Reverse Osmosis Equipment

Reverse Osmosis Equipment Reverse Osmosis Equipment Introduction to Reverse Osmosis Equipment: I. Overview Reverse osmosis (RO) technology is a modern high-tech development that has emerged in China in recent years. Reverse osmosis involves applying pressure greater than the osmotic pressure to a solution, forcing water molecules through a specially designed semi-permeable membrane, thereby separating them from the solution. This process is the opposite of natural osmosis, hence the name "reverse osmosis." By applying pressure exceeding the osmotic pressure of various solutes, reverse osmosis can separate, extract, purify, and concentrate specific solutions. Reverse osmosis systems primarily separate ions in solutions without the need for heating or phase change, resulting in lower energy consumption compared to traditional methods. These systems are compact, easy to operate, and widely applicable. Using reverse osmosis to treat industrial water does not consume large amounts of acids or alkalis, avoids secondary pollution, and incurs relatively low operating costs. II. Reverse Osmosis—Working Principle Osmosis is a common natural phenomenon. For example, when a cucumber is placed in saltwater, it loses water and shrinks. The process of water molecules moving from the cucumber into the saltwater solution is osmosis. If a membrane that allows only water molecules to pass through divides a tank into two sections, with pure water on one side and saltwater on the other, both filled to the same level, over time, the pure water level will drop while the saltwater level rises. This movement of water molecules through the membrane into the saltwater is called osmosis. The rise in the saltwater level is not infinite; it reaches an equilibrium point at a certain height. The pressure represented by the difference in liquid levels at this point is known as the osmotic pressure, which is directly related to the concentration of the saltwater. After equilibrium is achieved, if pressure is applied to the saltwater side, water molecules will migrate from the saltwater side to the pure water side. This phenomenon, where solvent molecules move from a dilute solution to a concentrated solution under pressure, is called reverse osmosis. By adding saltwater to one end of such a system and applying pressure exceeding its osmotic pressure, pure water can be obtained on the other end. This is the principle of reverse osmosis water purification. The key components of reverse osmosis systems for producing pure water are a selective membrane, known as a semi-permeable membrane, and sufficient pressure. Simply put, the semi-permeable membrane contains numerous pores similar in size to water molecules. Bacteria, viruses, most organic pollutants, and hydrated ions are much larger than water molecules and cannot pass through the membrane, thus separating them from the purified water. Among various impurities in water, dissolved salts are the most challenging to remove. Therefore, the effectiveness of reverse osmosis is often measured by its desalination rate. The desalination efficiency primarily depends on the selectivity of the semi-permeable membrane. Currently, high-selectivity reverse osmosis membrane elements can achieve desalination rates of up to 99.7%. III. Applications - Production of pure water and ultrapure water in electronics, industrial, pharmaceutical, and food industries. - Purification and preparation of process water in light textile and chemical industries, chemical circulating water, and manufacturing of chemical products. - Purification and preparation of water for food and beverage industries, drinking pure water, beverages, beer, liquor, health products, etc. - Recovery and concentration of valuable substances from aqueous solutions in industrial production. - Pre-desalination treatment of boiler feed water in the power industry, high-pressure boiler feed water for thermal power plants, and low-to-medium pressure boiler systems in factories and mines. - Desalination of brackish water and seawater. - Production of bottled water, mineral water, and other packaged drinking water. - Water for rinsing electronic components such as integrated circuits, silicon wafers, and display tubes in the electronics industry. - Water for pharmaceutical applications, including large-volume injections, injections, tablets, biochemical products, and equipment cleaning. - Desalination of seawater and brackish water for islands, ships, offshore drilling platforms, and brackish water regions. - Ultrapure water for other industrial processes, such as automotive and home appliance coating, coated glass, cosmetics, and fine chemicals.