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Food Preservation Process Design [Kietas viršelis]

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(Professor of Food Engineering at The Ohio State University. He is also and Adjunct Professor at the University of California-Davis and Professor Emeritus at the University of Missouri.)
  • Formatas: Hardback, 368 pages, aukštis x plotis: 229x152 mm, weight: 710 g
  • Serija: Food Science and Technology
  • Išleidimo metai: 05-Apr-2011
  • Leidėjas: Academic Press Inc
  • ISBN-10: 0123724864
  • ISBN-13: 9780123724861
Kitos knygos pagal šią temą:
Food Preservation Process DesignDidesnis paveikslėlis
  • Formatas: Hardback, 368 pages, aukštis x plotis: 229x152 mm, weight: 710 g
  • Serija: Food Science and Technology
  • Išleidimo metai: 05-Apr-2011
  • Leidėjas: Academic Press Inc
  • ISBN-10: 0123724864
  • ISBN-13: 9780123724861
Kitos knygos pagal šią temą:
Pastovi nuoroda: https://www.kriso.lt/db/9780123724861.html
Raktažodžiai:
The preservation processes for foods have evolved over several centuries, but recent attention to non-thermal technologies suggests that a new dimension of change has been initiated.

The new dimension to be emphasized is the emerging technologies for preservation of foods and the need for sound base of information to be developed as inputs for systematic process design. The focus of the work is on process design, and emphasizes the need for quantitative information as inputs to process design.

The concepts presented build on the successful history of thermal processing of foods, and use many examples from these types of preservation processes. Preservation of foods by refrigeration, freezing, concentration and dehydration are not addressed directly, but many of the concepts to be presented would apply. Significant attention is given to the fate of food quality attributes during the preservation process, and the concept of optimizing the process parameters to maximize the retention of food quality

Focuses on three elements of preservation process:
* Kinetic Models for Food Components
* Transport Models in Food Systems
* Process Design Models

The preservation processes for foods have evolved over several centuries, but recent attention to non-thermal technologies suggests that a new dimension of change has been initiated.

The new dimension to be emphasized is the emerging technologies for preservation of foods and the need for sound base of information to be developed as inputs for systematic process design. The focus of the work is on process design, and emphasizes the need for quantitative information as inputs to process design.

The concepts presented build on the successful history of thermal processing of foods and use many examples from these types of preservation processes. Preservation of foods by refrigeration, freezing, concentration and dehydration are not addressed directly, but many of the concepts to be presented would apply. Significant attention is given to the fate of food quality attributes during the preservation process and the concept of optimizing process parameters to maximize the retention of food quality.

Focuses on three elements of preservation process:
* Kinetic Models for Food Components
* Transport Models in Food Systems
* Process Design Models

Daugiau informacijos

Documenting the positive science of the past and preparing food scientists for the future
Preface vii
1 Introduction 1(18)
History of preservation processes
6(3)
The quantitative approach
9(8)
Bibliography
17(2)
2 Kinetic Models for Food Systems 19(30)
Rate equations and rate constants
20(5)
First-order model
25(2)
Multiple-order models
27(3)
Agent intensity models
30(7)
Thermal process models
37(6)
Uniform parameters
43(3)
List of symbols
46(1)
Bibliography
47(2)
3 Kinetics of Inactivation of Microbial Populations 49(38)
Characteristics of microbial survivor curves
50(4)
Kinetic parameters for microbial populations
54(5)
Applications of kinetic parameters
59(17)
Definition of microbial inactivation
76(1)
Kinetic parameters for alternative preservation technologies
77(1)
List of symbols
77(1)
Bibliography
78(9)
4 Kinetics of Food Quality Attribute Retention 87(24)
Characteristics of quality retention kinetics
88(3)
Kinetic parameters for product quality retention
91(4)
Applications of kinetic parameters for quality attributes
95(10)
Impacts of preservation processes on quality attributes
105(1)
List of symbols
106(1)
Bibliography
107(4)
5 Physical Transport Models 111(36)
Physical properties
112(13)
Heating and cooling in containers
125(13)
Ohmic heating
138(1)
Microwave heating
139(2)
Ultra-high pressure applications
141(2)
List of symbols
143(1)
Bibliography
144(3)
6 Process Design Models 147(70)
The process design parameter
148(2)
General approaches to preservation process design.
150(16)
Process design targets
166(5)
Integrated impacts of preservation processes
171(11)
Design of a microwave process
182(11)
Design of an ohmic heating process
193(4)
Design of ultra-high pressure processes
197(5)
Design of pulsed-electric-field processes
202(7)
Design of combined processes
209(3)
List of symbols
212(2)
Bibliography
214(3)
7 Process Validation and Evaluation 217(28)
Process validation for microbial inactivation
219(10)
Alternative approaches to validation
229(8)
Process validation for alternative process technologies
237(6)
List of symbols
243(1)
Bibliography
243(2)
8 Optimization of Preservation Processes 245(22)
The HTST concept
246(3)
Applications to nonliquid foods
249(14)
List of symbols
263(2)
Bibliography
265(2)
9 Designing Processes in the Future 267(12)
Assembly of kinetic parameters
268(3)
Transport models
271(1)
Process models
272(1)
Opportunities for evolving process technologies
273(3)
Bibliography
276(3)
Appendix 279(62)
Index 341
Dennis R. Heldman is the Dale A. Seiberling Endowed Professor of Food Engineering at Ohio State University. He is also an Adjunct Professor at the University of California-Davis and Professor Emeritus at the University of Missouri. He has been author or co-author of over 150 research projects and several books. He served as President of the Institute of Food Technologists in 2006-07, and was recognized with the Food Engineering Lifetime Achievement Award from the International Association for Engineering and Food in 2011.