Problem See Section | Emerson PN 51-1055pHC/rev.K instruction

MODEL SOLU COMP II	SECTION 8.0
	TROUBLESHOOTING

8.3 TROUBLESHOOTING WHEN NO ERROR MESSAGE IS SHOWING — pH.

	Problem	See Section

	New temperature during calibration more than 2-3°C different from the live reading	8.3.1

	Calibration Error warning during two-point calibration	8.3.2

	Calibration Error warning during standardization	8.3.3

	Invalid Input while manually entering slope	8.3.4

	Sensor does not respond to known pH changes	8.3.5
	Calibration was successful, but process pH is slightly different from expected value	8.3.6

	Calibration was successful, but process pH is grossly wrong and/or noisy	8.3.7

8.3.1 Difference Between Solu Comp II and Standard Thermometer is Greater Than 3°C.

A.Is the standard thermometer, RTD, or thermistor accurate? General purpose liquid-in-glass thermometers, par- ticularly ones that have been mistreated, can have surprisingly large errors.

B.Is the temperature element in the pH sensor completely submerged in the test liquid?

C.Is the standard temperature sensor submerged to the correct level?

D.Review Section 6.2.

8.3.2 Calibration Error During Two-Point Calibration

Once the two-point (manual or automatic) calibration is complete, the Solu Comp II automatically calculates the sensor slope (at 25°). If the slope is greater than 60 mV/pH or less than 45 mV/pH, the analyzer displays the Calibration Error screen and does not update the calibration. Check the following:

A.Are the buffers accurate? Inspect the buffers for obvious signs of deterioration, such as turbidity or mold growth. Neutral and slightly acidic buffers are highly susceptible to molds. Alkaline buffers (pH 9 and greater) that have been exposed to air for long periods may also be inaccurate. Alkaline buffers absorb carbon dioxide from the atmosphere, which lowers the pH. If a high pH buffer was used in the failed calibration, repeat the calibration using a fresh buffer. If fresh buffer is not available, use a lower pH buffer. For example, use pH 4 and 7 buffer instead of pH 7 and 10 buffer.

B.Was adequate time allowed for temperature equilibration? If the sensor was in a process substantially hotter or colder than the buffer, place it in a container of water at ambient temperature for at least 20 minutes before starting the calibration. Using auto calibration avoids calibration errors caused by temperature drift. The ana- lyzer will not update readings until the drift is less than 0.02 pH over 10 seconds.

C.Were correct pH values entered during manual calibration? Using auto calibration eliminates errors caused by improperly entering data.

D.Is the sensor properly wired to the analyzer? Check the sensor wiring including any connections in a junction box. See Section 3.2.

E.Is the sensor dirty or coated? See the sensor instruction manual for cleaning instructions.

SRef Imp	123k^
Glass Imp	123M^

F. Is the sensor faulty? With the main display showing, use or to scroll through the information screens until the electrode impedance screen (at left) is displayed. Refer to the table on the following page for an interpretation of the impedance readings.

Another way of checking for a faulty sensor is to replace it with a new one. If the new sensor can be calibrat- ed, the old sensor has failed.

G. Is the analyzer faulty? The best way to check for a faulty analyzer is to simulate pH inputs. See Section 8.6.

PN 51-1055pHC/rev.K specifications

The Emerson PN 51-1055pHC/rev.K is a highly advanced and reliable component designed for a wide range of applications in industrial automation and control systems. This device is known for its robust performance, exceptional durability, and integration of cutting-edge technologies, making it an ideal choice for demanding operational environments.

One of the key features of the PN 51-1055pHC/rev.K is its versatility. It is compatible with various systems and can be easily integrated into existing configurations without the need for extensive modifications. This adaptability allows users to streamline their operations and enhance overall efficiency, ensuring that the PN 51-1055pHC/rev.K is suitable for diverse industrial scenarios.

Technologically, the device incorporates advanced sensor capabilities that enable accurate monitoring and measurement of critical parameters. These sensors are designed to provide real-time data, allowing operators to make informed decisions quickly. The real-time diagnostics feature is essential for maintenance, as it helps predict potential issues before they lead to system failures, thereby reducing downtime and operational costs.

The PN 51-1055pHC/rev.K also boasts a rugged construction, built to withstand harsh industrial conditions such as extreme temperatures, vibrations, and moisture. This durability ensures a long lifespan, making it a cost-effective investment for businesses looking to optimize their operations without frequent replacements or repairs.

Another critical characteristic of the Emerson PN 51-1055pHC/rev.K is its user-friendly interface. The device is designed with ease of use in mind, featuring intuitive controls and straightforward setup processes. This accessibility enhances user experience, allowing both seasoned technicians and new operators to utilize its capabilities effectively.

Additionally, the device supports various communication protocols, enabling seamless integration with other equipment and systems. This feature is crucial for creating interconnected environments where data can be shared and analyzed across multiple platforms, fostering smarter and more efficient industrial processes.

In summary, the Emerson PN 51-1055pHC/rev.K stands out for its versatility, advanced sensor technologies, rugged design, user-friendly interface, and communication capabilities. It is a powerful tool for businesses seeking improved automation and control, helping to drive efficiency and enhance operational reliability in any industrial setting.