Table of Contents
Benefits of Using Dissolved Oxygen Sensors in Industrial Processes
Dissolved oxygen sensors play a crucial role in various industrial processes, providing valuable data that helps ensure the efficiency and quality of the final product. These sensors measure the amount of oxygen dissolved in a liquid, such as water, which is essential for many industrial applications. By monitoring and controlling the level of dissolved oxygen, companies can optimize their processes, reduce waste, and improve overall productivity.
One of the key benefits of using dissolved oxygen sensors in industrial processes is the ability to maintain optimal conditions for biological processes. In industries such as wastewater treatment, aquaculture, and fermentation, the presence of oxygen is essential for the growth and survival of microorganisms. By continuously monitoring the dissolved oxygen Levels, operators can ensure that the conditions are ideal for these biological processes to occur efficiently. This not only improves the overall performance of the system but also reduces the risk of costly downtime due to suboptimal conditions.
Another advantage of using dissolved oxygen sensors is the ability to detect and prevent oxygen-related issues in industrial processes. Oxygen can be both beneficial and detrimental in certain applications. For example, in the Food And Beverage industry, oxygen can cause spoilage and oxidation of products if present in excessive amounts. By monitoring the dissolved oxygen levels, companies can detect potential issues early on and take corrective actions to prevent product loss and maintain quality standards.
| Model No. | CIT-8800 Inductive Conductivity / Concentration Online Controller | |
| Measurement range | Conductivity | 0.00\\u03bcS/cm ~ 2000mS/cm |
| Concentration | 1.NaOH\\uff0c\\uff080-15\\uff09% or\\uff0825-50\\uff09%\\uff1b | |
| 2.HNO3\\uff08note the Corrosion resistance of the sensor\\uff09\\uff080-25\\uff09% or\\uff0836-82\\uff09%\\uff1b | ||
| 3.User-defined concentration curves. | ||
| TDS | 0.00ppm~1000ppt | |
| Temp. | \\uff080.0 ~ 120.0\\uff09\\u2103 | |
| Resolution | Conductivity | 0.01\\u03bcS/cm |
| Concentration | 0.01% | |
| TDS | 0.01ppm | |
| Temp. | 0.1\\u2103 | |
| Accuracy | Conductivity | 0\\u03bcS/cm ~1000\\u03bcS/cm \\u00b110\\u03bcS/cm |
| 1 mS/cm~500 mS/cm \\u00b11.0% | ||
| 500mS/cm~2000 mS/cm \\u00b11.0% | ||
| TDS | 1.5 level | |
| Temp. | \\u00b10.5\\u2103 | |
| Temp. compensation | element | Pt1000 |
| range | \\uff080.0~120.0\\uff09\\u2103 linear compensation | |
| \\uff084~20\\uff09mA Current output | channels | Double channels |
| features | Isolated, adjustable, reversible, 4-20MA output, instruments/ transmitter mode. | |
| Loop resistance | 400\\u03a9\\uff08Max\\uff09\\uff0cDC 24V | |
| Resolution | \\u00b10.1mA | |
| Control contact | Channels | Triple channels |
| Contact | Photoelectric relay output | |
| Programmable | Programmable \\uff08 temperature \\u3001conductivity/concentration/TDS\\u3001timing\\uff09output | |
| Features | Could set temperature\\u3001conductivity/concentration/TDS\\u3001 timing NO/NC/ PID selection | |
| Resistance load | 50mA\\uff08Max\\uff09\\uff0cAC/DC 30V\\uff08Max\\uff09 | |
| Data communication | RS485,MODBUS protocol | |
| Power supply | DC 24V\\u00b14V | |
| Consumption | \\uff1c5.5W | |
| Working Environment | Temperature\\uff1a\\uff080~50\\uff09\\u2103 Relative Humidity\\uff1a\\u226485%RH(non- condensing ) | |
| Storage | Temperature\\uff1a(-20~60)\\u2103 Relative Humidity\\uff1a\\u226485%RH(non- condensing) | |
| Protection level | IP65\\uff08with rear cover\\uff09 | |
| Outline dimension | 96mm\\u00d796 mm\\u00d794mm (H\\u00d7W\\u00d7D) | |
| Hole dimension | 91mm\\u00d791mm(H\\u00d7W) | |
| Installation | Panel mounted , fast installation | |
Furthermore, dissolved oxygen sensors help companies comply with regulatory requirements and industry standards. Many industries are subject to strict regulations regarding the discharge of wastewater and the quality of the final product. By accurately measuring and recording the dissolved oxygen levels, companies can demonstrate compliance with these regulations and avoid costly fines or penalties. Additionally, using dissolved oxygen sensors can help companies improve their sustainability efforts by reducing energy consumption and minimizing waste generation.
In addition to regulatory compliance and process optimization, dissolved oxygen sensors also offer cost-saving benefits for industrial processes. By accurately monitoring the oxygen levels, companies can identify opportunities to reduce energy consumption and improve efficiency. For example, in water treatment plants, maintaining the optimal dissolved oxygen levels can help reduce the amount of energy required for aeration, leading to significant cost savings over time. Similarly, in aquaculture operations, monitoring dissolved oxygen levels can help prevent Fish mortality and improve overall production yields, resulting in higher profits for the company.
Overall, the use of dissolved oxygen sensors in industrial processes offers a wide range of benefits, including improved process efficiency, regulatory compliance, cost savings, and sustainability. By investing in these sensors and integrating them into their operations, companies can enhance their competitiveness, reduce risks, and achieve long-term success. As technology continues to advance, the capabilities of dissolved oxygen sensors will only improve, providing even more opportunities for companies to optimize their processes and achieve their business goals.