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Rosemount 3153N Nuclear Qualified Pressure Transmitter

Industry-leading performance

– Meets the following standards

o IEEE Std 323™-1974/1983/2003

o IEEE Std 344™-1975/1987/2004

– 36 Mrad (360 kGy) TID Gamma Radiation

– 8.5g ZPA Seismic

– 333ºF (167.2ºC) Vapour/Temperature

– 0.2% Reference Accuracy

Introduction to the Rosemount 3153N Nuclear Pressure

The Rosemount 3153N Nuclear Pressure Transmitter is designed for precision pressure measurement in nuclear applications.

These applications require reliable performance and safety over a long service life.

The 3153N complies with IEEE Std 323™-1974/1983/2003 and IEEE Std 344™-1975/1987/2004.

Irradiance is 36 Mrads TID Gamma, Seismic Rating 8.5g ZPA, and Vapour Pressure/Temperature Performance.

Rigorous quality control during manufacturing includes traceability of pressure retaining components, special nuclear cleaning and hydrostatic pressure testing.

Transmitter Description

The Rosemount 3153N transmitter is similar in construction and performance to the proven Rosemount 3051 transmitter.

The transmitter is available in absolute (AP), gauge (GP), and differential (DP) configurations with a choice of six pressure ranges.

Direct electronic sensing using a fully sealed www.cniacs.com coplanar capacitive sensing element (see Figure 1) eliminates mechanical force transfer and problems associated with shock and vibration.

Compact design, two-wire system compatibility, and non-interactive external range and zero adjustments for standard calibration simplify installation and commissioning.

Wiring terminals and electronics are located in separate compartments, helping to

ensure that the electronics remain sealed during installation.

Operation

The process pressure is transmitted to the sensing diaphragm in the centre of the sensor unit by means of an isolating diaphragm and a silicone oil filler fluid.

The process or reference pressure is transmitted in a similar manner to the other side of the centre sensing diaphragm.

Capacitor plates on both sides of the sensing diaphragm detect the position of the sensing diaphragm.

Sudden and small axial movements should be detected within 40 milliseconds or less to minimise or avoid rotor-to-casing contact.

or avoid rotor-to-case contact. Redundant sensors and voting logic are recommended.

Thrust bearing temperature measurement is strongly recommended as a supplement to thrust position monitoring.

Shaft thrust monitoring consists of one to three displacement sensors mounted on the shaft end or thrust collar in the axial direction parallel to the shaft.

The displacement sensors are non-contact sensors that measure shaft position.

For critically important safety applications, the A6250 monitor provides triple redundant thrust protection.

The A6210 monitor can also be configured for differential expansion measurement.

During turbine start-up, both the casing and the rotor expand due to changes in thermal conditions.

Differential expansion therefore measures the relative difference between the displacement sensor mounted on the housing and the target of the sensor mounted on the shaft. If

housing and shaft grow at approximately the same rate, the differential expansion remains ideally close to zero.

Differential expansion measurement modes are supported in series/complementary or cone/slope modes.

Finally, the A6210 monitor can be configured in average rod drop mode to monitor riding belt wear in reciprocating compressors.

Over time, the rider band in a horizontal reciprocating compressor wears due to the force of gravity acting on the horizontally orientated piston in the compressor cylinder.

If the rider belt wears beyond the point where the piston would come into contact with the cylinder wall, damage to the machine and possible malfunction occurs.

By installing at least one displacement probe to measure the piston rod position, you will be notified when the piston drops – a sign of a worn rider band.

You can then set the shutdown protection threshold for automatic tripping.

The average piston rod drop parameter can be used as a coefficient to indicate actual riding belt wear.

Or, without applying any coefficients, the rod drop will indicate the actual movement of the piston rod.

The AMS 6500 is easily integrated with DeltaV and Ovation process automation systems.

Includes pre-configured DeltaV graphical Dynamos and Ovation graphical macros to speed graphical development for operators.

AMS software provides maintenance www.cniacs.com personnel with advanced predictive and performance diagnostic tools, enabling them to identify machine failures early with confidence and accuracy.

Features:

Dual-channel, 3U-sized, 1-slot plug-in module reduces cabinet space requirements by half over traditional four-channel 6U cards

API 670 and API 618 compliant hot-swappable modules

Pre- and post-buffered and proportional outputs, 0/4-20 mA outputs, 0 – 10 V outputs

Self-test features include monitoring hardware, power inputs, hardware temperature, simplification, and cable connections,

Hardware temperature, simplification and cable

Built-in software linearisation for easy post-installation adjustment of sensors

For use with displacement sensors 6422. 6423. 6424 and 6425 and driver CON xxx