Easy Chloramination Monitoring

Easy Chloramination Monitoring

A chloramination analyzer is a device used to measure the concentration of chloramines in water treatment systems, a type of disinfectant. Chloramines are a mixture of chlorine and ammonia. They are an alternative to chlorine in water treatment because they are more stable and have a more prolonged residual effect.

Chloramination analyzers use various techniques to measure the concentration of chloramines in the water, including colorimetric methods, amperometric methods, and ultraviolet-visible spectrophotometry. These methods measure the volume of chloramines in a water sample and provide a numerical reading of the concentration.

Chloramination analyzers are typically used in water treatment plants to monitor the effectiveness of the chloramination process. They are also used to ensure that the concentration of chloramines in the treated water meets the required levels for safe drinking water. Additionally, they monitor the effectiveness of the chloramination process and ensure that the concentration of chloramines in the treated water is at the correct level for safe drinking water.

In summary, Chloramination Analyzer is a device used to measure the concentration of Chloramines in water treatment systems. Chloramines are used as an alternative to chlorine in water treatment because they are more stable and have a more prolonged residual effect. Chloramination analyzers are typically used in water treatment plants to monitor the effectiveness of the chloramination process and ensure that the concentration of chloramines in the treated water meets the required levels for safe drinking water.

The HF scientific MCX Monochloramine Analyzer features a unique pump design for more straightforward maintenance and accurate readings every 15 minutes. You can enjoy continuous monitoring and smoother day-to-day operations when you have a reliable, easy-to-use monochloramine analyzer in your facility.

For more information about the MCX Monochloramine Analyzer, contact Alliance Technical Sales. Call them at 630-321-9646 or visit them at https://alliancets.com.

Magnetic Level Gauges in Process Control

Magnetic Level Gauges in Process Control

A magnetic level gauge is a type of instrument that is used to measure the level of a liquid in a tank or process vessel. It works by using a magnetically coupled float that moves up and down along a calibrated vertical scale as the level of the liquid changes. The position of the float is indicated by a pointer or display that is visible to the operator.

In process control applications, the magnetic level gauge is used to monitor and control the level of liquids in tanks, vessels, and other containers. This is important for a number of reasons, including safety, efficiency, and product quality. For example, if the level of a liquid is too low, it may indicate a leak or a problem with the process. On the other hand, if the level is too high, it may indicate that the process is running too quickly or that there is a risk of overflow.

The magnetic level gauge is typically mounted on the outside of the tank or vessel, which allows the operator to easily monitor the level of the liquid without having to open the vessel or disrupt the process. Some gauges may also be equipped with alarms or automatic control systems that can shut down the process if the liquid level becomes too high or too low.

Overall, the magnetic level gauge is an important tool in process control, as it helps to ensure the safe and efficient operation of industrial processes that involve the handling of liquids.

For more information, contact Alliance Technical Sales. Call 630-321-9646 or visit https://alliancets.com.

Process Analytics: Measuring pH, Dissolved Oxygen, and Conductivity

Process Analytics: Measuring pH, Dissolved Oxygen, and Conductivity

pH, dissolved oxygen, and conductivity are important parameters to measure in industrial processes because they can provide valuable information about the products' quality and safety. By measuring these parameters, industrial processes can ensure that they are operating within safe and optimal ranges, which can improve the quality and efficiency of the products.


pH


pH is a measure of the acidity or basicity of a solution, and it can significantly impact the behavior of chemicals in a process. 


There are several ways to measure pH in industrial processes, including using a pH meter, pH test strips, and indicator solutions. A pH meter is a commonly used instrument that measures the pH of a solution by using a probe to measure the electrical potential difference between the solution and a reference electrode. pH test strips are also commonly used in industrial processes, as they are quick and easy to use and provide a general indication of the pH of a solution. 


Dissolved Oxygen


Dissolved oxygen is vital because many industrial processes involve biological organisms that require oxygen to survive and function properly. 


There are several ways to measure dissolved oxygen in industrial processes, but some of the most common methods include the following:


  • Electrochemical sensors: These sensors use an electrode to measure dissolved oxygen concentration in a solution.
  • Optical sensors: These sensors use light to measure the amount of dissolved oxygen in a solution.
  • Membrane-based sensors: These sensors use a thin membrane to separate the sample being measured from the oxygen-sensitive material, allowing for accurate dissolved oxygen levels.

Conductivity


Conductivity is a measure of the ability of a solution to conduct electricity. It can provide information about the concentration of ions in the solution, which can be helpful in various applications. 


Conductivity in industrial processes is typically measured using a conductivity meter. This device uses electrodes to pass an electrical current through a substance sample and measures the substance's resistance to the flow of electricity. The resistance converts into a conductivity reading, typically reported in units of siemens per meter (S/m).


It's worth noting that the most appropriate method for measuring dissolved oxygen, conductivity and pH in industrial processes will depend on the application's specific requirements. It's always a good idea to consult with an expert in the field to determine the best method for your particular needs.


METTLER TOLEDO provides analytical transmitters for a wide range of analytics, including pH/ORP, oxygen, dissolved carbon dioxide and conductivity or resistivity. These analytical transmitters are the component within a measurement system that communicates displayed measurements to a user or higher level control system.  METTLER TOLEDO high-performance analytical transmitters offer compatibility with traditional analog sensors and digital sensors with METTLER TOLEDO's Intelligent Sensor Management (ISM).


Discuss your process analytics requirements with professional, skilled expert engineers. Alliance Technical Sales is available to assist in the application and specification of sensors, transmitters, and controllers for any industrial process. Call them at 630-321-9646 or visit their website at https://alliancets.com.





Winterization Tips for Your Building, Facility, or Industrial Plant

Freeze Protection Tips

Anticipating freezing temperatures and safeguarding buildings, equipment, and materials from freeze damage are critical components of any annual property assessment. A solid freeze prevention plan comprises inspection, preventative maintenance, and corrective maintenance actions before the onset of cold weather.

Below are eighteen general freeze protection planning tips offered by application engineers and field experience comments. These procedures are not exhaustive, and we urge that you consult a professional before implementing your plan.
  1. Roof and Gutter: Inspect, remove debris, and patch/repair (if needed): roof drains, scuppers, canals, gutters, down spouts before first frost. Inspect and functionally test installed roof and gutter heat trace system. Apply heat in susceptible areas.
  2. Identify and test main water supply cutoffs for each facility. Ensure these areas are readily available to emergency personnel responding to a freeze/thaw incident. Apply heat in susceptible areas.
  3. Inspect wet‐pipe sprinkler systems for areas prone to freezing. Apply heat in susceptible areas.
  4. Identify materials that are subject to freeze damage in outside storage pads and unheated storage areas. Develop plan to ensure these materials can be easily heated and thawed to maintain production.
  5. Check and place antifreeze used in cooling systems as necessary.
  6. Protect heating system power and temperature controls against inadvertent deactivation.
  7. Inspect insulation on piping and vessels.  Look for damage and vulnerable areas that might be exposed to freezing conditions.  Add or replace insulation as needed. 
  8. Drain and remove water from all seasonal cooling systems (unless protected by heating tapes or antifreeze).
  9. Inspect, test, and stage portable auxiliary heaters.
  10. Inspect conditions of all surface heaters such as heating tapes, heating cable, drum heaters, IBC heaters, tank heaters, and pipe heaters. Verify operation and temperature settings and test ground‐fault equipment protection. Replace as needed.
  11. Inspect, test, and repair heat trace heating cable located on cooling tower supply and return lines.  Apply heat in susceptible areas.
  12. Inspect and identify remaining water and air lines subject to freezing. Install appropriate heat and insulation. Apply heat in susceptible areas.
  13. For steam systems: Blow down drip legs, clean strainers, test temperature sensing devices for actuation of control valves and dampers, check steam traps, control actuators/valves, face and bypass dampers, linkages, and temperature controllers. Ensure that a vacuum breaker is installed and in working order on all preheat and heating coils which may be exposed to freezing conditions.
  14. For ventilation systems: Test and calibrate all temperature sensing devices, and check operation of valves, dampers, linkages, control actuators, and temperature controllers.
  15. Identify areas where personal safety is at risk due to icy conditions. Develop a slip prevention maintenance plan. Apply heat in susceptible areas.
  16. Identify control panels and electronic devices susceptible to condensation. Install enclosure heaters to prevent short outs and corrosion.
  17. Institute a facility wide awareness plan to identify and report any suspected problems with heating or other cold weather protection equipment during the cold season.

  18. Special Consideration: Hazardous Materials 
  • Ensure that all containers used for hazardous or toxic materials are properly stored, and inspect them for deterioration prior to handling. If containers become brittle (due to the combination of chemical attack, freezing temperatures, and ultraviolet light) they may break when moved.
  • Liquids should not be permitted to remain in unheated process lines during periods when production has been stopped. All lines should be drained and purged to prevent future line breakage due to freezing temperatures.
  • Ensure that piping, tanks, and valves in systems that carry hazardous or toxic substances are properly insulated and/or heated. Install heaters such as heating blankets, insulators, heating tapes, heating jackets, and heating cable as appropriate.
Tips courtesy of BriskHeat. For more information on all BriskHeat products, contact Alliance Technical Sales. Call 630-321-9646 or visit https://alliancets.com.