Reducing the environmental pollution and overall operating costs are the main challenges involved in the treatment of high-purity water.
The Siemens Industry Automation Division is showcasing a range of products designed to provide answers to these challenges while also improving customer competitiveness.
Among the products showcased by Siemens at the four-day trade show are its new Ionpure modules for continuous electrodeionization (CEDI). These modules provide higher flow rates, greater tolerance to feedwater hardness and low power consumption, thus extending the range of applications for OEMs.
Another new unit to be showcased is the Ionpure 600VDC G2, a power controller consisting of a semi-conductor rectifier and a display element. The power controller provides a high degree of reliability and flexible module control.
Moreover, the G2 rectifier is compatible with all MX, LX and VNX modules of the Ionpure range, reducing the cost and effort of system integration. Matching the rectifier, Siemens also offers a digital display element.
Another exhibit is the Ionpure LabXT unit, which was developed as a replacement option for several Elix laboratory water system models. This line of EDI modules is designed with thin cell and four-pass technology to meet the needs of operation on single-pass reverse osmosis water systems. OEMs can now incorporate a proven and reliable EDI solution into these compact modular systems which process three to ten liters per hour.
| Siemens Industry
COMPAMED 2017: New manufacturing processes for customized products
06.12.2017 | IVAM Fachverband für Mikrotechnik
SYSTEMS INTEGRATION 2018 in Switzerland focuses on building blocks for industrial digitalization
20.11.2017 | IVAM Fachverband für Mikrotechnik
Tiny pores at a cell's entryway act as miniature bouncers, letting in some electrically charged atoms--ions--but blocking others. Operating as exquisitely sensitive filters, these "ion channels" play a critical role in biological functions such as muscle contraction and the firing of brain cells.
To rapidly transport the right ions through the cell membrane, the tiny channels rely on a complex interplay between the ions and surrounding molecules,...
The miniaturization of the current technology of storage media is hindered by fundamental limits of quantum mechanics. A new approach consists in using so-called spin-crossover molecules as the smallest possible storage unit. Similar to normal hard drives, these special molecules can save information via their magnetic state. A research team from Kiel University has now managed to successfully place a new class of spin-crossover molecules onto a surface and to improve the molecule’s storage capacity. The storage density of conventional hard drives could therefore theoretically be increased by more than one hundred fold. The study has been published in the scientific journal Nano Letters.
Over the past few years, the building blocks of storage media have gotten ever smaller. But further miniaturization of the current technology is hindered by...
With innovative experiments, researchers at the Helmholtz-Zentrums Geesthacht and the Technical University Hamburg unravel why tiny metallic structures are extremely strong
Light-weight and simultaneously strong – porous metallic nanomaterials promise interesting applications as, for instance, for future aeroplanes with enhanced...
An interdisciplinary group of researchers interfaced individual bacteria with a computer to build a hybrid bio-digital circuit - Study published in Nature Communications
Scientists at the Institute of Science and Technology Austria (IST Austria) have managed to control the behavior of individual bacteria by connecting them to a...
Physicists in the Laboratory for Attosecond Physics (run jointly by LMU Munich and the Max Planck Institute for Quantum Optics) have developed an attosecond electron microscope that allows them to visualize the dispersion of light in time and space, and observe the motions of electrons in atoms.
The most basic of all physical interactions in nature is that between light and matter. This interaction takes place in attosecond times (i.e. billionths of a...
11.12.2017 | Event News
08.12.2017 | Event News
07.12.2017 | Event News
11.12.2017 | Physics and Astronomy
11.12.2017 | Earth Sciences
11.12.2017 | Information Technology