Tailored to your industry, wastewater composition and treatment needs, Conqinphi offers one-stop customized evaporation solutions—from design, manufacturing to delivery, installation and after-sales.

In evaporation processes, process layout often determines operational success more than heat exchange area. For the same triple-effect evaporator, co-current flow saves pumps, counter-current flow increases concentration, parallel flow reduces scale buildup, and mixed flow offers a balance of advantages. This article uses 800 words to thoroughly explain the mechanisms, energy consumption, applicable scenarios, and failure modes of these four process flows, allowing process engineers to complete the initial selection within 5 minutes.

High-salinity, high-concentration wastewater, due to its extremely high salt and pollutant concentrations, is difficult to treat and has become a thorny problem in the field of industrial environmental protection. Its treatment technology requires the synergy of multiple processes to form a systematic solution. With industrial development and increasingly stringent environmental requirements, the treatment of high-salinity wastewater is not only related to enterprises' compliant discharge but also closely linked to resource recycling and sustainable development. This article will delve into its treatment technology system, current applications, and future directions.

With carbon emissions targets and soaring steam prices, energy consumption in evaporation processes now accounts for over 30% of manufacturing costs in industries such as chemicals, pharmaceuticals, and food. Traditional single-effect, double-effect, and triple-effect evaporation achieves tiered energy savings through "series steam utilization," while the new generation of mechanical steam recompression (MVR) technology directly "turns waste into treasure" with secondary steam. From single-effect to MVR, how much higher can the energy efficiency limit be pushed? We provide an objective answer with data.

The core working principle of MVR (Mechanical Vapor Recompression) evaporators lies in using a compressor to...

The core working principle of an MVR (Mechanical Vapor Recompression) evaporator is to upgrade the energy of the...

MVR evaporators (mechanical vapor recompression evaporators) are highly efficient and energy-saving evaporation...

MVR Evaporator Material Selection Guide – Material Decisions for Overcoming Multiple Challenges Including Acid Ions, Temperature, and Particle Size

The main battleground for MVR evaporation crystallization equipment in fine chemical plants can be summarized as the...