Dengan perkembangan teknologi desalinasi air laut (reverse osmosis), SWRO adalah cara utama yang dapat menghasilkan air tawar dari air laut atau air yang berwarna kehitaman di abad ke-21 saat ini, namun, masih ada banyak masalah pada biaya operasi. Dan konsumsi energi untuk osmosis balik air laut (SWRO) is one of main factors that affect the cost of desalination product. Energy reduction is therefore imperative.

How is the function for energy recovery device?

The function of energy recovery device is to reduce energy consumption and cost by recycling and reusing the pressure energy from RO system high pressure concentrated seawater. Energy Recovery Device (ERD) is the key to energy-saving in the operation of any seawater reverse osmosis (SWRO) desalination products, in which PX Pressure Ex-changer device is the most efficient solution available today and can reduce the energy consumption of seawater reverse osmosis (SWRO) systems by up to 60 percent.

The cost of power consumption accounts for the largest proportion, which is around 30% of the total RO operating cost. Typically for large facilities (>50,000m3/d), the ERD that reduces energy consumption is only a fraction of the initial capital cost (1-2%) of the entire plant, but offer major return on investment through energy savings.

How is PX Pressure Ex-changer energy recovery device working principle?

  1. The PX Pressure Ex-changer energy recovery device promotes pressure transfer from the high pressure brine reject stream to a low-pressure seawater feed stream by putting the two streams into the state of direct and momentary contact in the ducts of a rotor. The rotor is installed into a ceramic sleeve between two ceramic end covers with precise clearances.
  2. When injecting high-pressure water, it can create a hydrodynamic bearing without almost friction. The rotor spinning inside the hydrodynamic bearing is the only moving part in the PX device. At any time, half of the rotor ducts are exposed to the high-pressure stream and half to the low-pressure stream. When the rotor turns, the ducts pass a sealing area that separates high and low pressure. Thus, the ducts that contain high pressure are separated from the adjacent ducts containing low pressure by the seal formed with the rotor’s ribs and the ceramic end covers.
  3. When the rotor turns every time, this pressure exchange process is repeated for each duct, so that the ducts are continuously filling and discharging. At a nominal speed of 1,200 rpm, 20 revolutions are completed every second.

 Advantages recover pressure energy device

  1. Exceptionally High Energy Recovery Efficiency At the heart of the PX unit lies a rotor crafted from high-purity alumina ceramic—the sole moving component within. It achieves direct pressure energy transfer by enabling brief, direct contact between high-pressure brine and low-pressure feed water within the rotor’s microchannels. This process eliminates the multi-step conversion required by traditional technologies—first converting pressure energy into mechanical energy and then back into pressure energy—resulting in minimal energy loss. Consequently, the PX unit achieves a peak efficiency of 98%, with actual operating efficiency typically stabilizing between 93% and 96.4%. This means the vast majority of pressure energy that would otherwise be wasted is successfully recovered.
  2. Significant Energy Savings and Reduced Consumption Thanks to this highly efficient energy recovery, the system’s reliance on high-pressure pumps is substantially reduced. In practical industrial applications, such as in nanofiltration brine purification systems, adopting the PX process can reduce the total installed power of the high-pressure system by approximately 39%. This not only lowers electricity consumption but also decreases the capacity demands on the power grid.
  3. Exceptional Reliability and Durability The unit’s rotor is constructed from ultra-hard alumina ceramic, offering exceptional resistance to corrosion and wear. Combined with a minimalist design featuring only one moving part and few friction points, the PX unit delivers high reliability, extended service life, and low maintenance requirements.
  4. Outstanding Economic Benefits While requiring an initial investment, the PX unit delivers significant economic returns through substantial energy savings. In many cases, the investment cost can be recouped within two years or less through reduced electricity bills. Long-term economic benefits become even more substantial as the system operates over time.
  5. Excellent Operational Flexibility Featuring a modular design, the PX unit can be flexibly adapted to various water treatment project scales by parallel connection of multiple units. It accommodates diverse feed conditions—from brackish water to seawater desalination—and exhibits adaptability to flow and pressure fluctuations.

Practical Applications and Considerations

The technical advantages of PX pressure exchangers make them core equipment for reducing energy consumption in modern seawater desalination and challenging industrial wastewater reuse/zero-liquid discharge projects. For instance, in Shandong Haihua’s soda ash plant, the PX unit achieved 96.4% energy recovery when integrated with the nanofiltration brine purification system. In a zero-liquid discharge project at a lithium battery materials plant in Hubei, ultra-high-pressure PX equipment integrated with DuPont membrane technology substantially reduced overall energy consumption and operational costs.

To ensure efficient and stable operation of PX units, pay particular attention to the following:

  • Feedwater Quality: Water entering the PX unit must undergo precision filtration to ensure particle diameters are less than 5 microns, preventing rotor jamming or wear.
  • Flow and Pressure Control: During operation, strictly maintain flow and pressure within rated limits to avoid exceeding specifications. Exceeding limits may cause “fluid penetration,” compromising system stability.
  • Long-Term Shutdown Maintenance: For extended shutdowns, thoroughly flush the unit with fresh water and implement antimicrobial measures to prevent rotor jamming caused by biological growth or salt precipitation.

KYsearo skala yang lebih besar sistem desalinasi air laut (above 120 TPD) will equip ERI’s energy recovery device, which can curtail energy consumption to 3~4 KWH per cubic meter product water, comparing with the system without ERD 6~7 KWH, reducing the running cost up to 49%. Should you have further interest in application details for specific industries—such as chemical wastewater treatment or seawater desalination—we welcome continued discussion.

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