HART communications
Integral or remote mounting
Global or AC or DC power supply
4 optical switch LOI user interface

Accuracy ± 0.075%
Stability ± 0.1% URL/1 year
Response time 120 ms
TUV and Exida SIL2 / SIL3 certification
10-stage signal curve characterization
Local Parameter Setting (LPS)

Lightweight, compact design allows for easy installation
Available protocols include 4-20 mA HART and 1-5 Vdc HART Low Power for application flexibility
Optional protocols include 4-20mA HART, Field Foundation Bus Protocol, Profibus PA protocol, and 1-5Vdc HART Low Power Protocol
Adjustable LCD displays process variables, range percentages, and diagnostic information

0.2% Accuracy
700 ms Response Time
External Zero Adjustment

Proven field performance and reliability
Commitment to continuous improvement
Reference accuracy of 0.075%
Rangeability of 50:1, See manual for list of ranges

BRAIN or HART communication signals
Full lattice liquid crystal display
Dual frequency excitation method
Durable and easy to operate.

One -way overvoltage characteristics are excellent
No bracket, install it directly
Used in routine, no three valve groups need
The impact of static pressure is ignored

Device dashboards provide easy interface for simplified device configuration and diagnostic troubleshooting
LOI option eliminates the need for special configuration tools (i.e. field communicator) for ease-of-use
Transmitter-sensor matching with Callendar-Van Dusen constants reduces total measurement error

Place of Origin: Japan
Brand Name: Yokogawa
Model Number: AXF050
Quality: Original
Guarantee: 1 year

0.055% Accuracy (0.04% Accuracy optional)
0.1% Stability per 10 years
90 ms Response Time
Exida and TUV SIL 2 / SIL3 Certified
MWP 2,300 psi (MWP 3,600 psi option)
Local Parameter Setting (LPS)

Accuracy: 0.36°F (0.20°C) or 0.1% of span
HART/4-20 mA Communication Protocol
Less than 0.5 seconds update time
DIN B style head mount or rail mount

Welded, sealed coil housing
39.37 ft/s (12 m/s) upper range limit
Pulsed DC coil drive power
Standard process design