERGY USE IN PRODUCTION 72
4.1 Introduction 72
4.2 The identification of factor services provided by energy 72
4.3 Regularities in human wants and direct services of energy 75
4.4 Indirect energy requirements of changes in user relevant properties 81
4.5 Conclusions 86
5. CHANGING POWER RELATIONS: THE LONG TERM DEVELOPMENT
OF ENERGY USE IN PRODUCTION 89
5.1 Introduction 89
5.2 Qualitative changes in energy use: a taxonomy of historical energy
innovations 89
5.3 The macroscopic picture: quantitative growth and increasing variety
rather than stages of development 101
5.4 Conclusions 105
6. PROCESS INNOVATIONS IN SEQUENTIAL PRODUCTION 107
6.1 Introduction 107
6.2 Kinds of changes in production operations 107
6.2.1 Changes in individual operations 107
Contents ___ jjj_
6.2.2 Changes affecting several operations 111
6.3 Incompatibilities and complementarities of operations 113
6.3.1 Kinds of interdependencies between operations 113
6.3.2 Levels of interdependencies between operations 114
6.4 A suggestive parallel: modular product designs and architectural
innovation 118
6.5 The broader context: complex systems, decomposability and evolution 121
6.6 Modularity of techniques 125
6.7 Variable and endogenous decomposability 128
6.7.1 Knowledge as a source of decomposability 128
6.7.2 Increasing elasticity of interfaces 130
6.7.3 Reduced decomposability caused by integration of operations 131
6.8 Conclusions 131
7. A CLOSER LOOK AT CHANGE: THREE HISTORICAL EXAMPLES
OF ENERGY INNOVATIONS 133
7.1 Introduction 133
7.2 The transition from wood to coal 133
7.2.1 Wood scarcity and the use of coal 133
7.2.2 The use of coal as a source of thermal energy 136
7.2.3 The use of coke in pig iron production 137
7.2.4 The use of coal in wrought iron production 138
7.2.5 Characteristics of the introduction of coal 141
7.3 The introduction of the steam engine 143
7.3.1 Major changes in the design of steam engines 144
7.3.2 Gradual improvements of steam engine design 146
7.3.3 Indicators of technological change in steam engines 148
7.3.4 Obstacles to the use of steam 151
7.3.5 The competitiveness of steam and water power 152
7.3.6 Characteristics of the introduction of steam power 154
7.4 The electrification of manufacturing 156
7.4.1 The problem of power transmission 156
7.4.2 The introduction of electric power 158
7.4.3 From direct drive to unit drive 161
7.4.4 Characteristics of electrification 164
7.5 Conclusions 165
8. CONCLUSIONS 169
REFERENCES 177
Contents jv_
Figures
Figure 2.1: Inputs and outputs of two types of production 36
Figure 3.1: The typical sequence of industrial production processes 48
Figure 3.2: Classification of manufacturing processes 51
Figure 3.3: Levels of production technology 62
Figure 3.4: Goods, operations, factor services and factors of production 66
Figure 5.1: U.S. energy use, 1850 1997. 103
Figure 5.2: World production of coal, oil, natural gas, and primary electricity,
1800 1985. 103
Figure 7.1: Maximum efficiency of steam engines used for pumping, 1725 1903 149
Tables
Table 3.1: Classification and examples of unit operations for physical and
physico chemical materials processing 49
Table 3.2: Categories and examples of basic chemical reaction processes 50
Table 4.1: Economically important transformations between energy forms 74
Table 5.1: Major innovations in energy use 90
Table 6.1: Classification of product innovations 119
Table 6.2: Classification of process innovations in sequential production 126
Table 7.1: Efficiency of steam engines, 1725 1903 149
Table 7.2: Capital costs per horsepower for alternative transmission technologies
(1883) 159
Table 7.3: Price paid at the receiving station per horsepower hour transmitted
using various technologies (1883) 159
Symbols
B exergy
G Gibbs free energy
I Information
k Boltzman s constant
K number of interdependent elements
N total number of elements
p pressure
p probability
P conditional probability
n profit
Q heat
R universal gas constant
S entropy
T temperature
V volume
w number of microstates
W work
X state of knowledge
Y state of system
|
| adam_txt |
Contents i_
Contents
Contents i
Figures iv
Tables iv
Symbols iv
1. INTRODUCTION 1
1.1 Power blackouts in the Knowledge Economy 1
1.2 Three levels of analyzing production 3
1.3 Outline of the argument 7
2. THE PHYSICAL PERSPECTIVE ON THE ECONOMY AND ITS
LIMITATIONS 9
2.1 Introduction 9
2.2 A brief history of energy in economics 9
2.2.1 Energy in economic theory 9
2.2.2 Energetic approaches to economic and cultural development 11
2.2.3 Energetic laws of evolution and systems development 14
2.2.4 Biophysical economics 16
2.2.5 Problems of energetic approaches to the economy 16
2.3 Thermodynamic concepts and economic applications 17
2.3.1 The first and second laws of thermodynamics 17
2.3.2 Economic applications of thermodynamic concepts 21
2.3.3 Exergy as an encompassing thermodynamic variable 24
2.4 Thermodynamics of open systems 30
2.4.1 Open systems and the self organization of dissipative structures 30
2.4.2 On the relationship between self organization and evolutionary change 32
2.5 Implications of thermodynamic concepts for production and economic
evolution 35
2.5.1 The necessity of exergy as an input into production 35
2.5.2 The output side: on the ubiquity of joint production 38
2.5.3 Exergy as a driving force of economic evolution? 39
2.6 Conclusions: the limits of the physical perspective and the need for a
more encompassing approach 40
3. PRODUCTION AS A SEQUENTIAL PROCESS 43
3.1 Introduction 43
3.2 Activity analysis: abstract models of inputs and outputs 43
Contents j|_
3.3 Sequential production models in management theories, engineering and
economics 45
3.3.1 Sequential production models in management theories 45
3.3.2 Classifications of production operations in engineering 47
3.3.3 Economics meets engineering: the engineering production function 53
3.3.4 Sequential production models in economics 55
3.4 Property vectors, operations and techniques: a sequential framework
for analyzing production processes 57
3.4.1 The workpiece as the object of production 57
3.4.2 Operations: input combinations change the properties of the workpiece 60
3.4.3 Production processes as sequences of operations 62
3.5 From operations to factors of production 63
3.5.1 Factor services as inputs into operations 63
3.5.2 The categories of factors of production 66
3.5.3 Knowledge underlies all factors of production 69
3.6 Conclusions 70
4. MORE THAN HEAT AND LIGHT: THE SERVICES PROVIDED BY
ENERGY USE IN PRODUCTION 72
4.1 Introduction 72
4.2 The identification of factor services provided by energy 72
4.3 Regularities in human wants and direct services of energy 75
4.4 Indirect energy requirements of changes in user relevant properties 81
4.5 Conclusions 86
5. CHANGING POWER RELATIONS: THE LONG TERM DEVELOPMENT
OF ENERGY USE IN PRODUCTION 89
5.1 Introduction 89
5.2 Qualitative changes in energy use: a taxonomy of historical energy
innovations 89
5.3 The macroscopic picture: quantitative growth and increasing variety
rather than stages of development 101
5.4 Conclusions 105
6. PROCESS INNOVATIONS IN SEQUENTIAL PRODUCTION 107
6.1 Introduction 107
6.2 Kinds of changes in production operations 107
6.2.1 Changes in individual operations 107
Contents _ jjj_
6.2.2 Changes affecting several operations 111
6.3 Incompatibilities and complementarities of operations 113
6.3.1 Kinds of interdependencies between operations 113
6.3.2 Levels of interdependencies between operations 114
6.4 A suggestive parallel: modular product designs and architectural
innovation 118
6.5 The broader context: complex systems, decomposability and evolution 121
6.6 Modularity of techniques 125
6.7 Variable and endogenous decomposability 128
6.7.1 Knowledge as a source of decomposability 128
6.7.2 Increasing elasticity of interfaces 130
6.7.3 Reduced decomposability caused by integration of operations 131
6.8 Conclusions 131
7. A CLOSER LOOK AT CHANGE: THREE HISTORICAL EXAMPLES
OF ENERGY INNOVATIONS 133
7.1 Introduction 133
7.2 The transition from wood to coal 133
7.2.1 Wood scarcity and the use of coal 133
7.2.2 The use of coal as a source of thermal energy 136
7.2.3 The use of coke in pig iron production 137
7.2.4 The use of coal in wrought iron production 138
7.2.5 Characteristics of the introduction of coal 141
7.3 The introduction of the steam engine 143
7.3.1 Major changes in the design of steam engines 144
7.3.2 Gradual improvements of steam engine design 146
7.3.3 Indicators of technological change in steam engines 148
7.3.4 Obstacles to the use of steam 151
7.3.5 The competitiveness of steam and water power 152
7.3.6 Characteristics of the introduction of steam power 154
7.4 The electrification of manufacturing 156
7.4.1 The problem of power transmission 156
7.4.2 The introduction of electric power 158
7.4.3 From direct drive to unit drive 161
7.4.4 Characteristics of electrification 164
7.5 Conclusions 165
8. CONCLUSIONS 169
REFERENCES 177
Contents jv_
Figures
Figure 2.1: Inputs and outputs of two types of production 36
Figure 3.1: The typical sequence of industrial production processes 48
Figure 3.2: Classification of manufacturing processes 51
Figure 3.3: Levels of production technology 62
Figure 3.4: Goods, operations, factor services and factors of production 66
Figure 5.1: U.S. energy use, 1850 1997. 103
Figure 5.2: World production of coal, oil, natural gas, and primary electricity,
1800 1985. 103
Figure 7.1: Maximum efficiency of steam engines used for pumping, 1725 1903 149
Tables
Table 3.1: Classification and examples of unit operations for physical and
physico chemical materials processing 49
Table 3.2: Categories and examples of basic chemical reaction processes 50
Table 4.1: Economically important transformations between energy forms 74
Table 5.1: Major innovations in energy use 90
Table 6.1: Classification of product innovations 119
Table 6.2: Classification of process innovations in sequential production 126
Table 7.1: Efficiency of steam engines, 1725 1903 149
Table 7.2: Capital costs per horsepower for alternative transmission technologies
(1883) 159
Table 7.3: Price paid at the receiving station per horsepower hour transmitted
using various technologies (1883) 159
Symbols
B exergy
G Gibbs free energy
I Information
k Boltzman's constant
K number of interdependent elements
N total number of elements
p pressure
p probability
P conditional probability
n profit
Q heat
R universal gas constant
S entropy
T temperature
V volume
w number of microstates
W work
X state of knowledge
Y state of system |
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| author | Bünstorf, Guido 1968- |
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| indexdate | 2024-07-09T20:48:24Z |
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| spelling | Bünstorf, Guido 1968- Verfasser (DE-588)124019633 aut Energy use in production a long-term analysis 2002 IV, 190 Bl. graph. Darst. txt rdacontent n rdamedia nc rdacarrier Jena, Univ., Diss., 2002 Energiewirtschaft (DE-588)4014743-5 gnd rswk-swf Langfristige Analyse (DE-588)4200335-0 gnd rswk-swf Strukturwandel (DE-588)4058136-6 gnd rswk-swf Energieforschung (DE-588)4152220-5 gnd rswk-swf Produktionsprozess (DE-588)4123984-2 gnd rswk-swf Produktion (DE-588)4047347-8 gnd rswk-swf Energieverbrauch (DE-588)4014733-2 gnd rswk-swf Technischer Fortschritt (DE-588)4059252-2 gnd rswk-swf (DE-588)4113937-9 Hochschulschrift gnd-content Energiewirtschaft (DE-588)4014743-5 s DE-604 Produktionsprozess (DE-588)4123984-2 s Energieforschung (DE-588)4152220-5 s Produktion (DE-588)4047347-8 s Strukturwandel (DE-588)4058136-6 s Technischer Fortschritt (DE-588)4059252-2 s Energieverbrauch (DE-588)4014733-2 s Langfristige Analyse (DE-588)4200335-0 s DE-188 HBZ Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=015181028&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis |
| spellingShingle | Bünstorf, Guido 1968- Energy use in production a long-term analysis Energiewirtschaft (DE-588)4014743-5 gnd Langfristige Analyse (DE-588)4200335-0 gnd Strukturwandel (DE-588)4058136-6 gnd Energieforschung (DE-588)4152220-5 gnd Produktionsprozess (DE-588)4123984-2 gnd Produktion (DE-588)4047347-8 gnd Energieverbrauch (DE-588)4014733-2 gnd Technischer Fortschritt (DE-588)4059252-2 gnd |
| subject_GND | (DE-588)4014743-5 (DE-588)4200335-0 (DE-588)4058136-6 (DE-588)4152220-5 (DE-588)4123984-2 (DE-588)4047347-8 (DE-588)4014733-2 (DE-588)4059252-2 (DE-588)4113937-9 |
| title | Energy use in production a long-term analysis |
| title_auth | Energy use in production a long-term analysis |
| title_exact_search | Energy use in production a long-term analysis |
| title_exact_search_txtP | Energy use in production a long-term analysis |
| title_full | Energy use in production a long-term analysis |
| title_fullStr | Energy use in production a long-term analysis |
| title_full_unstemmed | Energy use in production a long-term analysis |
| title_short | Energy use in production |
| title_sort | energy use in production a long term analysis |
| title_sub | a long-term analysis |
| topic | Energiewirtschaft (DE-588)4014743-5 gnd Langfristige Analyse (DE-588)4200335-0 gnd Strukturwandel (DE-588)4058136-6 gnd Energieforschung (DE-588)4152220-5 gnd Produktionsprozess (DE-588)4123984-2 gnd Produktion (DE-588)4047347-8 gnd Energieverbrauch (DE-588)4014733-2 gnd Technischer Fortschritt (DE-588)4059252-2 gnd |
| topic_facet | Energiewirtschaft Langfristige Analyse Strukturwandel Energieforschung Produktionsprozess Produktion Energieverbrauch Technischer Fortschritt Hochschulschrift |
| url | http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=015181028&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |
| work_keys_str_mv | AT bunstorfguido energyuseinproductionalongtermanalysis |