Editorial

Ohne Zusammenfassung     

Issues in nonlinear stochastic grey box identification

Grey box identification refers to the practice of identifying dynamical systems in model structures exploiting partial prior information. This contribution reviews a method for stochastic grey box identification and surveys experiences and lessons of applying it to a number of industrial processes. Issues to be addressed include advantages and costs of introducing stochastics into the model, the question of what contribution must be expected from the model designer as opposed to what can be formalized in computer algorithms, and an outlook on future plans to resolve present shortcomings.     

Integrated fluid handling system for biomolecular interaction analysis.

An integrated fluid handling system used for multichannel biomolecular interaction analysis is described. Reactions between biological molecules are monitored in real time by measuring changes in the angular position where surface plasmon resonance occurs at a biospecific active surface. The adsorption efficiency of the analyte onto the biospecific active surface is up to approximately 3%, due to the low channel height, 50 microns, in the flow cell. When a large part of the total biospecific active surface for surface plasmon resonance probing (approximately 0.15 mm2) is used, the sensitivity is high. Sample sizes in the order of 1-50 microL can be injected. The sample zone dispersion is minimized by the low dead volume in the system (approximately 0.4 microL) accomplished by using integrated sample loops and thin conduits. An asset of this integration is the low reagent consumption. The sensor chip with the biospecific active surface is reusable and easily exchanged. Experimental results obtained with a theophylline monoclonal antibody as the analyte are compared with a theoretical model. The standard deviation for the repeatability is approximately 5% typically with 50 microL of 250 pM analyte, and the assay time is 10 min. The detection limit is approximately 10 pg of the analyte on the probed spot of the surface. Possible improvements of the sensitivity and detection limit are discussed.     

Autothermal two-stage gasification of low-density waste-derived fuels

In order to increase the efficiency of waste utilization in thermal conversion processes, pre-treatment is advantageous. With the Herhof Stabilat^® process, residual domestic waste is upgraded to waste-derived fuel by means of biological drying and mechanical separation of inerts and metals. The dried and homogenized waste-derived Stabilat^® fuel has a relatively high calorific value and contains high volatile matter which makes it suitable for gasification. As a result of extensive mechanical treatment, the Stabilat^® produced is of a fluffy appearance with a low density. A two-stage gasifier, based on a parallel-arranged bubbling fluidized bed and a fixed bed reactor, has been developed to convert Stabilat^® into hydrogen-rich product gas. This paper focuses on the design and construction of the configured laboratory-scale gasifier and experience with its operation. The processing of low-density fluffy waste-derived fuel using small-scale equipment demands special technical solutions for the core components as well as for the peripheral equipment. These are discussed here. The operating results of Stabilat^® gasification are also presented.