Separation Principles Technique

C.E. Meloan, Chemical Separations, Principles, Techniques and Experiments, J. Wiley Sons, New York, 2000, ISBN 0471351970. 

C. E. Meloan, Chemical Separations Principles, Techniques Experiments, Wiley-Interscience, New York, NY (2000). 

It s easier to pinpoint and eliminate any physical or technical contradictions. See Structured Abstraction (Technique 23) and Separation Principles (Technique 24) for more. 

Review each cell in the matrix and discuss the merits of joining the two characteristics. Eliminate cells that contain existing ideas or don t make sense (such as spa services and in-seat chargers). However, don t immediately discard ideas because they contain technical or physical contradictions you may be able to get past the contradictions using Structured Abstraction (Technique 23) or Separation Principles (Technique 24). 

As a result, of applying movement to the PT statements, you should have a list of innovative ideas to explore further. Your ideas may be ready-made solutions. More than likely, however. Provocation and Movement may have pushed you to the boundaries of what is possible. In this case, you may need to leverage Structured Abstraction (Technique 23) or Separation Principles (Technique 24) to help you overcome any physical or technical contradictions inherent in your ideas. 

Use the Separation Principles technique when you ve identihed a physical contradiction, and when other ideation techniques may have fallen short of resolving it. You may need the help of an expert to apply Separation Principles, depending on the nature of your innovation project and its difficulty level. 

This technique comes in handy when the innovation opportunity is (a) well-defined and (b) contains at least one technical contradiction (see Structured Abstraction, Technique 23) or physical contradiction (see Separation Principles, Technique 24). Unless you re well-versed in the Theory of Inventive Problem Solving (TRIZ), you will need special assistance from an expert to properly apply this technique. Several U.S. and U.K. organizations can help (see resource list at the end of this technique). 

New York, John Wiley Sons, Inc., 1999, pp.xv,752 CHEMICAL SEPARATIONS- PRINCIPLES, TECHNIQUES, AND EXPERIMENTS MELOAN, C E... 

H. Axelsson, Centrifugal Separations—Principles and Techniques, Alfa Laval Separation, Tumba, Sweden, presented at the Bioprocess Technology Program, University of Virginia, Charlottesville, Va., Oct. 17—25 1991. 

CE provides analysis based on orthogonal separation principles compared to other techniques as well as high resolving power. Like slab gel electrophoresis, CE is a family of techniques that resolve sample components by differences in intrinsic molecular characteristics such as size, mass, charge, differential interaction, and isoelectric point (pi). 

CE is frequently compared to two of the mainstream techniques in the protein laboratory HPLC and gel electrophoresis. The comparison to HPLC focuses on the instrumentation format and modes of detection, whereas gel electrophoresis shares its separation principles with CE. CE exploits the same molecular differences of the sample components to achieve separation as slab gel... 

Electrophoresis has been used for a long time as one of the most important separation principles in analytical biochemistry. In particular, it has been applied to the separation of DNA and DNA components. Electrophoretical techniques have predominated in this field for decades and will continue to do so in the future. The advent of capillary electrophoresis (CE) has boosted the development of electrophoretic techniques, because it opened access to higher sensitivity, better resolution, and greater speed of separation (1-3). 

RPC is the most common and important separation system in HPLC. The popularity of this technique is due to the versatility and convenience of the system. The separation principle is readily... 

Naturally, there exist a variety of membrane separation processes depending on the particular separation task [1]. The successful introduction of a membrane process into the production line therefore relies on understanding the basic separation principles as well as on the knowledge of the application limits. As is the case with any other unit operation, the optimum configuration needs to be found in view of the overall production process, and combination with other separation techniques (hybrid processes) often proves advantageous for large-scale applications. 

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