Keller summarized some common separation techniques and application maturity diagrams in 1987. Distillation, extraction, absorption, crystallization, etc. are still the most widely used separation techniques. Although the concept of liquid membrane separation is clever, there are still limitations in technology, and it has only been applied in drug release.
The complexity of chemical separation technology The importance and diversity of chemical separation technology determine its complexity. Even for mature technologies such as distillation and extraction, the design of large multi-component equipment is still a difficult task. The problem is the lack of basic data and reliable design methods for large towers. For high-temperature, high-pressure, multi-component, and strong non-ideal systems, it is difficult to accurately calculate the equilibrium data and molecular diffusion coefficients, and even physical properties such as interfacial tension viscosity are difficult to obtain.
Coupled separation techniques such as catalysts and reactive extractions have even less basic data. The main difficulty in the amplification of large-scale tower designs is that the two-phase flow and mass transfer characteristics in the tower are complex and the digital model is not yet perfect. The balance-level model that has been used for more than a hundred years is simple and intuitive, but the disadvantages of the multi-component separation process are obvious. Non-equilibrium models are known to have the advantage of “possibly creating a new era of plate separation equipment design and simulationâ€, but lack of mass transfer coefficient experimental data and model parameters are too many, making it difficult for engineering applications. The developed software is powerful and has been applied in engineering design. However, engineering experience and pilot test are still indispensable.
The forward-looking nature of separation technology With the development of basic industries and high-tech such as energy, resources, environment, and new materials, classification technology faces new opportunities and challenges. The separation process in the petrochemical sector requires further energy and pulp consumption, making full use of energy and resources. The pace of large-scale production equipment is accelerating, and energy consumption and costs are continuously decreasing. In biopharmaceutical engineering, with the development of genetic engineering and cell engineering, biopharmaceuticals have developed rapidly. Supercritical extraction using CO2 as a solvent has the advantages of non-polluting products and high selectivity. Chromatographic separation, electrophoretic separation and other methods have been successfully used in production and laboratory research because of their high efficiency, normal temperature and pressure characteristics. With the strengthening of environmental awareness, the "three wastes" treatment has attracted attention. From an industrial ecology point of view, the "wastes" discharged from many processes are no longer "useless" but are materials that are not fully utilized. "Three-waste treatment" is a new challenge for separation technology.
The Particularity of Separation Technology The competition promotes the strengthening of the separation process. The strengthening of the separation process includes two aspects: the new installation and the new process. Any new chemical separation technology that can make the equipment smaller, energy efficient, and conducive to sustainable development belongs to the strengthening of the separation process. This is one of the important trends in the development of chemical separation technology.
Coupled separation techniques are of interest. Catalyst coupling, membrane distillation, adsorption distillation, reaction extraction, complex adsorption, reverse micelles, membrane extraction, fermentation extraction, chemical adsorption, and electrophoretic extraction have been well-established and industrialized. Coupled separation techniques may solve many tasks that traditional separations have difficulty performing. Electrokinetic coupling chromatography can efficiently separate vitamins.
Information technology has promoted the development of separation technologies. Separation science and technology have the characteristics of multi-discipline, and the combination of information technology and traditional chemical methods has accelerated the progress of separation technology.
Reactive Silicone Fluid Series
Silicone oil generally refers to linear polysiloxane products that remain liquid at room temperature. Generally divided into two types: methyl silicone oil and modified silicone oil. The most commonly used silicone oil-methyl silicone oil, also known as ordinary silicone oil, its organic groups are all methyl, methyl silicone oil has good chemical stability, insulation, and good hydrophobic properties. It is obtained by hydrolyzing dimethyldichlorosilane with water to obtain the primary polycondensation ring body. The ring body is cracked and rectified to obtain the low ring body, and then the ring body, the capping agent and the catalyst are put together to obtain each A mixture of different polymerization degrees can be obtained by vacuum distillation to remove low-boiling substances.
Silicone Fluids,Silane Coupling Agent,Reactive Silicone Fluid,Reactive Silicone Polyether Oil
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