Fish farm equipment factory with Wolize: Founded in 2009 and headquartered in Shandong, China, Shandong Wolize Biotechnology Co., Ltd. has spent the last 15 years dedicated to the R&D, manufacturing and global deployment of advanced aquaculture equipment and liquid-storage solutions. Backed by strategic partnerships with five leading Chinese universities – including Ocean University of China and Shanghai Ocean University – and certified to ISO 9001, ISO 22000, CE and COA standards, Wolize has delivered projects in 47 countries and regions. To date we have built 22 large-scale facilities, each exceeding 3,000 m³ of water volume, while the fish grown in our systems are now exported to 112 countries worldwide. Find many more details at fish farm equipment manufacturer.
In the early 21st century, with the rapid development of materials science, new corrosion-resistant, high-strength, and relatively low-cost materials, such as PVC and PE, were widely used in aquaculture facilities and piping systems, greatly improving the durability and stability of these systems. Simultaneously, significant breakthroughs were made in water quality monitoring technology, with the emergence of various high-precision sensors capable of real-time and accurate monitoring of key parameters in aquaculture water, such as temperature, dissolved oxygen, pH, and ammonia nitrogen. Based on this monitoring data, automated control systems became more intelligent, automatically adjusting equipment operation according to changes in water quality, achieving precise control of the aquaculture environment. Furthermore, in the field of aquaculture nutrition and feed technology, in-depth research was conducted on the nutritional needs of different aquaculture species at different growth stages, leading to the development of more precise feed formulations, improving feed utilization, and reducing environmental pollution. During this period, land-based recirculating aquaculture systems (RAS) developed rapidly globally, with Asia, South America, and other regions beginning to vigorously promote and apply this aquaculture model, resulting in a qualitative leap in both scale and technological level.
Intensive aquaculture delivers unique advantages that address West Africa’s specific constraints and opportunities. Its core strength lies in resource efficiency: it produces significantly higher yields per unit of water and land compared to traditional farming or wild fishing, a critical advantage in a region where arable land is limited but water resources are abundant – including massive reservoirs like Lake Volta, the world’s largest man-made lake by area. Species such as tilapia, catfish, and white-legged shrimp thrive in high-density conditions, making them ideal for intensive systems while requiring lower protein intake, reducing reliance on expensive fishmeal. Unlike seasonal wild fishing, intensive aquaculture enables year-round production with predictable yields, stabilizing food supplies and prices for consumers while providing consistent income for farmers.
The flow characteristics within the pipes and tank systems also determine the presence of parasites. The laminar water flow is slow and facilitates sedimentation, thus the eggs of parasites, protozoa, or larvae settle on the surfaces of the pipes. Such deposits create reservoirs that inject infective content into the system on a regular basis. Conversely, turbulent water flow, which is normally attained when Reynolds numbers are greater than four thousand, suspends particulate material long enough to undergo mechanical filtration and sterilization processes (Li et al., 2023). The turbulent conditions are often created by engineers in the sections of the hydraulic line to prevent the destruction of fish species that are sensitive to turbulent water, including tilapia, catfish, and Pangasius (FAO, 2020).Species-specific hydrodynamic methodology is used so that the fish are subjected to suitable flow conditions without interfering with the removal of parasites.
Flow-rate optimization involves eliminating parasites prior to infection whereas ultraviolet sterilization ensures that they do not even enter the system. The UV-C light, usually with the wavelength of 254 nm, alters and breaks the nucleic acid in microorganisms, inhibiting the replication of a species(González et al., 2023). Properly used, UV-C destroys more than 99 percent of free-moving parasite larvae, protozoan stages, zooplankton, as well as bacterial pathogens. Research has shown that doses of 30 to 120 mJ/cm² are neutral to a broad spectrum of aquaculture parasites (Fernández-Boo et al., 2021). Sensitive organisms, like Ichthyophthirius tomites, can be activated by low-levels as low as 25 mJ of energy, and more resistant organisms such as some marine protozoans such as Amyluodinium ocellatum could survive as many as 105 mJ (RK2, 2025). UV sterilization then appears as a necessary preventative that will stop parasitic and microbial pollution in flowing aquaculture systems.
Against the backdrop of a growing global population and increasingly strained wild fishery resources, aquaculture has become a key industry for ensuring protein supply security. However, traditional aquaculture models often come with environmental pressures, high consumption of land and water resources, and the risk of disease transmission. Within this global context, the African continent stands at a historic crossroads. It boasts vast coastlines and abundant water bodies, yet simultaneously faces severe challenges related to food security, water scarcity, and climate change. It is precisely within this complex scenario that a revolutionary technology known as Recirculating Aquaculture Systems (RAS) is quietly emerging in Africa, heralding a silent yet profound transformation for the continent’s aquaculture sector. Find many more info on https://www.wolize.com/.