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9780824742492

Battery Technology Handbook

by ;
  • ISBN13:

    9780824742492

  • ISBN10:

    0824742494

  • Edition: 2nd
  • Format: Hardcover
  • Copyright: 2003-08-29
  • Publisher: CRC Press

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Summary

This practical reference remains the most comprehensive guide to the fundamental theories, techniques, and strategies used for battery operation and design. It includes new and revised chapters focusing on the safety, performance, quality, and enhancement of various batteries and battery systems. From automotive, electrochemical, and high-energy applications to system implementation, selection, and standardization, the Second Edition presents expert discussions on electrochemical energy storage, the advantages of battery-powered traction, the disposal and recycling of used batteries, hazard prevention, and the chemistry and physics of lithium primary batteries.

Table of Contents

Preface to the Second Edition iii
Preface to the First Edition v
Contributors xix
I. Fundamentals and Theory, Running Techniques, Applications, and Outlook: Traction Batteries, Stationary Batteries, and Charging Methods
1 Electrochemical Energy Storage
1(100)
D. Berndt
1.1 Introduction
1(1)
1.2 The Electrochemical Cell and the Cell Reaction
2(2)
1.3 Fundamental Laws
4(17)
1.3.1 Parameters that Influence the Cell Reaction
4(1)
1.3.2 Equilibrium or Thermodynamic Parameters
5(5)
1.3.3 Current Flow, Kinetic Parameters, and Polarization
10(11)
1.4 Heat Effects
21(16)
1.4.1 The Reversible Heat Effect
21(1)
1.4.2 Current Related Heat Effects (Joule Heating)
22(1)
1.4.3 Heat Generation in Total
23(1)
1.4.4 Examples for Heat Generation in Batteries
23(9)
1.4.5 Heating of the Battery and Heat Capacity
32(1)
1.4.6 Heat Dissipation
32(5)
1.5 General Terms and Characteristics
37(3)
1.5.1 Cathodic/Anodic
37(1)
1.5.2 Cell/Battery
38(1)
1.5.3 Active Material and Change of Volume
38(1)
1.5.4 Nonactive Components
39(1)
1.6 Battery Parameters
40(8)
1.6.1 Voltage
41(1)
1.6.2 Capacity
42(2)
1.6.3 Energy Content
44(1)
1.6.4 Specific Energy and Energy Density
44(1)
1.6.5 Internal Resistance
44(2)
1.6.6 Self-Discharge
46(2)
1.7 General Aspects of Electrochemical Energy Storage
48(2)
1.7.1 Electrolytes
49(1)
1.8 Fundamental Aspects of Existing Battery Systems
50(47)
1.8.1 Lead-Acid Batteries
50(25)
1.8.2 Nickel/Cadmium Batteries
75(6)
1.8.3 Nickel/Hydrogen Batteries
81(4)
1.8.4 Nickel/Metal Hydride Batteries
85(6)
1.8.5 Batteries of Particular Design
91(6)
1.9 Final Remarks
97(4)
References
98(3)
2 Batteries for Electrically Powered Industrial Trucks
101(18)
H. A. Kiehne
2.1 Introduction
101(1)
2.2 Demands of the Market
101(2)
2.3 Standardized Designs
103(6)
2.4 Energy/Weight and Energy/Volume Ratios
109(4)
2.5 Service Life and Economy
113(1)
2.6 Charging Techniques
114(1)
2.7 Maintenance
115(1)
2.8 Summary and Outlook
115(4)
References
118(1)
3 Power Supply Concepts for Driverless Industrial Trucks
119(18)
P. Preuss
3.1 The Importance of Driverless Industrial Trucks
119(1)
3.2 Load Placed on Traction Batteries by Driverless Industrial Trucks
120(2)
3.3 Traction Batteries for Driverless Industrial Trucks
122(1)
3.4 Optimization of Temperature
122(3)
3.4.1 Considerations on Battery Dimensioning
123(1)
3.4.2 Estimating Battery Load Rating
123(2)
3.5 The Choice of Battery
125(2)
3.5.1 Maximum Permissible Capacity
125(1)
3.5.2 Maximum Permissible Temperature in Battery Systems
126(1)
3.5.3 Charging Requirements
126(1)
3.6 Development of a Concept of Power Supply
127(5)
3.6.1 Nature and Scope of Application Data
127(2)
3.6.2 Processing and Transformation of Application Data
129(3)
3.6.3 Comparison of System
132(1)
3.7 Current State of Charging Technology
132(2)
3.7.1 Methods of Control/Exchange of Information
133(1)
3.7.2 Practical Example
133(1)
3.8 Summary and Outlook
134(3)
4 Batteries for Electric Road Vehicles
137(18)
H. A. Kiehne
4.1 Introduction
137(2)
4.2 Energy and Raw Materials
139(1)
4.3 Solution to the Range Problem
140(2)
4.4 Battery Requirements: Contributions to Solving the Problem
142(3)
4.5 Alternatives to Lead-Acid Systems
145(3)
4.6 Battery Systems of the Near Future
148(3)
4.7 High-Temperature Batteries and Fuel Cells
151(1)
4.8 Economic Viability
151(3)
4.9 Outlook
154(1)
References
154(1)
5 Battery-Powered Traction: The User's Point of View
155(32)
W . König
5.1 Introduction
155(1)
5.2 General Remarks
156(1)
5.3 Advantages of Battery-Powered Traction
156(3)
5.3.1 Impacts of Operation and Environmental Concerns
156(1)
5.3.2 Physical Advantages of Battery-Powered Traction
157(1)
5.3.3 Survey on Service Cost Calculation
157(2)
5.4 Demands on Batteries
159(5)
5.4.1 Increase of Electrical Performance
161(1)
5.4.2 Service Life
161(1)
5.4.3 Maintenance
161(1)
5.4.4 Purchasing Costs
162(1)
5.4.5 Safety of Operation
163(1)
5.4.6 Destinations of Types
163(1)
5.5 Construction and Selection Criteria of Traction Batteries
164(4)
5.5.1 Standard Design of Cells Conforming to an Older Standard DIN 43 567
164(1)
5.5.2 Low-Maintenance Cells (Closed, but Not Sealed)
164(1)
5.5.3 Low-Maintenance in Improved Cell Design with Higher Capacities
165(1)
5.5.4 Special Design for Heavy Duty
166(1)
5.5.5 Maintenance-Free Design Valve Regulated Cells
166(2)
5.6 Charging of Traction Batteries
168(5)
5.6.1 Regulations and Manuals
168(1)
5.6.2 Chargers with Taper Characteristics
168(1)
5.6.3 Chargers with Regulated Characteristics
169(4)
5.7 Organization of Charge Operation
173(3)
5.7.1 The Battery Room (Charging Room)
173(1)
5.7.2 Battery Charging Station
174(1)
5.7.3 Single Charge Point
174(1)
5.7.4 Mobile Charge Stations
175(1)
5.7.5 Protection Methods and Specifications
175(1)
5.8 Peripheral Equipment
176(4)
5.8.1 Venting Plugs
176(1)
5.8.2 Electrolyte Level Indicator
176(1)
5.8.3 Regulating Vents
176
5.8.4 Cell Connectors
116(60)
5.8.5 Water Refill Equipment
176(1)
5.8.6 Recombination Plugs
177(1)
5.8.7 Connections
178(1)
5.8.8 Capacity Indicators
178(1)
5.8.9 Electronic Controllers
179(1)
5.9 Quality Assurance of Batteries and Chargers
180(1)
5.9.1 Capacity Tests
181(1)
5.10 Maintenance and Upkeep
181(3)
5.10.1 Traction Batteries
182(1)
5.10.2 Chargers
183(1)
5.11 Leasing of Batteries
184(1)
5.12 Disposal of Batteries
184(1)
5.13 Future Outlook
185(1)
5.14 Conclusions
185(1)
References
185(2)
6 Safety Standards for Stationary Batteries and Battery Installations
187(14)
H. Willmes
6.1 Introduction
187(1)
6.2 Safety Standard DIN VDE 0510: "Accumulators and Battery Installations"
187(2)
6.3 DIN VDE 0510 Part 1 (draft): "General"
189(1)
6.4 DIN VDE 0510 Part 2: "Stationary Batteries and Battery Installations"
190(7)
6.4.1 Hazards Caused by Electricity
190(2)
6.4.2 Hazards Caused by the Electrolyte
192(1)
6.4.3 Explosive Charging Gases/Ventilation of Battery Rooms
193(4)
6.5 DIN VDE 0510 Part 3: "Traction Batteries for Electric Vehicles"
197(1)
6.6 DIN VDE 0510 Part 5 (draft): "Batteries on Board Crafts or Vehicles"
197(2)
6.7 DIN VDE 0510 Part 6: "Portable Batteries"
199(1)
6.8 DIN VDE 0510 Part 4 (draft): "SLI-Starter Batteries"
199(1)
6.9 International Standardization
200(1)
References
200(1)
7 Batteries for Stationary Power Supply
201(28)
H. Franke
7.1 Introduction
201(1)
7.2 Stationary Batteries
202(2)
7.3 Cell and Plate Design
204(3)
7.4 Characteristics
207(13)
7.5 Selection of Stationary Batteries
220(3)
7.6 Maintenance
223(2)
7.7 Pole Sealing
225(1)
7.8 Delivery Design
226(1)
7.9 Future Aspects
226(1)
References
226(3)
8 The Operation of Batteries
229(14)
U.-C. Stahl
8.1 Introduction
229(1)
8.2 The Development of Power Supply for Telecommunications
230(3)
8.3 Product Development and Products in Use
233(1)
8.4 Concept of Energy Reserve
234(1)
8.5 Operation Conditions
235(2)
8.6 Battery Installation
237(1)
8.7 Purchasing and Quality Management
238(2)
8.8 Maintenance Activities in Battery Plants
240(1)
8.9 Operation Experience
240(3)
8.9.1 Vented Batteries
241(1)
8.9.2 Valve-Regulated Batteries
241(1)
8.9.3 Accidents
242(1)
References
242(1)
9 Motor Vehicle Starter Batteries 243
G. Sassmannhausen and E. Nann
9.1 The European Market
243(1)
9.2 Tasks of a Motor Vehicle Starter Battery
244(1)
9.3 Construction of a Vehicle Starter Battery
244(3)
9.4 Active Masses of the Electrodes
247(1)
9.5 The Manufacturing Process
247(1)
9.6 Dimensions and Detailed Specifications
248(1)
9.7 Mounting Position in the Motor Vehicle
248(1)
9.8 Electrical Properties
249(1)
9.9 Standardization of Battery Characteristics
249(1)
9.10 New Development Requirements
249(1)
9.11 Valve-Regulated Lead-Acid Batteries
250(2)
9.12 Trends and Requirements for New Board-Net Batteries
252(1)
9.13 Battery Sensor for Dynamic Energy Management
253(1)
References
254(1)
10 High Energy Batteries
255(20)
C.-H. Dustmann
10.1 Introduction
255(2)
10.2 ZEBRA Battery (Na/NiCl2)
257(9)
10.2.1 Technology
257(4)
10.2.2 ZEBRA Cell Design and Production
261(1)
10.2.3 ZEBRA Battery Design and Production
262(1)
10.2.4 Battery System Design
263(1)
102.5 ZEBRA Battery Performance and Life Data
264(1)
10.2.6 Battery Safety
264(1)
10.2.7 Recycling
265(1)
10.2.8 Applications
266(1)
10.3 NaS Battery
266(2)
10.3.1 Technology
266(2)
10.4 Lithium-Ion Battery
268(1)
10.4.1 Technology
268(1)
10.5 Lithium-Polymer Battery
268(2)
10.6 Other Battery Systems
270(1)
10.7 Battery Overview
271(1)
10.7.1 Minimum Requirements for EV Batteries
271(1)
10.7.2 ZEV Life Cycle Costs Start to Be Competitive
272(1)
10.8 Fuel Cells
272(1)
References
273(2)
11 Solar Electric Power Supply with Batteries
275(16)
H. K. Köthe
11.1 Introduction
275(1)
11.2 Dimensioning a Solar Electric System
276(4)
11.2.1 Preconditions
276(1)
11.2.2 Calculation of the Mean Consumption
276(1)
11.2.3 Calculation of the Mean Supply
276(1)
11.2.4 Calculation of the Capacity
277(1)
11.2.5 Evaluation of the System
277(3)
11.3 Design of Solar Electric Systems
280(2)
11.3.1 The Power Source: The Solar Generator
280(1)
11.3.2 System Design
281(1)
11.3.3 The Isolating Diode
281(1)
11.3.4 The Battery
282(1)
11.3.5 The Operating System
282(1)
11.4 Aspects for the Choice of the Battery
282(2)
11.4.1 Power Rating
282(1)
11.4.2 Feasible Battery Types
283(1)
11.4.3 Application Technology
284(1)
11.5 Designs of Operating Systems
284(1)
11.5.1 Systems with Current Limitation
284(1)
11.5.2 Systems with Voltage Limitation
284(1)
11.5.3 Systems with Two-Step Regulators
284(1)
11.6 Influence of Geographic Position
285(1)
11.7 Summary
285(4)
References
289(2)
12 Charging Methods and Techniques: General Requirements and Selection of Chargers
291(26)
E. Wehrle
12.1 The Battery's Requirements for the Charger
291(1)
12.2 Technical Data and Terms
291(5)
12.2.1 Battery Capacity, Discharge Current, and Charge Current
294(1)
12.2.2 Charge Coefficient
294(1)
12.2.3 Charging Time
294(2)
12.2.4 Gassing Voltage
296(1)
12.3 Characteristic Curves
296(3)
12.3.1 Decreasing (Taper) Characteristics (W Type)
298(1)
12.3.2 Increasing Characteristics (S Type)
298(1)
12.3.3 Limited Characteristics
298(1)
12.3.4 Constant Characteristics
299(1)
12.3.5 Assembled Characteristics
299(1)
12.4 Employment of Charging Methods
299(11)
12.4.1 Installation and Operation of Batteries and Chargers
299(1)
12.4.2 Demands of Vented Lead-Acid Accumulators
299(1)
12.4.3 Demands of the Maintenance-Free Lead-Acid Battery
299(1)
12.4.4 Demands of Vented Nickel/Cadmium Batteries
299(1)
12.4.5 Charging Lead-Acid-Batteries According to the W Characteristic
300(3)
12.4.6 Charging Lead-Acid Batteries Corresponding to the I Characteristic
303(1)
12.4.7 Charging of Lead-Acid Accumulators According to the IUIa Characteristic
304(1)
12.4.8 Charging According to the IU Characteristic
305(1)
12.4.9 Charging of Nickel/Cadmium Batteries
306(1)
12.4.10 Charging of Nickel/Cadmium Batteries to the I Characteristics
307(1)
12.4.11 Charging Nickel/Cadmium Batteries According to the W Characteristic
307(1)
12.4.12 Charging of NiCd/Batteries According to the IU Characteristic
308(1)
12.4.13 Charging Valve-Regulated Lead-Acid Batteries
309(1)
12.4.14 Charging Gas-Tight Nickel/Cadmium Batteries
310(1)
12.5 Comparing Charging Methods for Lead Batteries
310(1)
12.6 Installation Costs of Charging Devices
311(1)
12.7 Guidelines for the Selection of Chargers
311(1)
12.8 Special Demands and Recommendations for the Choice of Charger
311(6)
12.8.1 Demands of Valve-Regulated Lead-Acid Batteries
311(1)
12.8.2 Demands of Modified Traction Batteries
312(3)
References
315(2)
13 Technical Aspects of Chargers and Current Transformers and Methods for Supervision
317(18)
G. Will
13.1 Application of Battery Chargers
317(1)
13.2 Characteristic Voltages of Lead-Acid and NiCd Batteries
318(1)
13.3 Construction and Function of Battery Chargers
318(7)
13.3.1 Controlled Battery Chargers
318(6)
13.3.2 Uncontrolled Chargers
324(1)
13.4 Chargers for Traction Batteries and Stationary Batteries in Switch Operation
325(1)
13.5 Chargers for Stationary Batteries in Parallel Operation
326(1)
13.6 Surveillance and Additional Devices
327(2)
13.6.1 Mains Surveillance
328(1)
13.6.2 DC Voltage Surveillance
328(1)
13.6.3 Surveillance of the DC Voltage Waviness
329(1)
13.6.4 Fuse Surveillance
329(1)
13.6.5 Automated Charging
329(1)
13.6.6 State-of-Charge Surveillance
329(1)
13.7 Harmonic Oscillations and Reactive Power
329(3)
13.7.1 Three-Phase Bridge Circuit
330(1)
13.7.2 Primary-Chopped Switching Power Supply
331(1)
13.8 Inverters for Ascertained Power Supply of Three-Phase Consumers
332(3)
13.8.1 Inverters with Double-Phase Bridge Circuits
332(2)
13.8.2 Inverters with Three-Phase Bridge Circuits
334(1)
14 Standards and Regulations for Batteries and Battery Plants
335(12)
H. A. Kiehne
14.1 Significance of Standards
335(1)
14.2 National German Standards and Regulations
335(2)
14.2.1 How Standards Come into Being
336(1)
14.3 International Standards
337(2)
14.3.1 International Electrotechnical Commission
337(1)
14.3.2 EN Standards (CENELEC)
338(1)
14.4 Product Standards, Testing Standards, and Safety Standards
339(1)
14.5 Standards for Dry Batteries (Selection)
339(1)
14.6 Standards for Starter Batteries (Selection)
340(1)
14.6.1 Existing German National Standards (Selection)
340(1)
14.6.2 IEC and EN Standards (Selection)
341(1)
14.7 Standards for Traction Batteries (Selection)
341(1)
14.7.1 Existing German National Standards (Selection)
341(1)
14.7.2 IEC and EN Standards (Selection)
342(1)
14.8 Standards for Stationary Lead-Acid Batteries (Selection)
342(1)
14.8.1 Existing German National Standards (Selection)
342(1)
14.8.2 IEC and EN Standards (Selection)
342(1)
14.9 Standards for Portable Maintenance-Free, Valve-Regulated Lead-Acid (VRLA) Cells
343(1)
14.9.1 Existing German National Standards (Selection)
343(1)
14.9.2 IEC and EN Standards (Selection)
343(1)
14.10 Standards for Alkaline Accumulators (Selection)
343(1)
14.10.1 Existing German National Standards (Selection)
343(1)
14.l0.2 IEC and EN Standards (Selection)
343(1)
14.11 VDE Regulations (Selection)
343(1)
14.12 Other German Standards and Guidelines
344(1)
14.13 Other International Standards and Committees
344(1)
14.14 Significance of Standards and Regulations Regarding Manufacturer Liability
344(3)
References
345(2)
II. Portable Batteries
15 Batteries, an Overview and Outlook
347(14)
H. A. Kiehne, D. Spahrbier, D. Sprengel, and W. Raudzsus
15.1 Terms, Definitions, and Characterizing Marks
347(4)
15.2 Construction, Sizes, and Marking
351(6)
15.2.1 Construction
351(1)
15.2.2 The IEC Designation System for Primary Batteries Defined in IEC Standard 60 086 1
352(5)
15.3 The Alkaline Manganese Cell
357(1)
15.4 Regeneration/Recharging
358(1)
15.5 A New Generation of Batteries: Lithium Primary Batteries
358(2)
15.6 Outlook
360(1)
References
360(1)
16 Feasibility Study for Appliances 361
H. A. Kiehne and W. Raudzsus
16.1 Battery-Operated Appliances
361(1)
16.2 Calculations to Estimate Capacity
362(3)
16.3 Capacity of a Battery
365(1)
16.4 The Most Important Load Profiles of Electric Appliances
366(2)
16.4.1 Continuous Current Load
366(1)
16.4.2 Intermittent Current Load
366(1)
16.4.3 Severely Intermittent Load
366(2)
16.4.4 Short Peak Currents
368(1)
16.5 Influence of Self-Discharge and Temperature
368(1)
16.5.1 Self Discharge
368(1)
16.5.2 Influence of Temperature
368(1)
16.6 Design Requirement Study
369(1)
16.7 Description of Available Portable Batteries
370(3)
16.7.1 Primary Cells
370(3)
16.7.2 Secondary Cells, Accumulators
373(1)
16.8 National and International Standardization
373(1)
16.9 The Interchange-Program NiCd Cells and Primary Cells
374(2)
16.10 Guidelines for Use and Maintenance
376(2)
16.10.1 Primary Batteries
377(1)
16.10.2 VRLA Batteries
377(1)
16.10.3 NiCd Batteries
378(1)
16.10.4 Nickel/Metal Hydride Batteries
378(1)
16.10.5 Lithium Batteries
378(1)
16.11 Summary
378(3)
References
319(62)
17 Maintenance-Free Lead Batteries with Immobilized Electrolyte 381
H. Tuphorn
17.1 Introduction
381(1)
17.2 Fundamentals
382(4)
17.2.1 Oxygen Recombination
384(2)
17.3 Construction
386(1)
17.4 Systems and Properties
386(6)
17.4.1 Gel System
386(2)
17.4.2 AGM System
388(1)
7.4.3 System Comparison
388(4)
17.5 Electrical Properties
392(6)
17.5.1 Methods of Charging
392(2)
17.5.2 Discharge Conditions
394(1)
17.5.3 Life and Self Discharge
395(2)
17.5.4 Deep Discharge Ability
397(1)
17.6 Battery Types and Applications
398(1)
17.7 Standards
399(2)
References
400(1)
18 Lithium Batteries: The Latest Variant of Portable Electrical Energy
401(66)
W. Jacobi
18.1 Introduction
401(1)
18.2 The Name "Lithium Battery"
402(2)
18.3 The Lithium Battery's Special Advantages
404(2)
18.3.1 High Cell Voltage
405(1)
18.3.2 Energy Content by Weight: Specific Energy
405(1)
18.3.3 Energy Content by Volume: Energy Density
405(1)
18.3.4 Loadability
406(1)
18.3.5 Discharge Characteristic
406(1)
18.3.6 Deep Temperature Capability
406(1)
18.3.7 Shelf Life
406(1)
18.3.8 Environmental Compatibility
406(1)
18.4 Chemistry and Physics of Lithium Primary Batteries
406(7)
18.4.1 Properties of Anodic Metal Lithium
406(2)
18.4.2 Electrolytes for Lithium Batteries
408(5)
18.4.3 Cathodic Materials
413(1)
18.5 Designs and Technology of Primary Lithium Batteries
413(2)
18.6 Examples of Lithium Primary Battery Systems
415(24)
18.6.1 The System Lithium/Manganese Dioxide
415(2)
18.6.2 The System Lithium/Carbon Monofluoride
417(3)
18.6.3 The System Lithium/Thionylchloride
420(5)
18.6.4 The System Lithium/Sulfur Dioxide
425(5)
18.6.5 The System Lithium/Iodine
430(2)
18.6.6 The System Lithium-Aluminum/Iron Disulfide
432(7)
18.7 Secondary Lithium Batteries
439(25)
18.7.1 The Special Aspects of a Secondary Lithium Battery Technology
440(2)
18.7.2 Rechargeable Lithium Batteries for Low Energy Applications (Button Cells)
442(3)
18.7.3 Lithium-Ion Batteries
445(12)
18.7.4 The System Lithium (Carbon)/Lithium (Cobalt Oxide)
457(6)
18.7.5 Other Rechargeable Lithium Batteries
463(1)
18.7.6 Potential Safety Impacts
463(1)
18.7.7 Safety Measures
464(1)
18.8 Disposal of Lithium Batteries
464(3)
References
465(2)
19 The Disposal of Portable Batteries
467(22)
J. L. Fricke and N. Knudsen
19.1 Portable Battery Systems and Their Relevance to the Environment
467(8)
19.1.1 Main Systems and Their Implementation
467(2)
19.1.2 Significance of Heavy Metals for Disposal
469(4)
19.1.3 Basic Prerequisites for Recycling
473(2)
19.2 Recycling Procedures and Level of Recycling
475(10)
19.2.1 Lead Batteries
475(1)
19.2.2 Nickel/Cadmium Batteries
476(1)
19.2.3 Batteries Containing Mercury (R9 Cells)
476(1)
19.2.4 Nickel/Metal Hydride Batteries
476(2)
19.2.5 Lithium Batteries
478(1)
19.2.6 Zinc-Carbon and Alkali-Manganese Batteries
479(6)
19.3 The German Battery Decree
485(1)
19.4 The Manufacturers' Common Collection System
486(3)
20 History
489
H. A. Kiehne
20.1 Early Beginnings
489(1)
20.2 Primary and Secondary Cells
489(4)
20.3 Fuel Cells and High Temperature Cells
493(2)
References
493(2)
Index 495
0268025541
About the William and Katherine Devers Series in Dante Studies ix
List of Illustrations xi
Acknowledgments xiii
INTRODUCTION 1(8)
1. LADY GRAMMAR BETWEEN NURTURING AND DISCIPLINE 9(40)
Defining grammatica
9(5)
nutrix as magistra
14(1)
inter blandimenta nutricum
15(5)
Lady Grammar's Whip
20(2)
Sapientia nutria and Grammatica nutria
22(3)
Grammatica in the Metalogicon
25(15)
Lady Grammar in the Twelfth and Thirteenth Centuries
40(6)
Lady Grammar in Fourteenth-Century Italy
46(3)
2. THE PRIMAL SCENE OF SUCKLING IN DE VULGARI ELOQUENTIA 49(28)
a la tetta de la madre s'apprende
49(4)
nutricem imitantes
53(5)
vir sine matre, vir sine lacte
58(1)
quanquam Sarnum biberimus ante dentes
59(11)
ut "femina," "corpo"
70(2)
os ex ossibus meis et caro de carne mea
72(5)
3. THE BODY OF GAETA: BURYING AND UNBURYING THE WET NURSE IN INFERNO 77(32)
From Lady Grammar to the Neoplatonic Nurse and Beyond
77(1)
là presso a Gaeta, prima the sì Enëa la nomasse
78(2)
Ex ore infantium et lactentium
80(2)
Aeneia nutrix
82(3)
Circe, the Anti-nurse
85(3)
Bones and a Name
88(5)
in misericordia uberi
93(4)
Ulysses as Circe
97(2)
Noms de lieu
99(5)
Poppa and prora at the End of Paradiso
104(2)
The Nurse in Inferno
106(3)
4. DECONSTRUCTING SUBJECTIVITY IN ANTEPURGATORY 109(26)
Selfhood and the Body in Purgatorio
109(4)
Silva from Plato to Dante
113(3)
Silva and Alma Mater
116(2)
Silva in Purgatorio 5
118(17)
5. RECONSTRUCTING SUBJECTIVITY IN PURGATORIO AND PARADISO 135(32)
Serino humilis and the Nursing Body of Christ
135(3)
Dante's Nurse-Poets
138(7)
The Pilgrim as infans /puer
145(9)
The Triumph of the Resurrected Breast
154(3)
Et coram paire le si fece unito
157(10)
Notes 167(102)
Bibliography 269(28)
Index 297

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