EMERSON FISHER FIELDVUE DLC3100 SIS User Manual

DLC3100 Digital Level Controller  
Instruction Manual  
D104213X012  
July 2019  
FisherFIELDVUEDLC3100 and DLC3100 SIS  
Digital Level Controllers  
Figure 1. Fisher DLC3100 Digital Level Controller  
This manual applies to:  
Device Type  
130D  
Device Revision  
Hardware Revision  
Firmware Revision  
DD Revision  
1
1
1.0.9  
1
Contents  
Scope of Manual . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3  
Installation , Mounting and Electrical Connections,  
and Initial Configuration and Calibration using  
X1456  
the Local User Interface . . . . . . . . . . . . . . . . . . . . 3  
Conventions Used . . . . . . . . . . . . . . . . . . . . . . . . . . . 3  
Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3  
DLC3100 Digital Level Controller . . . . . . . . . . . 3  
249 Caged Sensors . . . . . . . . . . . . . . . . . . . . . . . 5  
249 Cageless Sensors . . . . . . . . . . . . . . . . . . . . . 5  
Related Documents . . . . . . . . . . . . . . . . . . . . . . . . . . 5  
Educational Services . . . . . . . . . . . . . . . . . . . . . . . . . 8  
Section 2 Electrical Connections . . . . . . . . . . . . . . . . 13  
Test Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . 13  
Alarm Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . 13  
Loop Test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14  
Section 3 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . 15  
Status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15  
Primary Purpose Variables . . . . . . . . . . . . . . . . . . . . 15  
Device Information . . . . . . . . . . . . . . . . . . . . . . . . . 15  
AMS Device Manager or a Field Communicator . . . 17  
Configuration Advice . . . . . . . . . . . . . . . . . . . . . . . . 20  
Force Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20  
Write Protection . . . . . . . . . . . . . . . . . . . . . . . . 20  
Level Offset . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20  
Initial Setup . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21  
Device Setup . . . . . . . . . . . . . . . . . . . . . . . . . . . 21  
PV Setup . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23  
Process Setup . . . . . . . . . . . . . . . . . . . . . . . . . . 23  
Manual Setup . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24  
General . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25  
Device . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25  
Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26  
Process . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26  
HART . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27  
Safety Recovery . . . . . . . . . . . . . . . . . . . . . . . . . 27  
Alert Setup . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28  
Primary Variable . . . . . . . . . . . . . . . . . . . . . . . . 28  
Rate Limit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29  
Temperature . . . . . . . . . . . . . . . . . . . . . . . . . . . 29  
Operational . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30  
Informational . . . . . . . . . . . . . . . . . . . . . . . . . . 30  
Input Compensation . . . . . . . . . . . . . . . . . . . . . 30  
Hardware . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31  
Program and Memory . . . . . . . . . . . . . . . . . . . 31  
Alert Record . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31  
Calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32  
Two Points Calibration . . . . . . . . . . . . . . . . . . . 32  
Min/Max Calibration . . . . . . . . . . . . . . . . . . . . . 33  
Weight Calibration . . . . . . . . . . . . . . . . . . . . . . 34  
DLC3100 Digital Level Controller  
Instruction Manual  
D104213X012  
July 2019  
Section 1  
Introduction and Specifications  
Scope of Manual  
This instruction manual is a supplement to the DLC3100 and DLC3100 SIS Quick Start Guide (D104214X012) that  
ships with every digital level controller. This instruction manual includes specifications, operating, and maintenance  
information for FIELDVUE DLC3100 and DLC3100 SIS digital level controllers.  
Notes  
The DLC3100 SIS is identified by a label affixed to the terminal box cover.  
Unless otherwise noted, the information in this document applies to both DLC3100 and DLC3100 SIS. However, for simplicity, the  
DLC3100 model name will be used throughout.  
This instruction manual supports the 475 Field Communicator with device description revision 1, used with DLC3100  
instruments with firmware revision 1.0.9. You can obtain information about the process, instrument, or sensor using  
the Field Communicator. Contact your Emerson sales office to obtain the appropriate software.  
Do not install, operate, or maintain a DLC3100 digital level controller without being fully trained and qualified in valve,  
actuator, and accessory installation, operation, and maintenance. To avoid personal injury or property damage, it is  
important to carefully read, understand, and follow all the contents of this manual, including all safety cautions and  
warnings. If you have any questions regarding these instructions, contact your Emerson sales office before proceeding.  
Installation, Mounting and Electrical Connections, and Initial  
Configuration and Calibration using the Local User Interface  
Refer to the DLC3100 and DLC3100 SIS Quick Start Guide (D104214X012) for installation and connection information,  
as well as initial configuration and calibration using the local user interface. If a copy of this quick start guide is needed  
contact your Emerson sales office or visit Fisher.com.  
Conventions Used  
This manual describes using the Field Communicator to configure and calibrate the digital level controller.  
Procedures that require the use of the Field Communicator have the text path and the sequence of numeric keys  
required to display the desired Field Communicator menu.  
Description  
DLC3100 Digital Level Controller  
between two liquids, or liquid density. Changes in level or density exert a buoyant force on a displacer, which rotates  
electrical signal and digitized. The digital signal is compensated and processed per user configuration requirements,  
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DLC3100 Digital Level Controller  
July 2019  
Instruction Manual  
D104213X012  
Figure 2. Fisher DLC3100 Digital Level Controller  
Figure 3. Fisher 249 Torque Tube Rotation  
TORQUE  
TUBE  
DISPLACER  
X1461  
X1501  
Figure 4. Mechanical Architecture  
Main Electronic Compartment - Ex 'd' IP66 Enclosure  
Terminal  
Magnetic  
LCD (with reed  
Push Buttons  
(with magnets)  
Compartment  
switches)  
(with cover)  
Electrical  
Electrical  
Mechanical  
Magnetic  
Electrical  
Main PCB  
249 Torque Tube  
Lever Assembly  
Hall Sensor  
Mechanical  
Lock Mechanism  
(with magnets)  
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DLC3100 Digital Level Controller  
Instruction Manual  
D104213X012  
July 2019  
Several operations with the DLC3100 can be performed using the Field Communicator. The digital level controller can  
be configured, calibrated, or tested. Using the HART protocol, information from the field can be integrated into  
control systems or be received on a single loop basis.  
DLC3100 digital level controllers are designed to directly replace standard pneumatic and electro-pneumatic level  
transmitters. DLC3100 digital level controllers mount on a wide variety of caged and cageless 249 level sensors. They  
can also be mounted on other manufacturers’ displacer type level sensors with designed mounting kits.  
CAUTION  
There are many magnets used in the DLC3100 (lever assembly, push button, coupling handle). Care must be taken to avoid  
having a high powered magnet in close proximity. This could cause permanent damage to the DLC3100. Potential sources  
of damaging equipment include, but are not limited to: transformers, DC motors, stacking magnet assemblies.  
General Guidelines for use of High Power Magnets:  
Use of high power magnets in close proximity to any instrument which is operating a process should be avoided.  
Regardless of the instrument model, high power magnets can affect its functionality.  
249 Caged Sensors  
249, 249B, 249BF, 249C, 249K and 249L sensors side-mount on the vessel with the displacer mounted inside a cage  
outside the vessel.  
249 Cageless Sensors  
249BP, 249CP and 249P sensors top-mount on the vessel with the displacer hanging down into the vessel.  
249VS sensor side-mounts on the vessel with the displacer hanging out into the vessel.  
249W wafer-style sensor mounts on top of a vessel or on a customer-supplied cages.  
Related Documents  
Other documents containing information related to the DLC3100 digital level controllers and 249 sensors include:  
DꢀFIELDVUE DLC3100 and DLC3100 SIS Quick Start Guide (D104214X012)  
DꢀATEX and IECEx Hazardous Area Approvals - DLC3100 Digital Level Controller (D104233X012)  
DꢀFisher 249 Caged Displacer Sensors Instruction Manual (D200099X012)  
DꢀFisher 249 Cageless Displacer Sensors Instruction Manual (D200100X012)  
DꢀFisher 249VS Cageless Displacer Sensor Instruction Manual (D103288X012)  
DꢀFisher 249W Cageless Wafer Style Level Sensor Instruction Manual (D102803X012)  
DꢀSimulation of Process Conditions for Calibration of Fisher Level Controllers and Transmitters (D103066X012)  
DꢀBolt Torque Information (D103220X012)  
DꢀBulletin 11.2:DLC3100 - FIELDVUE DLC3100 and DLC3100 SIS Digital Level Controllers (D104216X012)  
DꢀBulletin 34.2:249 - Fisher 249 Sensor, Level Controller, and Transmitter Dimensions (D200039X012)  
These documents are available from your Emerson sales office or at Fisher.com.  
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DLC3100 Digital Level Controller  
July 2019  
Instruction Manual  
D104213X012  
Table 1. Fisher DLC3100 Specifications  
Available Configurations  
Transient Voltage Protection  
Pulse Waveform  
Max V @ I  
Mounts on caged and cageless 249 sensors  
Function: Transmitter  
I
CL  
pp  
pp  
(Clamping  
(Peak Pulse  
Current) (A)  
Rise Time  
Decay  
Voltage) (V)  
(ms)  
to 50% (ms)  
10  
1000  
48.4  
12.4  
Communications Protocol: HART  
Electrical Classification  
Input Signal  
Overvoltage Category II per IEC 61010 clause 5.4.2d  
Pollution Degree 4  
Level, Interface, or Density : Rotary motion of  
torque tube shaft proportional to changes in liquid  
level, interface level, or density that change the  
buoyancy of a displacer.  
Altitude Rating  
Up to 2000 meters (6562 feet)  
Process Temperature: Interface for 2- or 3-wire  
100 ohm platinum RTD for sensing process  
temperature, or optional user-entered target  
temperature to permit compensating for changes in  
specific density.  
Ambient Temperature  
The combined temperature effect on zero and span  
without the 249 sensor is less than 0.02% of full scale  
per degree Celsius over the operating range -40 to  
80_C (-40 to 176_F)  
LCD operating temperature limits: -20 to 70_C  
(-4 to 158_F)  
Output Signal  
Analog: 4 to 20 mA DC  
J Direct action—increasing level, interface, or density  
increases output; or  
J Reverse action—increasing level, interface, or  
density decreases output  
Process Temperature  
The process density and torque rate are affected by  
compensation can be implemented to correct for  
process density changes.  
High saturation: 20.5 mA  
Low saturation: 3.8 mA  
Process Density  
High alarm : > 21.0 mA  
The sensitivity to error in knowledge of process  
density is proportional to the differential density of  
the calibration. If the differential specific gravity is  
0.2, and error of 0.02 specific gravity units in  
knowledge of a process fluid density represents 10%  
of span.  
Low Alarm : < 3.6 mA  
Digital: HART 1200 Baud Frequency Shift Keyed (FSK)  
HART impedance requirements must be met to  
enable communication. Total shunt impedance  
across the master device connections (excluding the  
master and transmitter impedance) must be between  
230 and 600 ohms.  
Hazardous Area  
CSA  
The transmitter HART receive impedance is defined  
Class/Division: Intrinsically Safe, Explosion-proof  
,
as:  
Division 2, Dust Ignition-proof  
Rx: 30.2 k ohms and  
Cx: 5.45 nF  
Zone: Intrinsically Safe, Flameproof, Type n, Dust by  
intrinsic safety and Enclosure  
ATEX/IECEx—Flameproof, Intrinsic Safety, Dust by  
Intrinsic Safety  
Supply Requirements  
Electrical Housing  
12 to 30 volts DC; 25 mA  
Instrument has reverse polarity protection.  
IP66, Type 4X  
A minimum compliance voltage of 17.75 VDC (due to  
HART impedance requirement) is required to  
guarantee HART communication.  
Electrical Connections: Two 1/2-14 NPT internal  
conduit connections. Both are at the bottom of  
terminal box.  
-continued-  
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DLC3100 Digital Level Controller  
Instruction Manual  
D104213X012  
July 2019  
Electromagnetic Compatibility  
Minimum Differential Specific Gravity  
DLC3100 meets EN61326-1:2013  
0.05 SGU  
DLC3100 SIS meets EN61326-3-2:2008  
Construction Material  
DLC3100 SIS  
Safety Instrumented System Classification  
Housing and Cover: Low-copper aluminum die  
casting alloy  
Internal: Aluminum, and stainless steel; encapsulated  
printed circuit board  
SIL2 capable - certified by exida Consulting LLC  
Lever assembly: Plated steel, Neodymium iron boron  
magnets  
Hall Guard: Thermoplastic elastomer  
Performance  
w/ NPS 3  
DLC3100  
Performance  
Criteria  
249W, Using w/ All Other  
Digital Level  
a 14‐inch  
Displacer  
249 Sensors  
Controller  
Independent  
Linearity  
$0.25% of  
$0.8% of  
$0.5% of  
Weight  
output span  
output span  
output span  
<0.2% of  
Hysteresis  
Repeatability  
Dead Band  
- - -  
- - -  
Less than 3.45 kg (7.57 lb)  
output span  
$0.1% of full  
$0.5% of  
$0.3% of  
scale output  
output span  
output span  
<0.05% of  
input span  
- - -  
- - -  
Options  
Hysteresis plus  
Deadband  
<1.0% of  
<1.0% of  
- - -  
J Sunshade J Mountings for Masoneilan, Yamatake,  
Foxboro-Eckhardt sensors J Factory Calibration:  
available for instruments factory-mounted on 249  
sensor, when application, process temperature and  
density are supplied  
output span  
output span  
NOTE: At full design span, reference conditions.  
1. To lever assembly rotation inputs.  
At effective proportional band (PB)<100%, linearity,  
dead band, and repeatability are derated by the factor  
(100%/PB)  
1. Density application is not available in DLC3100 SIS.  
2. Only one of the High/Low alarm definition is available in a given configuration. Both alarms are NAMUR NE43 compliant.  
3. Outside of this limit, LCD will not be readable but it will not affect the functionality of DLC3100 if the temperature is still within the normal limits. Push buttons will be disabled when instrument  
temperature is below -20°C (-4°F) or above 70°C (158°F) where LCD display might be intermittent.  
4. Not for use in Ester and Ketone atmospheres.  
Table 2. DLC3100 EMC Summary Results—Immunity per EN61326-1  
Port  
Phenomenon  
Basic Standard  
Test Level  
Test Results  
Electrostatic  
4 kV contact  
8 kV air  
IEC 61000-4-2  
A
discharge (ESD)  
80 to 1000 MHz @ 10V/m with 1 kHz AM at 80%  
1400 to 2000 MHz @ 3V/m with 1 kHz AM at 80%  
2000 to 2700 MHz @ 1V/m with 1 kHz AM at 80%  
Radiated EM field  
IEC 61000-4-3  
IEC 61000-4-8  
A
A
Enclosure  
Radiated power  
frequency magnetic  
field  
30 A/m at 50 and 60 Hz  
Burst  
Surge  
IEC 61000-4-4  
IEC 61000-4-5  
IEC 61000-4-6  
IEC 61000-4-4  
IEC 61000-4-5  
IEC 61000-4-6  
1 kV  
A
B
A
A
B
A
1kV (line to ground only, each)  
150 kHz to 80 MHz at 3 Vrms  
2 kV  
I/O signal/control  
Protective earth  
Conducted RF  
Burst  
Surge  
2 kV (line to ground only)  
150 kHz to 80 MHz at 3 Vrms  
Conducted RF  
1. A = No degradation during testing. B = Temporary degradation during testing, but is selfrecovering. Specification limit = +/- 1% of span.  
2. HART communication was considered as “not relevant to the process” and is used primarily for configuration, calibration, and diagnostic purposes.  
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DLC3100 Digital Level Controller  
July 2019  
Instruction Manual  
D104213X012  
Table 3. DLC3100 SIS EMC Summary Results—Immunity per EN61326-3-2  
Port  
Phenomenon  
Basic Standard  
Test Level  
Test Results  
Electrostatic  
6 kV contact  
8 kV air  
IEC 61000-4-2  
A
discharge (ESD)  
80 to 1000 MHz @ 10V/m with 1 kHz AM at 80%  
1400 to 2000 MHz @ 10V/m with 1 kHz AM at 80%  
2000 to 2700 MHz @ 3V/m with 1 kHz AM at 80%  
Radiated EM field  
IEC 61000-4-3  
IEC 61000-4-8  
A
A
Enclosure  
Radiated power  
frequency magnetic  
field  
100 A/m at 50 and 60 Hz  
Burst  
Surge  
IEC 61000-4-4  
IEC 61000-4-5  
IEC 61000-4-6  
IEC 61000-4-4  
IEC 61000-4-5  
IEC 61000-4-6  
1 kV  
A
FS  
A
1 kV (line to ground only, each)  
10 kHz to 80 MHz at 10 Vrms  
2 kV  
I/O signal/control  
Protective earth  
Conducted RF  
Burst  
A
Surge  
1 kV (line to ground only)  
10 kHz to 80 MHz at 10 Vrms  
A
Conducted RF  
A
1. A = No degradation during testing. B = Temporary degradation during testing, but is selfrecovering. FS = Fail Safe. Specification limit = +/- 2% of span.  
2. HART communication was considered as “not relevant to the process” and is used primarily for configuration, calibration, and diagnostic purposes.  
Figure 5. Guidelines for Use of Optional Heat Insulator Assembly  
AMBIENT TEMPERATURE (_C)  
0
10  
20 30 40 50 60 70 80  
-40 -30 -20 -10  
800  
425  
400  
TOO  
HOT  
HEAT INSULATOR  
REQUIRED  
300  
200  
100  
400  
0
NO HEAT INSULATOR NECESSARY  
0
-100  
1
TOO  
COLD  
HEAT INSULATOR  
REQUIRED  
-200  
-325  
-40  
-20  
0
20  
40  
60  
80 100 120 140 160 176  
AMBIENT TEMPERATURE (_F)  
STANDARD TRANSMITTER  
NOTES:  
ꢀ1ꢁꢀFOR PROCESS TEMPERATURES BELOW -29_C (-20_F) AND ABOVE 204_C (400_F)  
2. IF AMBIENT DEW POINT IS ABOVE PROCESS TEMPERATURE, ICE FORMATION MIGHT  
CAUSE INSTRUMENT MALFUNCTION AND REDUCE INSULATOR EFFECTIVENESS.  
39A4070‐B  
A5494‐1  
Educational Services  
For information on available courses contact:  
Emerson Automation Solutions  
Educational Services, Registration  
Phone: +1-641-754-3771 or +1-800-338-8158  
e‐mail: [email protected]  
emerson.com/fishervalvetraining  
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DLC3100 Digital Level Controller  
Instruction Manual  
D104213X012  
July 2019  
Figure 6. Theoretical Reversible Temperature Effect on Common Torque Tube Materials  
TORQUE RATE REDUCTION  
(NORMALIZED MODULUS OF RIGIDITY)  
1.00  
0.98  
1
0.96  
0.94  
0.92  
N05500  
N06600  
0.90  
N10276  
0.88  
0.86  
0.84  
0.82  
0.80  
S31600  
20 40 60 80 100 120 140 160 180 200 220 240 260 280 300 320 340 360 380 400 420  
TEMPERATURE (_C)  
TORQUE RATE REDUCTION  
(NORMALIZED MODULUS OF RIGIDITY)  
1.00  
0.98  
1
0.96  
0.94  
0.92  
N05500  
N06600  
0.90  
N10276  
0.88  
0.86  
0.84  
0.82  
0.80  
S31600  
50 100 150 200 250 300 350 400 450 500 550 600 650 700 750 800  
TEMPERATURE (_F)  
NOTE:  
ꢀ1ꢀꢁDUE TO THE PERMANENT DRIFT THAT OCCURS NEAR AND ABOVE 260_C (500_F), N05500 IS NOT  
RECOMMENDED FOR TEMPERATURES ABOVE 232_C (450_F).  
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DLC3100 Digital Level Controller  
July 2019  
Instruction Manual  
D104213X012  
Table 4. Fisher 249 Sensor Specifications  
Input Signal  
equalizing connection styles are numbered and are  
Liquid Level or Liquid‐to‐Liquid Interface Level:  
From 0 to 100 percent of displacer length  
Liquid Density: From 0 to 100 percent of  
displacement force change obtained with given  
displacer volume—standard volumes are  
Mounting Positions  
Most level sensors with cage displacers have a  
rotatable head. The head may be rotated through  
360 degrees to any of eight different positions.  
3
3
J980 cm (60 inches ) for 249C and 249CP sensors  
3
3
or J1640 cm (100 inches ) for most other sensors;  
other volumes available depending upon sensor  
construction  
Construction Materials  
Sensor Displacer Lengths  
Operative Ambient Temperature  
Sensor Working Pressures  
For ambient temperature ranges, guidelines, and use  
Consistent with applicable ANSI  
pressure/temperature ratings for the specific sensor  
Options  
J Heat insulator J Gauge glass for pressures to  
29 bar at 232_C (420 psig at 450_F), and J Reflex  
gauges for high temperature and pressure  
applications  
Caged Sensor Connection Styles  
Cages can be furnished in a variety of end connection  
styles to facilitate mounting on vessels; the  
Table 5. Allowable Process Temperatures for  
Table 6. Displacer and Torque Tube Materials  
Common 249 Sensor Pressure Boundary Materials  
Part  
Standard Material  
Other Materials  
316 Stainless Steel,  
N10276, N04400,  
Plastic, and Special  
Alloys  
PROCESS TEMPERATURE  
MATERIAL  
Min.  
Max.  
Displacer  
304 Stainless Steel  
Cast Iron  
Steel  
-29_C (-20_F)  
-29_C (-20_F)  
-198_C (-325_F)  
-198_C (-325_F)  
232_C (450_F)  
427_C (800_F)  
427_C (800_F)  
427_C (800_F)  
Displacer Stem  
Driver Bearing,  
Displacer Rod and  
Driver  
N10276, N04400,  
other Austenitic  
Stainless Steels, and  
Special Alloys  
Stainless Steel  
N04400  
316 Stainless Steel  
Graphite  
316 Stainless Steel,  
N06600, N10276  
-198_C (-325_F)  
427_C (800_F)  
Laminate/SST  
Gaskets  
(1)  
Torque Tube  
N05500  
N04400/PTFE  
Gaskets  
1. N05500 is not recommended for spring applications above 232_C  
(450_F). Contact your Emerson sales office or application engineer if  
temperatures exceeding this limit are required.  
-73_C (-100_F)  
204_C (400_F)  
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DLC3100 Digital Level Controller  
Instruction Manual  
D104213X012  
July 2019  
(1)  
Table 7. Caged Displacer Sensors  
STANDARD CAGE, HEAD,  
AND TORQUE TUBE ARM  
MATERIAL  
EQUALIZING CONNECTION  
Style  
TORQUE TUBE  
SENSOR  
(2)  
PRESSURE RATING  
ORIENTATION  
Size (NPS)  
Screwed  
Flanged  
1‐1/2 or 2  
2
(3)  
249  
Cast iron  
CL125 or CL250  
CL600  
Screwed or optional socket weld  
1‐1/2 or 2  
CL150, CL300, or  
CL600  
1‐1/2  
(4)  
249B, 249BF  
Steel  
Raised face or optional ring‐type joint  
flanged  
CL150, CL300, or  
CL600  
Torque tube  
arm rotatable  
with respect to  
equalizing  
2
Screwed  
1‐1/2 or 2  
1‐1/2  
CL600  
CL150, CL300, or  
CL600  
connections  
(3)  
249C  
316 stainless steel  
Raised face flanged  
CL150, CL300, or  
CL600  
2
Raised face or optional ring‐type joint  
flanged  
249K  
249L  
Steel  
Steel  
1‐1/2 or 2  
CL900 or CL1500  
CL2500  
(5)  
2
Ring‐type joint flanged  
1. Standard displacer lengths for all styles (except 249) are 14, 32, 48, 60, 72, 84, 96, 108 and 120 inches. The 249 uses a displacer with a length of either 14 or 32 inches.  
2. EN flange connections available in EMA (Europe, Middle East and Africa).  
3. Not available in EMA.  
4. The 249BF available in EMA only. Also available in EN size DN 40 with PN 10 to PN 100 flanges and size DN 50 with PN 10 to PN 63 flanges.  
5. Top connection is NPS 1 ring‐type joint flanged for connection styles F1 and F2.  
(1)  
Table 8. Cageless Displacer Sensors  
(2),  
Standard Head Wafer  
Body and Torque Tube  
Arm Material  
(3)  
(6)  
Mounting  
Sensor  
Flange Connection (Size)  
Pressure Rating  
NPS 4 raised face or optional ring‐type joint  
NPS 6 or 8 raised face  
CL150, CL300, or CL600  
CL150 or CL300  
(4)  
249BP  
Steel  
249CP  
316 Stainless Steel  
NPS 3 raised face  
CL150, CL300, or CL600  
Mounts on  
CL900 or 1CL500  
(EN PN 10 to DIN PN 250)  
top of vessel  
NPS 4 raised face or optional ring‐type joint  
NPS 6 or 8 raised face  
(5)  
249P  
Steel or stainless steel  
CL150, CL300, CL600, CL900,  
CL1500, or CL2500  
CL125, CL150, CL250, CL300,  
CL600, CL900, or CL1500  
(EN PN 10 to DIN PN 160)  
WCC (steel) LCC (steel), or  
CF8M (316 stainless steel)  
For NPS 4 raised face or flat face  
Mounts on  
249VS  
249W  
side of vessel  
WCC, LCC, or CF8M  
WCC or CF8M  
For NPS 4 buttweld end, XXZ  
For NPS 3 raised face  
CL2500  
Mounts on top of  
vessel or on  
customer  
CL150, CL300, or CL600  
LCC or CF8M  
For NPS 4 raised face  
CL150, CL300, or CL600  
supplied cage  
1. Standard displacer lengths are 14, 32, 48, 60, 72, 84, 96, 108, and 120 inches.  
2. Not used with side‐mounted sensors.  
3. EN flange connections available in EMA (Europe, Middle East and Africa).  
4. Not available in EMA.  
5. 249P available in EMA only.  
6. Wafer Body only applicable to the 249W.  
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Figure 7. Style Number of Equalizing Connections  
STYLE 1  
STYLE 2  
STYLE 3  
STYLE 4  
TOP & LOWER SIDE  
CONNECTIONS  
UPPER & LOWER SIDE  
CONNECTIONS  
UPPER SIDE & BOTTOM  
CONNECTIONS  
TOP & BOTTOM  
CONNECTIONS  
SCREWED (S-2) OR  
FLANGED (F-2)  
SCREWED (S-3) OR  
FLANGED (F-3)  
SCREWED (S-4) OR  
FLANGED (F-4)  
SCREWED (S-1) OR  
FLANGED (F-1)  
E1697  
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Section 2  
Electrical Connections  
Note  
This information supplements the Electrical Connections section in the quick start guide (D104214X012) that shipped with your  
instrument. If a copy of this quick start guide is needed contact your Emerson sales office or visit Fisher.com.  
Test Connections  
WARNING  
Personal injury or property damage caused by fire or explosion may occur if this connection is attempted in an area which  
contains a potentially explosive atmosphere or has been classified as hazardous. Confirm that area classification and  
atmosphere conditions permit the safe removal of the terminal box cap before proceeding.  
Test connections inside the terminal box can be used to measure loop current across an internal 1 ohm resistor.  
1. Remove the terminal box cap.  
2. Adjust the test meter to measure mV.  
3. Connect the positive lead of the test meter to the + connection and the negative lead to the TEST connection inside  
the terminal box.  
4. Measure Loop current as mV = mA. For example, if the meter measures 12.5 mV, it means the loop current is  
12.5 mA.  
5. Remove test leads and replace the terminal box cover.  
Alarm Conditions  
Each digital level controller continuously monitors its own performance during normal operation. This automatic  
diagnostic routine is a timed series of checks repeated continuously. If diagnostics detect a failure in the electronics,  
the instrument drives its output to trip alarm current either below 3.6 mA or above 21 mA, depending on the position  
(High/Low) of the alarm switch.  
An alarm condition occurs when the self-diagnostics detect an error that would render the process variable  
measurement inaccurate, incorrect, or undefined, or a user defined threshold is violated. At this point the analog  
output of the unit is driven to a defined level either above or below the nominal 4-20 mA range, based on the position  
of the alarm switch. The factory default Alarm Switch setting is High.  
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Table 9. Trip Alarm Current Default Setting  
Alerts  
Trip Alarm Current Default Setting  
Device Malfunction  
Enable  
Enable  
Enable  
Enable  
Enable  
Enable  
Enable  
Enable  
Enable  
Enable  
Enable  
Enable  
Disable  
Disable  
Reference Voltage Failed  
PV Analog Output Readback Limit Failed  
Instrument Temperature Sensor Alert  
Hall Sensor Alert  
RTD Sensor Alert  
Hall Diagnostic Failed  
RTD Diagnostic Failed  
Program Memory Failed  
NVM Error  
RAM Test Error Alert  
Watchdog Reset Executed  
PV HiHi Alert  
PV LoLo Alert  
Loop Test  
Note  
The DLC3100 must be put out of service during Loop Test. Place the loop into manual operation before putting device out of  
service as the DLC3100 output may not be valid.  
When the DLC3100 is out of service, it is locked for exclusive access by the Primary/Secondary master that put it out of service. If  
the instrument reports Locked by HART or Access Restricted when you attempt to configure it, and a master of the original  
priority is not available, use Force Mode on the Local User Interface menu to force the instrument mode to In Service. You will  
then be able to take it out of service with your own master to make changes.  
Loop Test can be used to verify the controller output, the integrity of the loop, and the operations of any recorders or  
similar devices installed in the loop. To initiate a loop test, perform the following procedure:  
1. Connect a reference meter to the controller. To do so, either connect the meter to the test connections inside the  
2. Access Loop Test via Service Tools > Maintenance > Tests > Loop Test (3-4-2-2).  
3. Select OK after you set the control loop to manual. The Field Communicator displays the loop test menu.  
4. Put the instrument to “Not in Service” and select analog output level: 4mA, 20mA or Other to manually input a  
value between 4 and 20 milliamps.  
5. Check the reference meter to verify that it reads the value that is commanded. If the readings do not match, either  
the controller requires an output trim, or the meter is malfunctioning.  
After completing the test procedure, the display returns to the loop test screen and allows you to choose another  
output value or end the test and put instrument back in service.  
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Section 3  
Overview  
Overview provides information about the current state of the instrument, measurement data, and device variables  
that are of interest.  
Status  
Name  
Status  
Description  
Good  
There are no active alerts and instrument is In Service.  
The highest severity active alert is in the Failure category.  
Failure  
Device  
The highest severity active alert is in the Maintenance  
category.  
Maintenance  
Advisory  
The highest severity active alert is in the Advisory category.  
Communication with digital level controller is established.  
Digital level controller is in alert simulation mode.  
Polled  
Communications  
Mode  
Simulation Active  
In Service  
Digital level controller is online and performing its function.  
Digital level controller is Out of Service. Output may not be  
valid.  
Not In Service  
Primary Purpose Variables  
Name  
Description  
Process Fluid  
Name of the process fluid.  
Process Fluid Compensated Density of the process fluid. If temperature compensation is enabled, the density  
Density  
value is after compensation.  
PV  
Actual measurement in percentage of span.  
Actual measurement in unit.  
PV Value  
Process Temperature  
Analog Output  
Actual temperature of the process (via RTD or manual input).  
Current output of the digital level controller, in milliamps.  
Device Information  
Identification  
Name  
Description  
A unique name to identify the HART device, up to 8 characters.  
A unique name to identify the HART device, up to 32 characters.  
Field device model: DLC3100  
Tag  
Long Tag  
Model  
Device ID  
The ID of the printed wiring board in the instrument.  
Serial number printed on the nameplate of the device.  
Serial number printed on the nameplate of the 249 sensor.  
Unique code in device for traceability.  
Instrument Serial Number  
Sensor Serial Number  
Instrument Assembly Code  
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Revisions  
Name  
Description  
HART Universal Revision  
Device Revision  
Hardware  
The revision number of the HART Universal Commands used by the instrument.  
The revision number of the instrument-to-HART communicator interface software.  
The revision number of the instrument hardware.  
Firmware  
The revision number of the instrument firmware.  
Alarm Type and Security  
Name  
Value  
High  
Description  
Analog output will be >= 21mA when Trip Alarm Current is activated.  
Analog output will be <= 3.6mA when Trip Alarm Current is activated.  
Alarm Switch  
Low  
When protection is enabled, writing to parameters and calibration are  
not allowed.  
Enable  
Disable  
Protection  
When protection is disabled, device can be configured and calibrated.  
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Section 4  
Configuration and Calibration using AMS Device Manager or a  
Field Communicator  
Note  
Refer to the DLC3100 and DLC3100 SIS Quick Start Guide (D104214X012) for configuration and calibration using the local user  
interface. If a copy of this quick start guide is needed contact your Emerson sales office or visit Fisher.com.  
DLC3100 has to be set to “Not In Service” during configuration and calibration which include:  
DꢀDevice Setup  
DꢀPV Setup  
DꢀProcess Setup  
DꢀCalibration  
DꢀManual Setup  
DꢀAlert Setup  
The DLC3100 will continue to regulate the current output based on lever assembly position. The output can be at  
failed current value (determine by alarm switch on the Main Electronics Board) depending on the device alerts/status.  
This current output shall not be treated as actual level/interface measurement as the device is “Not In Service”.  
CAUTION  
The control loop must be in manual before putting DLC3100 to Not In Service.  
Note  
When configuring the DLC3100 using the DD, the access of DLC3100 via Local User Interface will be locked.  
If a DLC3100 digital level controller ships from factory mounted on a 249 sensor, initial setup and calibration may not  
be necessary. The factory enters the sensor data, couples the instrument to the sensor, and calibrates the instrument  
and sensor combination.  
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Note  
If the digital level controller mounted on the sensor is received with the displacer blocked, or if the displacer is not connected, the  
instrument will be coupled to the torque tube assembly and the lever assembly unlocked. To place the unit in service, if the  
displacer is blocked, remove the rod and block at each end of the displacer and check the instrument calibration. (If the “factory  
cal” option was ordered, the instrument will be pre-compensated to the process conditions provided on the requisition, and may  
not appear to be calibrated if checked against room temperature with 0% and 100% water level inputs). If the displacer is not  
connected, hang the displacer on the torque tube.  
If the digital level controller mounted on the torque tube arm and the displacer is not blocked when received (such as in skid  
mounted systems), the instrument will not be coupled to the torque tube assembly, and the lever assembly will be locked. To  
place the unit in service, couple the instrument to the sensor and unlock the lever assembly.  
When the 249 assembly is properly connected and coupled to the digital level controller, establish the zero process condition and  
perform the Trim Zero procedure. The torque tube rate should not need to be recalibrated.  
To review the configuration data entered by the factory, connect the instrument to a 24 VDC power supply as shown in  
review the data under Manual Setup and Alert Setup. If application data has been changed since the instrument was  
factory-configured, refer to the Manual Setup section for instructions on modifying configuration data.  
Figure 8. Connecting to a Power Supply  
230  
W
3
R
3
6
0
0
W
L
+
+
Reference meter  
for calibration  
or monitoring  
operation. May  
be a voltmeter  
across 250 ohm  
resistor or a  
+
POWER  
SUPPLY  
current meter.  
+
Signal loop may be grounded at  
any point or left ungrounded.  
Field Communicator may be  
connected at any termination  
point in the signal loop other  
than across the power supply.  
Signal loop must have between  
230 and 600 ohms load for  
communication.  
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For instruments not mounted on a level sensor or when replacing an instrument, initial setup consists of entering  
sensor information.  
Sensor information includes displacer and torque tube information, such as:  
DꢀDisplacer Information (Length, Volume and Weight)  
DꢀDriver Rod Length  
DꢀMounting position (Left or Right of Displacer)  
DꢀTorque Tube Material  
DꢀTorque Tube Wall  
DꢀMeasurement Application (Level, Interface or Density)  
DꢀDirect/Reverse Action  
DꢀTemperature Compensation (Enable/Disable)  
DꢀProcess Fluid Density  
nameplate. The moment arm is the effective length of the driver rod length, and depends upon the sensor type. For a  
Table 10. Setup Information  
Description  
Value  
Units Available in LUI  
Displacer Length  
mm, cm, m, in, ft  
3
3
3
Displacer Volume  
mm , cm , L, in  
G, kg, oz, lb  
Displacer Weight  
Driver Rod (Moment Arm) Length  
Mounting  
mm, cm, m, in, ft  
Right of displacer, Left of displacer  
249 Cast, 249A, 249B/249BF, 249BP, 249C, 249CP, 249K, 249L, 249N,  
249P (CL150-600), 249P (CL900-2500), 249PT, 249V, 249VS, 249VT  
(TeeMount), 249VT (SideMount), 249W, 259, Other, Masoneilan,  
Foxboro-Eckardt, Yamatake Honeywell, Unknown  
249 Sensor  
K-Monel, Inconel, 316SST, Hasteloy C, DuraNickel, Monel, Alloy 20,  
Incoloy, Hasteloy B2, 304SST, 304L SST, 316L SST, 321SST, 347SST,  
Custom  
Torque Tube Material  
Torque Tube Wall  
Thin, Standard, Heavy, Unknown  
Level, Interface, Density  
Direct, Reverse  
Measurement Application  
Analog Output Action  
3
3
3
3
SGU, g/cm , g/mL, g/L, kg/m , lb/in , lb/ft , lb/gal,  
Fluid Density  
Degrees Baume – Heavy, Degrees Baume – Light, Degrees API  
2. When setting up the density in Degrees Baume, note of the range supported:  
Degrees Baume Heavy - 0 degree to 37.6 degree  
Degrees Baume Light - 10 degree to 100 degree  
Degrees API - 0 degree to 100 degree  
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Configuration Advice  
Force Mode  
Local User Interface Menu > Force Mode  
When the DLC3100 is out of service, it is locked for exclusive access by the Primary/Secondary master that put it out of  
service. The same master must be used to put the instrument back in service; another master will not be able to  
change anything on the device and the LCD will return a “Locked by HART” message, unless you run Force Mode.  
Select Force Mode to force the instrument mode to In Service if the original master is not available.  
Note  
Make sure no outstanding tasks are on-going in the device, including configuration and calibration, before forcing the DLC3100 In  
Service  
Write Protection  
To setup and calibrate the instrument, write protection must be set to disable.  
Level Offset  
Level Offset is the value DLC3100 reports when the process level is at the bottom of the displacer. Adding a level offset  
permits the process variable value in engineering units to be reported with respect to a reference point other than the  
bottom of the displacer. Examples include: bottom of the process vessel, the process set point, or sea level. Set Level  
Offset is only available in Level or Interface measurement mode. Follow the prompts on the Field Communicator to  
enter the offset value (2-3-2-1-6).  
Level Offset will affect URV/LRV, PV Hi/Lo, PV HiHi/LoLo alerts. Changing PV alert points assumes you have already  
considered the affect of Level Offset on the alert points. This parameter should be cleared to zero before running  
Device Setup.  
Figure 81. Example of the Use of Level Offset  
URV  
DISPLACER  
(10 FEET)  
LRV  
(6 FEET)  
LEVEL  
OFFSET  
(6 FEET)  
E0368  
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Initial Setup  
Initial Setup consists of the following:  
DꢀDevice Setup  
DꢀPV Setup  
DꢀProcess Setup  
All three setup procedures must be completed when configuring the DLC3100 in order for the device to function  
properly.  
Initial Setup directs you through initialization of configuration data needed for proper operation. When the instrument  
comes out of the box, the default dimensions are set for the most common Fisher 249 construction. If any data is  
unknown, it is generally safe to accept the defaults. The mounting position - left or right of displacer - is important for  
correct interpretation of positive motion. Use Manual Setup to locate and modify individual parameters when they  
need to be changed. Refer to the Initial Setup section below for DLC3100 configuration.  
Notes  
The DLC3100 has to be “Not In Service” when carrying out Initial Setup. Place the loop into manual operation before putting  
device out of service as the output will not be valid.  
When the DLC3100 is out of service, it is locked for exclusive access by the Primary/Secondary master that put it out of service. If  
the instrument reports Locked by HART or Access Restricted when you attempt to configure it, and a master of the original  
priority is not available, use Force Mode on the Local User Interface menu to force the instrument mode to In Service. You will  
then be able to take it out of service with your own master to make changes.  
Guided setup is available to aid initial setup. Follow the prompts to enter information required by the setup. Most of  
the information is available from the sensor nameplate.  
Device Setup  
AMS Configure > Guided Setup > Device Setup  
Field Communicator Configure > Guided Setup > Device Setup (2-2-1)  
Input the required information as follows:  
DꢀDisplacer Information (Length, Weight and Volume)  
DꢀMounting Position (Left or Right of Displacer)  
Dꢀ249 Sensor Model  
DꢀTorque Tube Material and wall thickness  
The Driver Rod (moment arm) is the effective length of the driver rod length, and depends upon the sensor type. For a  
Once Device Setup is completed, configure the application settings using the PV Setup procedures.  
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(1)  
Table 11. Driver Rod Length  
MOMENT ARM  
(2)  
SENSOR TYPE  
mm  
203  
203  
203  
203  
169  
169  
267  
229  
267  
Inch  
8.01  
8.01  
8.01  
8.01  
6.64  
6.64  
10.5  
9.01  
10.5  
249  
249B  
249BF  
249BP  
249C  
249CP  
249K  
249L  
249N  
249P  
(CL125-CL600)  
203  
229  
8.01  
9.01  
249P  
(CL900-CL2500)  
(1)  
249VS (Special)  
See serial card  
See serial card  
13.5  
249VS (Std)  
249W  
343  
203  
8.01  
1. Driver rod length is the perpendicular distance between the vertical centerline of the displacer and the horizontal centerline of the torque tube. See figure 9. If you cannot determine the driver  
rod length, contact your Emerson sales office and provide the serial number of the sensor.  
2.ꢀThis table applies to sensors with vertical displacers only. For sensor types not listed, or sensors with horizontal displacers, contact your Emerson sales office for the driver rod length. For other  
manufacturers' sensors, see the installation instructions for that mounting.  
Figure 9. Method of Determining Moment Arm from External Measurements  
VESSEL  
VERTICAL C OF  
L
DISPLACER  
MOMENT  
ARM LENGTH  
HORIZONTAL C OF  
L
TORQUE TUBE  
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PV Setup  
AMS Configure > Guided Setup > PV Setup  
Field Communicator Configure > Guided Setup > PV Setup (2-2-2)  
PV Setup consists of the following:  
DꢀAnalog Output Action (Direct or Reverse)  
DꢀLevel Offset  
DꢀMeasurement Range (Lower Range Value and Upper Range Value)  
Note  
For interface applications, if the 249 is not installed on a vessel, or if the cage can be isolated, calibrate the instrument with  
weights, water, or other standard test fluid, in level mode. After calibrating in level mode, the instrument can be switched to  
interface mode, then enter the actual process fluid specific gravity and range values, follow with Trim Zero.  
Table 12. Application Information  
Measurement Application  
Description  
The default process variable units are set to the same units chosen for displacer length. When level  
offset is changed, range values will be initialized based on level offset and displacer length. The default  
upper range value is set to equal to displacer length and the default lower range value is set to zero when  
the level offset is 0.  
Level, Interface  
The default process variable units are set to “SGU” (Specific Gravity Units). The default upper range value  
is set to “1.0” and the default lower range value is set to ”0.1”.  
Density  
When a DLC3100 with analog output is set for direct action the loop current will increase as the fluid level increases.  
Upper Range Value is the process variable values at 20 mA and Lower Range Value is the process variable values at  
4 mA.  
Choosing Reverse action will swap the default values of the upper and lower range values. The loop current will  
decrease as the fluid level increases. Upper Range Value is the process variable values at 4 mA and Lower Range Value  
is the process variable values at 20 mA.  
Once PV Setup is completed configure the process information using the Process Setup procedures.  
Process Setup  
AMS Configure > Guided Setup > Process Setup  
Field Communicator Configure > Guided Setup > Process Setup (2-2-3)  
Process Setup consists of the following:  
DꢀFluid Type (Water/Steam, Hydrocarbon, H SO Aqueous Solution or Custom Fluid)  
2
4
DꢀFluid Density  
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Process Temperature Input allows the DLC3100 to know the temperature in the process to carry out temperature  
compensation. Selecting Manual or RTD will enable the temperature compensation.  
Table 13. Process Temperature Input Information  
Process Temperature Input  
Temperature compensation  
None  
Disable.  
Manual  
Enable. input process temperature into DLC3100 manually.  
Enable. install RTD to the DLC3100 terminal box. DLC3100 will base on the RTD reading and derive the  
temperature of the process.  
RTD  
When Temperature Compensation is enabled (by selecting Manual or RTD in Process Temperature Input), select the  
process fluid type, and enter the temperature/density table. The DLC3100 will use the best matched compensated  
density value from the pre-loaded fluid type tables in DLC3100 for level measurement based on the actual process  
temperature. If Custom Fluid is selected, input Temperature/Density values to custom fluid table. For level  
measurement applications, only the lower fluid table is required. For interface measurement applications, both upper  
fluid and lower fluid tables are required. Neither table is used for density applications.  
Note  
A minimum of two pairs of temperature/density values must be entered to the table. The temperatures entered must be in  
ascending order.  
Manual Setup  
AMS Configure > Manual Setup  
Field Communicator Configure > Manual Setup (3)  
The DLC3100 digital level controller communicates via the HART protocol. This section describes the advanced  
features that can be accessed with the DD/Field Communicator.  
Note  
Changing setup parameters will require instrument protection to be disabled, and the instrument to be put out of service. Place  
the loop into manual operation before putting device out of service as the DLC3100 output may not be valid.  
When the DLC3100 is out of service, it is locked for exclusive access by the Primary/Secondary master that put it out of service. If  
the instrument reports Locked by HART or Access Restricted when you attempt to configure it, and a master of the original  
priority is not available, use Force Mode on the Local User Interface menu to force the instrument mode to In Service. You will  
then be able to take it out of service with your own master to make changes.  
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General  
Group  
Name  
Description  
A unique tag to identify the HART device, up to 8  
characters.  
Tag  
Date  
Calibration date entered by user.  
Device Information  
A loop descriptor with a maximum length of 16  
characters.  
Descriptor  
Message  
A message with a maximum length of 32 characters.  
Serial number on the instrument nameplate.  
Serial number on the sensor nameplate.  
Instrument Serial Number  
Sensor Serial Number  
Serial Numbers  
Dynamic date on the instrument clock for use in  
stamping logged events. The order of year, month and  
day depends on the setting of the operating system.  
Instrument Date  
Instrument Time  
Instrument Clock  
Time of day (hh:mm:ss) on instrument clock for use in  
stamping logged events.  
Device  
Group  
Name  
Description  
Application  
Measurement application: Level, Interface or Density  
Defines the operational endpoint from which the  
20 mA or 100% of the percent range are derived.  
PV Upper Range Value  
PV Lower Range Value  
Primary Value Offset  
Primary Variable  
Defines the operational endpoint from which the 4 mA  
or 0% of the percent range are derived.  
The primary variable value you want the instrument to  
report when physical level is at bottom of a displacer.  
Defines whether loop current increases/decreases  
when level changes.  
Direct – Loop current increases as the fluid level  
increases.  
Analog Output Action  
Analog Output Action  
Reverse – Loop current decreases as the fluid level  
increases.  
Indicates the maximum usable value for the Upper  
Range value.  
PV Upper Sensor Limit  
PV Lower Sensor Limit  
PV Damping  
Sensor Limits  
Damping  
Indicates the minimum usable value for the Lower  
Range value.  
Time constant of filter applied to PV signal after all  
compensation and before generating AO command.  
Time constant of filter applied to torque tube sensor  
input signal.  
Input Filter Time  
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Sensor  
Group  
Name  
Description  
Full length of the displacer.  
Displacer Length  
Displacer Volume  
Displacer Weight  
Driver Rod Length  
Volume of the displacer.  
Weight of the displacer.  
Length of the moment arm.  
Sensor Dimensions  
The location of the instrument when mounted on the  
level sensor, whether it is to the right or left of  
displacer.  
Instrument Mounting  
The selected units for length measurements and  
parameters.  
Length Units  
Volume Units  
Weight Units  
The selected units for displacer volume.  
The selected units for displacer weight.  
Sensor Units  
The selected units for temperature measurements and  
parameters.  
Temperature Units  
The selected units for density measurements and  
parameters.  
Fluid Density Units  
Torque Rate Units  
Unit of torque rate.  
Compound torsion rate of torque tube, pilot shaft, and  
instrument flexure, computed during calibration.  
Compensated Torque Rate  
Selected torque tube material for torque tube  
temperature compensation.  
Torque Tube Material  
Torque Tube  
Torque Tube Wall  
Sensor Type  
The thickness of the torque tube used.  
249 model level sensor used.  
Process  
Group  
Name  
Description  
Process Fluid  
Actual process fluid to be measured.  
Process Fluid Compensated  
Density  
Actual fluid density after temperature compensation.  
Process Fluid  
The selected units for density measurements and  
parameters.  
Fluid Density Units  
Temperature input to the instrument via RTD, manually  
input, or none.  
Process Temperature Input  
Process Temperature  
Temperature Units  
Temperature  
Compensation  
Actual temperature of the process.  
The selected units for temperature measurements and  
parameters.  
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HART  
Group  
Name  
Description  
The polling address for the instrument. If a  
point-to-point configuration is used, enter 0. If a  
multidrop configuration is used, enter a value in the  
range of 1 to 62, and disable loop current mode.  
Polling Address  
Communication Settings  
Field device dynamic variable that has been mapped  
into the Primary Variable.  
PV is  
SV is  
TV is  
QV is  
Field device dynamic variable that has been mapped  
into the Secondary Variable.  
Variable Mapping  
Field device dynamic variable that has been mapped  
into the Tertiary Variable.  
Field device dynamic variable that has been mapped  
into the Quaternary Variable.  
Safety Recovery (DLC3100 SIS)  
Group  
Name  
Description  
Auto: DLC3100 SIS is in Trip Alarm Current state; when  
the alarm current condition is cleared, the instrument  
will automatically revert back to normal operating  
current condition.  
Recovery  
Trip Recovery Mode  
Manual: DLC3100 SIS is in Trip Alarm Current state, when  
the alarm current condition is cleared, instrument will  
remain in trip alarm current state. You will need to  
manually reset the instrument by “Safety Reset”.  
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Alert Setup  
Note  
The DLC3100 has to be put out of service when carrying out Alert Setup. Place the loop into manual operation before putting  
device out of service as the output will not be valid.  
When the DLC3100 is out of service, it is locked for exclusive access by the Primary/Secondary master that put it out of service. If  
the instrument reports Locked by HART or Access Restricted when you attempt to configure it, and a master of the original  
priority is not available, use Force Mode on the Local User Interface menu to force the instrument mode to In Service. You will  
then be able to take it out of service with your own master to make changes.  
Primary Variable  
Group  
Description  
PV Alert Deadband  
The monitored primary variable must move more than this value to clear the alert.  
Indicates that the primary variable has violated the user-specified high high alert point.  
Output current will be set to alarm current depending on the hardware Alarm Switch  
configuration.  
PV Hi Hi Alert  
PV Hi Alert  
PV Lo Alert  
Indicates that the primary variable has violated the user-specified high alert point.  
Indicates that the primary variable has violated the user-specified low alert point.  
Indicates that the primary variable has violated the user-specified low low alert point.  
Output current will be set to alarm current depending on the hardware Alarm Switch  
configuration.  
PV Lo Lo Alert  
Note  
check the PV alert settings to make sure the alert thresholds are according to the analog output action.  
Table 14. Analog Output Action - Direct  
Direct Action  
(Span = Upper Range Value – Lower Range Value)  
Alarm Variable  
PV Hi Hi Alarm  
Default Value in unit  
Upper Range Value  
Default Value in percentage  
100%  
95%  
5%  
PV Hi Alarm  
PV Lo Alarm  
PV Lo Lo Alarm  
95% span + Lower Range Value  
5% span + Lower Range Value  
Lower Range Value  
0%  
Table 15. Analog Output Action - Reverse  
Reverse Action  
(Span = Lower Range Value – Upper Range Value)  
Alarm Variable  
PV Hi Hi Alarm  
Default Value in unit  
Default Value in percentage  
Lower Range Value  
0%  
5%  
PV Hi Alarm  
PV Lo Alarm  
PV Lo Lo Alarm  
95% span + Upper Range Value  
5% span + Upper Range Value  
Upper Range Value  
95%  
100%  
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For example, with a 14 inch displacer, PV Hi and PV HiHi alert will be active when the fluid level goes beyond the alert  
points. Likewise, PV Lo and PV LoLo will be active when the fluid level falls below the alert points.  
Table 16. Example; 14 Inch Displacer  
Action  
Range Value  
PV Alerts  
PV HiHi  
PV Hi  
Units  
13.3 in  
12.6 in  
1.4 in  
Percentage  
95%  
URV  
14 in  
0 in  
90%  
Direct  
PV Lo  
10%  
LRV  
URV  
LRV  
PV LoLo  
PV HiHi  
PV Hi  
0.7 in  
5%  
13.3 in  
12.6 in  
1.4 in  
5%  
0 in  
10%  
Reverse  
PV Lo  
90%  
14 in  
PV LoLo  
0.7 in  
95%  
Rate Limit  
Name  
Description  
Displacer Rise Rate  
Exceeded  
Indicates if the device detected a rise rate that exceeded the limit.  
Indicates if the device detected a fall rate that exceeded the limit.  
Displacer Fall Rate  
Exceeded  
Temperature  
Name  
Description  
Process Temperature  
Deadband  
The process temperature must move more than this value to clear the alert.  
The instrument temperature must move more than this value to clear the alert.  
Instrument Temperature  
Deadband  
Process Temperature Hi  
Alert  
Indicates that the process temperature has violated the user-specified high alert  
point.  
Process Temperature Lo  
Alert  
Indicates that the process temperature has violated the user-specified low alert  
point.  
Instrument Temperature Hi Indicates that the instrument temperature has violated the user-specified high alert  
Alert  
point.  
Instrument Temperature  
Lo Alert  
Indicates that the instrument temperature has violated the user-specified the low  
alert point.  
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Operational  
Name  
Description  
Indicates that parameters affecting calibration validity have been changed since the  
last calibration was accepted.  
Calibration Validity Alert  
Analog Output Fixed  
Indicates that the output is in fixed current mode, not tracking process.  
Indicates that the analog output is saturated at 3.8 mA or 20.5 mA.  
Analog Output Saturated  
Indicates that the process applied to the primary variable is outside the operating  
limits of the field device.  
PV Out of Limits  
Indicates that the process applied to the non-primary variable is outside the  
operating limits of the field device.  
Non-PV Out of Limits  
Device Malfunction  
PV AO Readback Fail  
Indicates that the field device has malfunctioned due to a hardware error or failure.  
Indicates that the output readback for the primary variable has deviated by the  
hard-coded limits.  
Indicates that the lever assembly is in locked position and will not respond to level  
changes.  
Lever Assembly Locked  
Calibration in Progress  
Set if a calibration routine is currently running in the instrument.  
Informational  
Name  
Description  
Indicates that a modification has been made to the configuration of the field device  
(configuration variable, tag descriptor or date).  
Configuration Changed  
Device Configuration  
Locked  
Indicates that the device is locked for exclusive access or in write-protect mode.  
Indicates that the device is not in service.  
Out of Service  
Indicates that a reset or selftest of the field device has occurred, or power has been  
removed and reapplied.  
Cold Start  
Input Compensation  
Name  
Description  
Indicates that process fluid density values have crossed. The upper fluid density is  
too close to 0.1 SGU or has become greater than the lower fluid density.  
Fluid Value Crossed  
Indicates that the custom process fluid density table or torque tube table being used  
for temperature compensation is invalid.  
Invalid Custom Table  
Temp Out of  
Compensation Range  
Indicates that the compensation temperature has exceeded the compensation table  
limits.  
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Hardware  
Name  
Description  
Reference Voltage  
Failed  
Indicates that the reference voltage for the Analog/Digital converter is outside the  
hard-coded limits.  
Indicates that the hall sensor reading has not been changing for 10 consecutive samples  
or has violated one of the hard-coded limits.  
Hall Sensor Alert  
Indicates that the apparent resistance measured at the RTD terminals is less than 10 ohms  
or greater than 320 ohms.  
RTD Sensor Alert  
Hall Diagnostic Failed  
Indicates that the internal hall diagnostics has possible failure in the Hall circuitry.  
RTD Diagnostic Failed Indicates that the device has failed to diagnose the integrity of the RTD.  
Instrument  
Indicates that both mainboard temperature sensors are reporting outside operating  
Temperature Sensor  
temperature range or differ by more than 10 degC.  
Alert  
Program and Memory  
Name  
Description  
Watchdog Reset  
Executed  
Indicates that the watchdog timer has timed out, triggering a hardware reset.  
Program Memory  
Failed  
Indicates that the program memory is corrupt.  
NVM Error  
Indicates that data in the critical section of configuration memory is corrupt.  
Indicates that the instrument is not performing the expected series of calculations.  
Program Flow Error  
EEPROM Write  
Accumulator  
Indicates that the total number of EEPROM writes has exceeded 950,000 cycles.  
Indicates that an on-going RAM test has detected possible corruption in the critical data.  
Indicates that the total number of EEPROM writes has exceeded 160 times within the day.  
RAM Test Error Alert  
EEPROM Daily Write  
Accumulator  
Alert Record  
Name  
Description  
Alert Record Not  
Empty  
Indicates that the alert record has entries.  
Indicates that the number of alert events has met or exceeded the storage capacity of the  
instrument.  
Alert Record Full  
Instrument Time Not  
Set  
Indicates that the instrument time was not initialized after the last power cycle.  
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Calibration  
AMS Configure > Calibration  
Field Communicator Configure > Calibration (2-4)  
Two Points Calibration  
Two Points  
Calibration  
st  
Set DLC3100 to  
“Not In Service”  
Capture 1  
calibration point  
Adjust level  
by at least 5% of  
nominal span  
Running at  
process  
conditions?  
Turn on/off  
temperature  
compensation  
No  
nd  
Capture 2  
Yes  
calibration point  
Select units for  
PV  
measurement  
Set DLC3100 to  
“In Service”  
Two-Points Calibration is usually the most accurate method for calibrating the sensor. It uses independent  
observations of two valid process conditions, together with the hardware dimensional data and specific gravity  
information, to compute the effective torque rate of the sensor. The two data points can be separated by any span  
between a minimum of 5% to 100%, as long as they remain on the displacer. Within this range, the calibration accuracy  
will generally increase as the data point separation gets larger. Accuracy is also improved by running the procedure at  
process temperature, as the temperature effect on torque rate will be captured. (It is possible to use theoretical data  
to pre-compensate the measured torque rate for a target process condition when the calibration must be run at  
ambient conditions).  
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Min/Max Calibration  
Min/Max  
Calibration  
Set DLC3100 to  
“Not In Service”  
Running at  
process  
Turn on/off  
temperature  
compensation  
No  
conditions?  
Yes  
Capture Min  
or Max  
Max  
buoyancy?  
Min  
Establish max  
buoyancy and  
capture  
Confirm fluid(s)  
density  
Establish min  
buoyancy and  
capture  
Establish min  
buoyancy and  
capture  
Establish max  
buoyancy and  
capture  
Set DLC3100 to  
“In Service”  
Min/Max Calibration can be used to calibrate the sensor if the process condition can be changed to the equivalent of a  
completely dry and completely submerged displacer, but the actual precise intermediate values cannot be observed  
(eg. no sight glass is available, but the cage can be isolated and drained or flooded). Correct displacer information and  
the SG of the test fluid must be entered before performing this procedure.  
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Weight Calibration  
Weight  
Calibration  
Set DLC3100 to  
“Not In Service”  
Apply larger weight  
of no more than max  
load allowed on driver  
rod and capture 1  
calibration point  
1
Counter-  
Weight  
Apply smaller counter-  
weight of at least min  
Weight  
Weight/  
Counter-Weight?  
load allowed and capture  
st  
st  
1
calibration point  
Apply larger counter-  
weight than previous  
step and capture 2  
Apply smaller weight  
than previous step on  
nd  
driver rod and capture  
calibration point  
nd  
2
calibration point  
Set DLC3100 to  
“In Service”  
Weight Calibration may be used on the bench or with a calibration jig that can apply a mechanical force to the driver  
rod to simulate displacer buoyancy changes. It allows the instrument and sensor to be calibrated using equivalent  
weights or force inputs instead of using the actual displacer buoyancy changes. If the displacer information has been  
entered prior to beginning the procedure, the instrument will be able to compute reasonable weight value  
suggestions for the calibration. The weight values suggested during the weight calibration aim to achieve maximum  
torque tube rotation for better accuracy. It does not necessary mean the weight at 0% or 100%. The only preliminary  
data essential for the correct calibration of the torque rate is the length of the driver rod being used for the calibration.  
Weight equivalent to the net displacer weight at two valid process conditions must be available. The sensor must have  
been sized properly for the expected service, so that the chosen process conditions are in the free motion linear range  
of the sensor.  
Table 17. Maximum Unbuoyed Displacer Weight  
Sensor Type  
Torque Tube Wall Thickness  
Displacer Weight, W (lb)  
T
Thin  
Standard  
Heavy  
3.3  
5.0  
9.5  
249, 249B, 249BP  
Standard  
Heavy  
4.0  
6.4  
249C, 249CP  
249VS  
Thin  
Standard  
3.0  
5.5  
Thin  
Standard  
4.5  
8.5  
249L, 249P  
Thin  
Standard  
3.8  
7.3  
249K  
1.ꢀHigh pressure Class 900 through 2500.  
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Two Points Time Delay Calibration  
Two Points  
Time Delay  
Calibration  
Use  
previously  
captured 1  
point?  
Set DLC3100 to  
“Not In Service”  
No  
st  
Yes  
Turn on/off  
temperature  
compensation  
Running at  
process  
conditions?  
No  
Select units for  
PV  
measurement  
Yes  
Select units for  
PV  
measurement  
nd  
Capture 2  
calibration point  
Yes  
First point  
captured?  
No  
st  
Capture 1  
calibration point?  
Set DLC3100 to  
“In Service”  
Two Points Time Delay is a two points calibration in which the two points captured can be taken some time apart. The  
first point is captured and stored indefinitely until the second point is captured. All instrument configuration data is  
needed to perform a Two Points Time Delay Calibration.  
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Zero Trim  
Gain Trim  
Zero Trim  
Partial  
Gain Trim  
Partial  
Calibration  
Calibration  
Set DLC3100 to  
“Not In Service”  
Set DLC3100 to  
“Not In Service”  
Running at  
process  
conditions?  
Turn on/off  
temperature  
compensation  
Running at  
process  
conditions?  
Turn on/off  
temperature  
compensation  
No  
No  
Yes  
Yes  
Select units for  
PV  
Select units for  
PV  
measurement  
measurement  
Input observed  
PV  
Input observed  
PV  
Set DLC3100 to  
“In Service”  
Set DLC3100 to  
“In Service”  
Trim Zero computes the value of the input angle  
required to align the digital Primary Variable with the  
user’s observation of the process, and corrects the  
stored input zero reference, assuming that the  
calibration gain is accurate.  
Gain Trim trims the torque rate value to align the  
digital Primary Variable with the user’s observation.  
This calibration assumes that sensor zero is already  
accurate and only a gain error exists. Actual process  
condition must be nonzero and able to be measured  
independently. Configuration data must contain  
density of calibration fluid(s), displacer volume, and  
driver rod length.  
Torque Rate Gain  
Torque Rate Gain allows you to input the torque rate.  
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Accuracy Considerations  
Effect of Proportional Band  
If a DLC3100 with level sensor is operating at low Proportional Band [PB = 100% times (full span torque tube rotation) /  
(4.4 degrees)], there will be a degradation factor of about (100%)/(PB%) on the device accuracy specifications.  
Note  
This formula is most correct for linearity errors that are relatively steepsided. If the linearity error curve shape is simple with  
relatively gradual slope, the net effect of reducing span may be less. Instruments such as the DLC3100, that use a compensation  
technique to reduce the residual mechanical or electrical nonlinearity, will generally have a complex shape for the neterror curve.  
If this is too much degradation, an improvement of 2.0 can be obtained by using a thinwall torque tube. Additional  
gain can be achieved by increasing the displacer diameter. Available clearance inside the cage, and the need to keep  
the net displacer weight at the highest and lowest process conditions within the usable range of the torque tube/driver  
rod combination, place practical limits on how much the sizing can be adjusted.  
With an overweight displacer, the calibration process becomes more difficult as the zero buoyancy condition will occur  
with the linkage driven hard into a travel stop. In interface measurement application, it is recommended to calibrate  
with actual process fluids (upper and lower fluids), or set the application to level and use water to calibrate the  
DLC3100.  
Density Variations in Interface Applications  
A high sensitivity to errors in the knowledge of fluid density can develop in some interface applications.  
For example: Suppose the whole input span is represented by an effective change in SG of 0.18. Then a change in the  
actual SG of the upper fluid from 0.8 to 0.81 could cause a measurement error of 5.6% of span at the lowest interface  
level. The sensitivity to the knowledge of a fluid density is maximum at the process condition where that fluid covers  
all the displacer, zero at the opposite extreme process condition, and varies linearly between those points.  
If the fluid density changes are batchrelated or very gradual, it may be practical to keep track of the SG of the fluid and  
periodically reconfigure the DLC3100 density setting to match the actual process condition. Frequent automatic  
updates to this variable are not advisable as the NVM location where it is stored has a write limit. If changes are only a  
function of temperature, the characteristic of the fluid can be loaded once in the density table, and an RTD connected  
to measure the process temperature and drive the temperature compensation table. If temperature is not the driving  
influence, the best that can be done is to calibrate for the widest potential differential SG. This will keep the variations  
as small a percentage of calibrated span as possible. Then calculate an alarm threshold that will prevent vessel overor  
underflow at the worst-case error.  
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Extreme Process Temperatures  
For applications that will run at extreme temperatures, the effect of process temperature on the torque tube must be  
considered. Best results are obtained by running the torque tube calibration at actual process temperature. However,  
the decrease in spring rate with temperature can be simulated at room temperature by increasing the load on the  
torque tube during roomtemperature calibration. This will produce the same deflection that would occur at actual  
process conditions. This compensation is theoretical and not perfect, but is still an improvement over ambient  
calibration with no attempt at compensation.  
Note  
For additional information, refer to the Simulation of Process Conditions for Calibration of Fisher Level Controllers and  
Transmitters instruction manual supplement (D103066X012), available at Fisher.com.  
Temperature Compensation  
AMS Configure > Manual Setup > Process  
Field Communicator Configure > Manual Setup > Process (2-3-4)  
If the process temperature departs significantly from calibration temperature, temperature compensation can be  
enabled. By selecting Process Temperature Input to either RTD or Manual, the temperature compensation will be  
enabled. DLC3100 digital level controller will use the correct fluid density from the default fluid table (depending on  
Custom Table must have ascending temperature inputs.  
Table 18. Example Specific Gravity vs Temperature Table for Saturated Water  
Temperature  
Data Point  
Specific Gravity  
_C  
_F  
1
2
3
4
5
26.7  
93.3  
80.0  
200.0  
350.0  
480.0  
580.0  
0.9985  
0.9655  
0.8935  
0.8040  
0.7057  
176.7  
248.9  
304.4  
6
7
8
9
10  
337.8  
354.4  
365.6  
371.1  
374.7  
640.0  
670.0  
690.0  
700.0  
706.5  
0.6197  
0.5570  
0.4940  
0.4390  
0.3157  
You can also correct the temperature effect by applying a correction factor to the torque tube rate. Interpolate the  
correction factor from the materialspecific tables of theoretical normalized modulus of rigidity versus temperature,  
as described in Simulation of Process Conditions for Calibration of Fisher Level Controllers and Transmitters  
(D103066X012). Multiply the measured torque tube rate (editable in Configure > Calibration > Trim Current  
Calibration > Torque Tube Gain) by the correction factor and enter the new value. This approach allows a better  
approximation of the actual torque tube behavior at process conditions when calibration cannot be carried out at  
process temperature.  
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July 2019  
Section 5  
Service Tools  
Active Alerts  
AMS Service Tools > Alerts  
Field Communicator Services Tools > Alerts (3-1)  
Alert  
Description  
Any device configuration has been changed (configuration variable, tag  
descriptor or date).  
Configuration Changed  
Calibration Validity  
A parameter that directly affects PV calculation has been modified through  
an inappropriate calibration method.  
Cold Start  
Power has just been applied to the device or a device reset has occurred.  
The device is in Out of Service mode or in fixed current mode.  
PV is above the PV Hi alarm value.  
Analog Output Fixed  
PV Hi  
PV Lo  
PV is below the PV Lo alarm value.  
Process Temperature Too High  
Process Temperature Too Low  
Process temperature is above Process Temperature Hi alarm value.  
Process temperature is below Process Temperature Lo alarm value.  
Electronics board temperature is above Electronics Temperature Hi alarm  
value.  
Instrument Temperature Too High  
Instrument Temperature Too Low  
Electronics board temperature is below Electronics Temperature Lo alarm  
value.  
Alert Event Record Not Empty  
Alert Event Record Full  
There is at least one entry in the device alert event record log.  
The Alert Event Record log has reached its maximum number of 30 entries.  
The device is in calibration sequence.  
Calibration in Progress  
Instrument Time Not Set  
Device Configuration Locked  
Lever Assembly Locked  
Analog Output Saturated  
PV Out of Limits  
Instrument time has not been set since power up.  
Instrument is in write protection mode or it is locked.  
Lever assembly is in locked position.  
The loop current has been driven to saturation, 3.8 mA or 20.5 mA.  
PV is less than 0% or more than 100%.  
PV Range Out of Sensor Range  
Displacer Rise Rate Exceeded  
Displacer Fall Rate Exceeded  
Fluid Values Crossed  
PV has gone beyond 20% of sensor range.  
Level has risen greater than Rapid Rate Limit value.  
Level has fallen greater than Rapid Rate Limit value.  
SG of two fluids are too close or have crossed.  
Custom table has less than 2 pairs input or temperature inputs are not in  
ascending order.  
Invalid Custom Table  
Temperature Out of Compensation  
Range  
The current temperature is beyond the valid table temperature range.  
Instrument temperature is beyond the operating range.  
Process temperature is beyond the range of -200 degC to 427 degC.  
In Level or Interface application, compensated lower SG is outside the  
range of density limits.  
Non-PV Out of Limits  
Program Flow Error  
Any critical or non-critical tasks missed execution for 5 consecutive cycles.  
- continued on next page -  
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Instruction Manual  
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Active Alerts (continued)  
Alert  
Description  
PV HiHi Alert  
PV LoLo Alert  
The PV has gone above user-adjustable PV HiHi alarm threshold.  
The PV has gone below user-adjustable PV LoLo alarm threshold.  
Any of the below alerts are active:  
•Hall Sensor Alert  
Device Malfunction  
•Program Memory Failed  
•NVM Error  
•RAM Test Error Alert  
Reference Voltage Failed  
Internal reference voltage has deviated more than tolerance.  
PV Analog Output  
Readback Limit Failed  
PV Analog Output Readback has deviated from the driven current.  
Instrument Temperature  
Sensor Alert  
Electronics temperature sensors have failed.  
Hall Sensor Alert  
Hall sensor reading is invalid.  
RTD Sensor Alert  
The sensor reading for the process temperature is invalid.  
Hall current readback has deviated from the driven current.  
Ongoing flash checksum operation does not match firmware checksum.  
Hall Diagnostics Failed  
Program Memory Failed  
Configuration data affecting the safety critical parameters in the memory is  
corrupted.  
NVM Error  
RAM Test Error Alert  
Critical RAM data is corrupted.  
Watchdog Reset  
Executed  
Watchdog reset has just been performed.  
Tests  
AMS Service Tools > Maintenance > Tests  
Field Communicator Service Tools > Maintenance > Tests (3-4-2)  
Test  
Description  
Instrument Display  
This is a LCD test. It will turn on/off all the pixels on LCD for 3 seconds.  
This is a loop test. It allows changing of output current. This test has to be done when  
the instrument is not in service.  
Analog Output  
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July 2019  
Reset/Restore Device  
AMS Service Tools > Maintenance > Reset/Restore Device  
Field Communicator Service Tools > Maintenance > Reset/Restore Device (3-4-1)  
Restore Factory Defaults will set the following parameters to default values:  
Parameter  
Polling Address  
Default Setting  
0
Instrument Mounting  
Temperature Compensation  
Process Temperature Input  
Torque Tube Material  
Application  
Right of Displacer  
Disable  
None  
K-Monel  
Level  
Displacer Length  
14 in  
3
Displacer Volume  
99 in  
Displacer Weight  
4.75 lb  
8 in  
Driver Rod Length  
Lower Fluid Density  
1 SGU  
Torque Rate  
8.80662 lb-in/deg  
Disable  
Manual Recovery  
0 sec  
Write Protection  
Trip Recovery Mode (DLC3100 SIS only)  
PV Damping  
Input Filter Time  
0 sec  
Level Offset  
0 in  
PV HiHi Alert  
14 in  
PV LoLo Alert  
0 in  
PV Hi Alert  
13.3 in  
0.7 in  
PV Lo Alert  
PV Alert Deadband  
0.14 in  
7
HART Universal Revision  
Instrument Temperature Hi Alert  
Instrument Temperature Lo Alert  
Instrument Temperature Deadband  
Process Temperature Hi Alert  
Process Temperature Lo Alert  
Process Temperature Deadband  
Rate Limit  
176 degF  
-40 degF  
9 degF  
797 degF  
-328 degF  
9 degF  
1.778 in  
0 degF  
176 degF  
Maximum Recorded Temperature  
Minimum Recorded Temperature  
Reset Device is equivalent to power cycle the DLC3100 digital level controller.  
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Instruction Manual  
D104213X012  
Section 6  
Maintenance and Troubleshooting  
The DLC3100 digital level controller features a modular design for easy maintenance. If there is a malfunction, check  
for an external cause before performing the diagnostics describe in this section.  
Sensor parts are subject to normal wear and must be inspected and replaced as necessary. For sensor maintenance  
information, refer to appropriate sensor instruction manual.  
WARNING  
To avoid personal injury, always wear protective gloves, clothing, and eyewear when performing any maintenance  
operations.  
Personal injury or property damage due to sudden release of pressure, contact with hazardous fluid, fire, or explosion can  
be caused by puncturing, heating, or repairing a displacer that is retaining process pressure or fluid. This danger may not  
be readily apparent when disassembling the sensor or removing the displacer. Before disassembling the sensor or  
removing the displacer, observe the appropriate warnings provided in the sensor instruction manual.  
Check with your process or safety engineer for any additional measures that must be taken to protect against process  
media.  
CAUTION  
When replacing components, use only components specified by the factory. Always use proper component replacement  
techniques, as presented in this manual. Improper techniques or component selection may invalidate the approvals and  
Alert Messages  
In addition to the level measurement and output current, the LCD displays abbreviated alert messages for  
troubleshooting the digital level controller. To check for alert messages, push the left button when the LCD is in Home  
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Table 19. Alert Messages  
Alert  
Description  
DEVICE MALFUNC  
ANALOG O/P | FIXED  
ANALOG O/P | SATURATED  
NON-PV | OUT OF LIMITS  
PV | OUT OF LIMITS  
PROG MEM FAIL  
Device Malfunction  
Analog Output Fixed  
Analog Output Saturated  
Non-PV Out of Limits  
PV Out of Limits  
Program Memory Failed  
Instrument Temp Sensor  
Hall Sensor  
TEMP SENSOR  
HALL SENSOR  
HALL DIAG FAIL  
Hall Diagnostics Failed  
Reference Voltage Failed  
REF VOLT FAIL  
PV ANALOG O/P | READBACK FAIL  
RTD DIAG FAIL  
PV Analog Output Readback Limited Failed  
RTD Diagnostics Failed  
RTD Sensor  
RTD SENSOR  
CALIBRATION | IN PROGRESS  
CAL VALIDITY  
Calibration In Progress  
Calibration Validity  
PROG FLOW ERR  
Program Flow Error  
INST TIME| NOT SET  
PV HI  
Instrument Time Not Set  
PV Hi  
PV HI HI  
PV Hi Hi  
PV LO  
PV Lo  
PV LO LO  
PV Lo Lo  
PROC TEMP | TOO HIGH  
PROC TEMP | TOO LOW  
INST TEMP | TOO HIGH  
INST TEMP | TOO LOW  
FLUID VALUES | CROSSED  
TEMP OUT OF | COMP RANGE  
CUSTOM TABLE | INVALID  
RISE RATE | EXCEEDED  
FALL RATE | EXCEEDED  
WATCHDOG RESET  
RAM ERROR  
Process Temperature Too High  
Process Temperature Too Low  
Instrument Temperature Too High  
Instrument Temperature Too Low  
Fluid Values Crossed  
Temperature Out of Compensation Range  
Invalid Custom Table  
Displacer Rise Rate Exceeded  
Displacer Fall Rate Exceeded  
Watchdog Rest Executed  
RAM Test Error  
NVM ERROR  
NVM Error  
OUT OF SERVICE  
Instrument Out of Service  
EEPROM Write Exceeded  
EEPROM Daily Write Exceeded  
EEPROM WRITE | EXCEEDED  
EEPROM DAILY | WRITE EXCEEDED  
Hardware Diagnostics  
If a malfunction is suspected despite the absence of diagnostic alert messages on the LCD, follow the procedures  
order. Under each of the major symptoms, specific suggestions are offered for solving problems. Always deal with the  
most likely and easiest-to-check conditions first.  
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Table 20. Troubleshooting  
Symptom  
Potential Cause  
Device Description  
Corrective Action  
Make sure the Field Communicator has the correct Device  
Description to communicate with the DLC3100 digital level  
controller.  
Check resistance between the power supply and the Field  
Communicator connection. The net resistance in the loop must be  
between 230 and 600ohms for HART communication.  
Check for adequate voltage to the digital level controller. Refer to  
figure 10 for requirements. Some models of battery operated field  
calibrators do not have sufficient compliance voltage to operate a  
DLC3100 over the entire output current range.  
Analog Output is within valid  
range but instrument does not  
communicate with Field  
Communicator  
Loop Wiring  
Terminal Box  
Check for excessive capacitance in the field wiring (Isolate the  
instrument from field wiring and try to communicate locally).  
The terminal box may have developed a high internal resistance.  
Try replacing the terminal box electronics board.  
Main Electronics Board  
Loop Wiring  
Replace the Main Electronics Board with a known good part.  
Check for open circuit.  
Check for proper polarity at the +/- terminals.  
Check for adequate voltage to the digital level controller.  
Check resistance between Loop Power “+” and “T” terminals of  
terminal box. If greater than 1.1 ohm, the terminal sense resistor  
may be damaged. Replace the terminal box electronics.  
Output at 0mA  
Terminal Box  
Main Electronics Board  
Replace the Main Electronics Board with a known good part.  
Check LCD for alert messages to isolate failures.  
For DLC3100 SIS, check if the digital level controller is locked in  
safety and requires a manual reset.  
Check PV against the PV HiHi and PV LoLo alarm threshold and  
deadband setting, if these alarms are enabled.  
Alarm Condition  
(Alarm Low setting)  
Fixed Output at <= 3.6mA  
Check the PV against the upper and lower range values. Check  
actual process condition and calibration adjustments.  
Fixed Output at 3.8mA  
Fixed Output at 20.5mA  
Low Saturation  
High Saturation  
Check the PV against the upper and lower range values. Check  
actual process condition and calibration adjustments.  
Check LCD for alert messages to isolate failures.  
For DLC3100 SIS, check if the digital level controller is locked in  
safety and requires a manual reset.  
Check PV against the PV HiHi and PV LoLo alarm threshold and  
deadband setting, if these alarms are enabled.  
Alarm Condition  
(Alarm High setting)  
Fixed Output at >= 21mA  
Output is within 4-20mA range,  
but does not track displayed PV  
value:  
Connect the Field Communicator and run a Loop Test. If the forced  
output does not track the commands, replace the Main Electronics  
Board.  
•Gain error  
Main Electronics Board  
•Low saturation occurs at  
value higher than 3.8mA  
•High saturation occurs at a  
value lower than 20.5mA  
Use appropriate material for process temperature.  
Sensor  
Pre-compensate the calibration for target process condition.  
Connect the Field Communication and check instrument  
temperature. If instrument temperature value is extreme, replace  
the whole DLC3100 digital level controller.  
Transducer Module  
Output Drifting while at fixed  
process input  
Connect the Field Communicator and run Loop Test. Leave  
instrument in fixed current mode at 12 mA command and observe  
analog output variation with ambient temperature. If drift exceeds  
specifications, replace the main electronics board.  
Main Electronics Board  
Configuration Data  
Connect the Field Communicator and check stored Specific Gravity  
values against independent measurement of process density. If  
process SG has changed from calibration values, correct the SG in  
configuration to match the process.  
-continued-  
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July 2019  
Symptom  
Potential Cause  
Corrective Action  
If output current enters a limit cycle between zero and a value  
within the 4-20 mA range when level reaches some arbitrary upper  
threshold, check for excessive loop resistance or low compliance  
voltage.  
Erratic Output  
Loop Wiring  
Loop Wiring  
Check for excessive loop resistance or low compliance voltage.  
Replace front cover assembly with known good part.  
Replace front cover assembly.  
Erratic display on LCD  
Push Buttons Stuck  
LCD Assembly  
Push Buttons Assembly  
Figure 10. Power Supply Requirements and Load Resistance  
Maximum Load = 43.5 X (Available Supply Voltage - 12.0)  
783  
Operating  
Region  
250  
0
10  
12  
15  
20  
25  
30  
LIFT‐OFF SUPPLY VOLTAGE (VDC)  
Removing the DLC3100 from the Sensor  
Because the DLC3100 digital level controller has a modular design, most of the service and maintenance to the digital  
level controller can be done without removing it from the sensor. However, if it is necessary to replace sensor to  
instrument mating parts or parts in the transducer housing, or to perform bench maintenance, perform the following  
procedures to remove the digital level controller from the sensor.  
WARNING  
On an explosion proof instrument, remove the electrical power before removing the instrument covers in a hazardous  
area. Personal injury or property damage may result from fire and explosion if power is applied to the instrument with the  
covers removed.  
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Tools Required  
Table 21. Tools Required  
Tool  
Size  
Usage  
Terminal box cover set screw (key 34)  
Front Cover screws (key 49)  
Hex Key  
2 mm  
6 mm  
4 mm  
10 mm  
13 mm  
Hex Key  
Hex Key  
Lever assembly mount cap screws (key 11)  
Coupling nut  
Hex Socket  
Open-end  
DLC3100 mounting nuts (key 15)  
Terminal screws  
Electronics module mounting screws  
Small Flat Blade Screwdriver  
- - -  
1. Loosen the set screw (key 34) in the terminal box cover assembly (key 7) so that the cover can be unscrewed from  
the terminal box.  
2. After removing the cover, note the location of field wiring connections and disconnect the field wiring from the  
wiring terminals.  
and slide toward the front of the DLC3100 (locked position), to expose the access hole. Be sure the locking handle  
drops into the detent.  
Figure 11. Access Handle  
ACCESS HOLE  
ACCESS HANDLE  
- LOCK (ACCESS HOLE EXPOSED)  
- UNLOCK (ACCESS HOLE COVERED)  
X1499  
Note  
If the access handle will not slide, the sensor linkage is most likely in an extreme position. When the lever assembly is at a hard stop  
inside the housing, the locking pin on the access door may not be able to engage the mating slot in the lever assembly. This  
condition can occur if the displacer has been removed, if the sensor is lying on its side, or if the instrument had been coupled to the  
sensor while the displacer was not connected. To correct this condition, manipulate the sensor linkage to bring the lever assembly  
to within approximately 4 degrees of the neutral position before attempting to slide the handle. A probe inserted through the top  
vent of the 249 head may be required to deflect the driver rod to a position where the lever assembly is free.  
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July 2019  
5. Loosen and remove the hex nuts (key 15) from the mounting studs (key 14).  
CAUTION  
Tilting the instrument when pulling it off of the sensor torque tube can cause the torque tube shaft to bend. To prevent  
damage to the torque tube shaft, ensure that the digital level controller is level when pulling it off the sensor torque tube.  
6. Remove the digital level controller as follows:  
DFor standard temperature applications carefully pull the digital level controller straight off the sensor torque  
tube.  
DFor high temperature applications carefully pull the digital level controller straight off the sensor torque tube  
7. Pull the heat insulator (key 57) off the mounting studs.  
When re-installing the digital level controller, follow the appropriate procedure outlined in the quick start guide  
(D104214X012). Setup the digital level controller as described in the Initial Setup section.  
Figure 12. Digital Level Controller Mounting on Sensor in High Temperature Applications  
INSULATOR  
(KEY 57)  
SHAFT  
EXTENSION  
(KEY 58)  
SET SCREWS  
(KEY 60)  
WASHER  
(KEY 78)  
SHAFT  
COUPLING  
(KEY 59)  
HEX NUTS  
(KEY 34)  
CAP SCREWS  
(KEY 63)  
MOUNTING STUDS  
(KEY 33)  
B2707  
DIGITAL LEVEL CONTROLLER  
SENSOR  
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Figure 13. DLC3100 Assembly Drawing  
GG25866  
Front Cover Assembly  
WARNING  
In an explosion proof or flame proof installation, remove the electrical power before removing the instrument covers in a  
hazardous area. Personal injury or property damage may result from fire and explosion if power is applied to the  
instrument with the covers removed.  
Removing the Front Cover Assembly  
Perform the following procedure to remove the front cover assembly:  
1. Disconnect power to the digital level controller.  
2. Loosen the four cap screws (key 49) and pull the front cover out slowly, as the main electronics board is connected  
to the hall sensor electronics board cable and terminal box cable.  
3. Disconnect the hall sensor board and terminal box electronics board cables from the main electronics board.  
4. Unscrew the three screws holding the main electronics board and remove it from the LCD assembly.  
5. Remove the two screws holding the LCD assembly and remove it from the front cover assembly.  
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Replacing the Front Cover Assembly  
Perform the following procedure to replace the front cover assembly:  
1. Mount the LCD assembly onto the front cover assembly and tighten the two screws.  
2. Mount the main electronics board onto the LCD assembly and tighten the three screws.  
3. Connect the cables from the hall sensor board and terminal box electronics board to the main electronics board.  
4. Make sure the O-ring is in place and install the front cover assembly to the digital level controller housing with the  
four cap screws, and tighten to 35 N•m (310 lbf•in).  
Main Electronics Board  
Removing the Main Electronics Board  
Note  
The Main Electronics Board is potted and it is a non-repairable unit. If a malfunction occurs, the entire main electronics board must  
be replaced.  
WARNING  
On an explosion proof instrument, remove the electrical power before removing the instrument covers in a hazardous  
area. Personal injury or property damage may result from fire and explosion if power is applied to the instrument with the  
covers removed.  
1. Disconnect power to the digital level controller.  
2. Remove the front cover and disconnect the cables of the hall sensor board and the terminal box electronics board  
connected to the main electronics board.  
3. Unscrew the three screws holding the main electronics board.  
4. Firmly grasp the Main Electronics Board and remove it from the LCD assembly.  
Replacing the Main Electronics Board  
Perform the following procedure to replace the main electronics board:  
1. Mount the main electronics board onto the LCD assembly.  
2. Tighten the three mounting screws.  
3. Install the cables of the hall sensor board and the terminal box electronics board to the main electronics board.  
4. Install the front cover with the four cap screws and tighten to 35 N•m (310 lbf•in) torque value.  
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LCD Assembly  
Removing the LCD Assembly  
WARNING  
On an explosion proof instrument, remove the electrical power before removing the instrument covers in a hazardous  
area. Personal injury or property damage may result from fire and explosion if power is applied to the instrument with the  
covers removed.  
1. Disconnect power to the digital level controller.  
2. Remove the front cover and disconnect the cables of the hall sensor board and the terminal box electronics board  
connected to the main electronics board.  
3. Remove the main electronics board  
4. Loosen the two screws holding the LCD assembly to the front cover assembly.  
Replacing the LCD Assembly  
Perform the following procedure to replace the LCD assembly:  
1. Mount the LCD assembly onto the front cover assembly.  
2. Tighten the two mounting screws.  
3. Connect the main electronics board to the LCD assembly and tighten the three mounting screws.  
4. Install the cables from the hall sensor board and the terminal box electronics board to the main electronics board.  
5. Install the front cover to the housing with the four cap screws and tighten to 35 N•m (310 lbf•in) torque value.  
Terminal Box Electronics Board  
The terminal box is located at the side of the housing and contains the terminal strips for field wiring connections.  
WARNING  
On an explosion proof instrument, remove the electrical power before removing the instrument covers in a hazardous  
area. Personal injury or property damage may result from fire and explosion if power is applied to the instrument with the  
covers removed.  
Removing the Terminal Box Electronics Board  
1. Disconnect power to the digital level controller.  
2. Loosen the four cap screws and remove front cover assembly. Disconnect the terminal box electronics board cable  
connected to the main electronics board.  
3. Loosen the set screw (key 34) in the terminal box cover assembly (key 7) so that the cover can be unscrewed from  
the terminal box.  
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July 2019  
4. After removing the cover (key 35), note the location of field wiring connections and disconnect the field wiring from  
the wiring terminals.  
5. Remove the screw (key 68) and pull out the terminal box electronics board.  
Replacing the Terminal Box Electronics Board  
Note  
Inspect all O-rings for wear and replace as necessary.  
1. Orient the terminal box electronics board and carefully insert into the housing.  
2. Ensure the cable of the terminal board electronics board goes through the housing.  
3. Tighten the screws of the terminal box electronics board to the housing.  
4. Connect the terminal box electronics board cable to the main electronics board.  
5. Install the front cover assembly to the housing and tighten the four cap screws.  
6. Connect the field wiring to the terminals on the terminal box electronics board.  
7. Screw the terminal box cover assembly (key 7) completely onto the terminal box to seat the O-ring (key 16).  
Loosen the cover (not more than 1 turn) until the set screw (key 24) aligns with one of the recesses in the terminal  
box beneath the cover. Tighten the set screw to engage the recesses but not more than 0.88 N•m (7.8 lbf•in).  
Packing for Shipment  
If it becomes necessary to return the unit for repair or diagnosis, contact your Emerson sales office for returned goods  
information.  
CAUTION  
Lock the lever assembly when shipping the standalone instrument, to prevent damage to the flexure.  
Use the original shipping carton if possible.  
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Instruction Manual  
D104213X012  
Section 7  
Parts  
Parts Ordering  
Whenever corresponding with your Emerson sales office about this equipment, always mention the controller serial  
number.  
WARNING  
Use only genuine Fisher replacement parts. Components that are not supplied by Emerson Automation Solutions should  
not, under any circumstances, be used in any Fisher instrument. Use of components not supplied by Emerson may void  
your warranty, might adversely affect the performance of the instrument, and could cause personal injury and property  
damage.  
Parts Kits  
Parts List  
Kit  
Description  
Part Number  
Note  
ꢂꢂ1* Small Hardware Spare Parts Kit  
GG51086X012  
Contact your Emerson sales office for Part ordering information.  
Includes  
Qty/kit  
Set screw, key 34  
Cap screw, key 21  
ꢀꢀWire Retainer, key 17  
Wire Retainer, key 18  
Cap screw, key 11  
Cap screw, key 13  
Hex nut, key 15  
Machine screw, key 8  
Stud, key 14  
2
2
2
2
2
4
8
4
8
Key  
Description  
Part Number  
ꢀ1  
ꢀ2  
ꢀ3  
ꢀ4  
ꢀ5  
ꢀ6  
ꢀ7  
ꢀ8  
ꢀ9  
Housing Assembly  
Main Board Assembly  
LCD Assembly  
GG25852X012  
GG25861X012  
Cover Assembly  
Nameplate, instrument  
Terminal Box Assembly  
Terminal Cover Assembly  
Screw, machine  
GG25784X012  
GG25788X012  
ꢂꢂ2* Spare O‐Rings Kit  
GG51085X012  
Transducer Housing  
Includes  
ꢀꢀKey 16  
Key 37  
Key 38  
Key 70  
Qty/kit  
10  
11  
12  
13  
14  
15  
Lever Assembly  
Screw, cap  
Shield, coupling  
Screw, cap  
Stud  
2
8
2
2
Nut, hex  
16  
17  
18  
19  
O-ring  
Wire Retainer  
Wire Retainer  
Pipe Plug  
*Recommended spare parts  
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Figure 14. Fisher DLC3100 Digital Level Controller Assembly  
GG25838  
APPLY LUBRICANT/ADHESIVE/THREADLOCK  
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Key  
Description  
Key  
Description  
59  
60  
61  
62  
67  
68  
69  
70  
71  
72  
Potting compound  
Magnet  
20  
21  
22  
23  
24  
25  
26  
Handle Assembly  
Screw, cap  
Button, sticker  
Pipe Thread Sealant  
Label, blank  
Guide, inner  
Screw, machine  
Bracket, plate  
PCBA, Sensor  
Hall Sensor Guard  
Screw, machine  
Terminal Box Assembly  
O-ring  
Wire Assembly  
Terminal Box Assembly  
27  
28  
29  
30  
31  
32  
33  
34  
Spring, compression  
Button, striker  
Pin, locking  
Handle  
100  
Coupling Block Subassembly  
100a Coupling Block  
100b Insert, front  
100c Insert, back  
Handle  
Magnet  
Adhesive  
Screw, set  
101  
Lever Subassembly  
101a Lever  
35  
37  
38  
39  
40  
42  
43  
44  
46  
Terminal Box Cap  
O-ring  
101b Roll Pin  
101c Coupling Bellows  
101d Counter Weight  
101e Adhesive, 3M Scotch  
O-ring  
Cover Assembly  
O-ring  
Button, striker  
Retainer  
102  
Magnet and Lever Subassembly  
102a Backup Plate  
102b Magnet  
102c Adhesive  
102d Activator  
Button, membrane  
Retainer  
47  
48  
49  
50  
51  
52  
53  
54  
55  
56  
57  
58  
Screw, countersunk  
Plate, face  
103a Bolt, lock  
Screw, cap  
103b Washer, lock, spring  
103c Nut, clamp  
Adhesive, Loctite  
Sealing Compound  
Sealant  
103d Block, flexure  
103e Flexure  
Lubricant, silicone sealant  
Screw, machine  
Retainer, screen  
Cover  
103f Clamp, flexure  
103g Screw, cap  
103h Lubricant, grease  
103j Adhesive, structural  
103k Activator  
O-ring  
Cover, front  
103m Loctite 499  
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Figure 15. Fisher DLC3100 Digital Level Controller Assembly  
GG25861  
GG25784  
APPLY LUBRICANT/ADHESIVE/THREADLOCK  
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Mounting Kits  
Key  
Description  
Note  
Contact your Emerson sales office for information on ordering the  
following mounting kits or for information on the availability of  
additional mounting kits.  
12100 or 12800 without Heat Insulator  
58  
59  
60  
61  
62  
63  
Shaft Extension  
Shaft Coupling  
Set Screw, hex socket (2 req'd)  
Screw, hex hd (4 req'd)  
Mounting Adapter  
Key  
Description  
Screw, hex socket, (4 req'd)  
12100 or 12800 with Heat Insulator  
249 Sensors with Heat Insulator  
57  
58  
59  
60  
61  
62  
63  
78  
Heat Insulator  
Shaft Extension  
57  
58  
59  
60  
61  
78  
Heat Insulator,  
Shaft Coupling  
Shaft Extension  
Set Screw, hex socket (2 req'd)  
Screw, hex hd (4 req'd)  
Mounting Adapter  
Shaft Coupling  
Set Screw, hex socket (2 req'd)  
Screw, hex hd (4 req'd)  
Washer, plain (4 req'd)  
Screw, hex socket (4 req'd)  
Washer, plain (4 req'd)  
Figure 16. Mounting Kit for 249 Sensors with Heat Insulator  
28B5741‐A  
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July 2019  
Figure 17. Mounting Kit for Masoneilan 12200 and 12300 Sensor without Heat Insulator  
29B8444‐A  
Figure 18. Mounting Kit for Masoneilan 12200 and 12300 Sensor with Heat Insulator  
29B84
57  
 
DLC3100 Digital Level Controller  
July 2019  
Instruction Manual  
D104213X012  
Key  
Description  
Key  
Description  
12200 or 12300 without Heat Insulator  
Foxboro‐Eckardt Sensors  
58  
59  
60  
62  
74  
75  
Shaft Extension  
144LD without Heat Insulator  
Shaft Coupling  
58  
59  
60  
62  
74  
75  
Shaft Extension  
Hex Socket Screw (2 req'd)  
Mounting Adaptor  
Hex Nut (4 req'd)  
Shaft Coupling  
Set Screw, hex socket (2 req'd)  
Mounting Adapter  
Hex Nut (4 req'd)  
Hex Cap Screw (4 req'd)  
Hex Cap Screw (4 req'd)  
12200 or 12300 with Heat Insulator  
144LD with Heat Insulator  
57  
58  
59  
61  
60  
62  
74  
75  
78  
Heat Insulator  
Shaft Extension  
57  
58  
59  
60  
61  
62  
74  
75  
78  
Heat Insulator  
Shaft Coupling  
Shaft Extension  
Hex Cap Screw (4 req'd)  
Hex Socket Screw (2 req'd)  
Mounting Adaptor  
Shaft Coupling  
Set Screw, hex socket (2 req'd)  
Screw, hex hd (4 req'd)  
Mounting Adapter  
Hex Nut (4 req'd)  
Hex Nut (4 req'd)  
Hex Cap Screw (4 req'd)  
Washer, plain (4 req'd) not shown  
Hex Cap Screw (4 req'd)  
Washer, plain (4 req'd)  
LP167 without Heat Insulator  
Yamatake NQP Sensor  
58  
59  
60  
62  
63  
Shaft Extension  
Shaft Coupling  
Without Heat Insulator  
Set Screw, hex socket (2 req'd)  
Mounting Adapter  
58  
59  
60  
62  
63  
71  
72  
73  
Shaft Extension  
Screw, hex socket (4 req'd)  
Shaft Retainer  
Hex Socket Screw  
Mounting Adaptor  
Hex Socket Screw(3 req'd)  
Hex Socket Screw (3 req'd)  
Shaft Adapter  
Sunshade  
Hex Socket Screw (2 req'd)  
Sunshades are available in two materials and orderable  
as a kit.  
With Heat Insulator  
57  
58  
59  
60  
61  
62  
63  
71  
72  
73  
78  
Heat Insulator  
Description  
Part Number  
Shaft Extension  
Shaft Retainer  
Sunshade  
Hex Socket Screw  
GG44394X012  
GG43970X012  
Hex Cap Screw (4 req'd)  
Mounting Adaptor  
Hex Socket Screw (3 req'd)  
Hex Socket Screw (3 req'd)  
Shaft Adapter  
Kits Include  
Qty/kit  
ꢀꢀHex head cap screw, key S1  
ꢀꢀFlanged hex nut, key S2  
ꢀꢀSunshade, key S3  
2
2
1
1
Hex Socket Screw (2 req'd)  
Washer, plain (4 req'd)  
ꢀꢀMounting bracket, key S4  
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DLC3100 Digital Level Controller  
Instruction Manual  
D104213X012  
July 2019  
Figure 19. FIELDVUE DLC3100 with 316 SST Sunshade  
S2  
S3  
S1  
S4  
GG44394  
Figure 20. FIELDVUE DLC3100 with Glass Reinforced Plastic (GRP) Sunshade  
S2  
S3  
S4  
S1  
GG43970  
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DLC3100 Digital Level Controller  
July 2019  
Instruction Manual  
D104213X012  
Appendix A  
Principle of Operation  
HART Communication  
The HART (Highway Addressable Remote Transducer) protocol gives field devices the capability of communicating  
instrument and process data digitally. This digital communication occurs over the same two‐wire loop that provides  
the 4-20 mA process control signal, without disrupting the process signal. In this way, the analog process signal, with  
its faster update rate, can be used for control. At the same time, the HART protocol allows access to digital diagnostic,  
maintenance, and additional process data. The protocol provides total system integration via a host device.  
The HART protocol uses the frequency shift keying (FSK) technique based on the Bell 202 communication standard. By  
superimposing a frequency signal over the 4-20 mA current, digital communication is attained. Two individual  
frequencies of 1200 and 2200 Hz are superimposed as a sinewave over the 4-20 mA current loop. These frequencies  
to the 4-20 mA signal. Thus, true simultaneous communication is achieved without interrupting the process signal.  
Figure 21. HART Frequency Shift Keying Technique  
+0.5 mA  
0
ANALOG  
SIGNAL  
-0.5 mA  
1200 Hz  
“1”  
2200 Hz  
“0”  
AVERAGE CURRENT CHANGE DURING COMMUNICATION = 0  
A6174  
The HART protocol allows the capability of multidropping, networking several devices to a single communications line.  
This process is well suited for monitoring remote applications such as pipelines, custody transfer sites, and tank farms.  
Multidrop Communication  
“Multidropping” refers to the connection of several digital level controllers or transmitters to a single communications  
transmission line. Communication between the host and the field instruments takes place digitally with the analog  
output of the instruments deactivated. With the HART communications protocol, up to 15 field instruments can be  
connected on a single twisted pair of wires or over leased phone lines. Multidrop installations are not recommended  
where intrinsic safety is a requirement.  
The application of a multidrop installation requires consideration of the update rate necessary from each instrument,  
the combination of instrument models, and the length of the transmission line. Communication with the field  
instruments can be accomplished with commercially available Bell 202 modems and a host implementing the HART  
protocol. Each instrument is identified by a unique address (1-15) and responds to the commands defined in the HART  
protocol.  
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Instruction Manual  
D104213X012  
July 2019  
sales office with specific requirements for multidrop applications.  
Figure 22. Typical Multidropped Network  
BELL 202  
MODEM  
LOAD  
HOST  
POWER  
SUPPLY  
The Field Communicator can test, configure, and format a multidropped DLC3100 digital level controller in the same  
way as in a standard point‐to‐point installation, provided that it has been configured to scan for multiple polling  
addresses.  
Note  
DLC3100 digital level controllers are set to address 0 at the factory, allowing them to operate in the standard point‐to‐point  
manner with a 4-20 mA output signal. To activate multidrop communication, the address must be changed to a number between  
1 and 15. This change deactivates the 4-20 mA analog output, sending it to 4 mA. The failure mode current also is disabled.  
Digital Level Controller Operation  
The DLC3100 digital level controller is a loop‐powered instrument that measure changes in liquid level, level of an  
interface between two liquids, or density of a liquid. Changes in the buoyancy of a displacer suspended in a vessel vary  
the load on a torque tube. The displacer and torque tube assembly constitute the primary mechanical sensor. The  
angular deflection of the torque tube is measured by the instrument transducer, which consists of a magnet system  
moving over a Hall effect device. A liquid crystal display (LCD) meter can display the analog output or process variable  
(level, interface level, or density) in units or percent range.  
The instrument uses a microcontroller and associated electronic circuitry to measure the process variable, provide a  
meter, the processor module, the transducer board, and the terminal board. The processor module contains the  
microprocessor, the analog‐to‐digital (A/D) converters, loop interface, signal conditioning, the digital‐to‐analog (D/A)  
output, power supply and interfaces to other boards.  
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DLC3100 Digital Level Controller  
July 2019  
Instruction Manual  
D104213X012  
Figure 23. FIELDVUE DLC3100 Digital Level Controller Assembly  
HOUSING ASSEMBLY  
MAIN BOARD  
ASSEMBLY  
LCD METER  
ASSEMBLY  
TERMINAL BOX  
ASSEMBLY  
TRANSDUCER  
BOARD  
TERMINAL  
BOX COVER  
COVER ASSEMBLY  
GG25866  
Figure 24. FIELDVUE DLC3100 Digital Level Controller Principle of Operation  
Transducer Module  
Electronics  
Temperature  
Sensor  
Electronics  
Temperature  
Terminal  
Box  
Loop / HART  
Interface  
Shaft Position  
Transducer  
Torque Tube  
Rotation  
Sensors on  
Processor  
Module  
Linearization Data  
resident in NVM  
RTD  
Process  
Temperature  
Interface  
LCD Meter  
The transducer board contains the Hall sensor, a temperature sensor to monitor the Hall sensor temperature, and an  
EEPROM to store the coefficients associated with the Hall sensor. The terminal board contains the EMI filters, the loop  
connection terminals, and the connections for the optional RTD used to measure process temperature.  
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DLC3100 Digital Level Controller  
Instruction Manual  
D104213X012  
July 2019  
This change is transferred to the torque tube assembly. As the measured fluid changes, the torque tube assembly  
rotates up to 4.4 degrees for a 249 sensor, varying the digital level controller output between 4 and 20 mA.  
Figure 25. Typical Sensor Operation  
TORQUE  
TUBE  
DISPLACER  
249 SENSOR (SIDE VIEW)  
W1389‐1  
The rotary motion of the torque tube is transferred to the digital level controller lever assembly. The rotary motion  
moves a magnet attached to the lever assembly, changing the magnetic field that is sensed by the Hall effect sensor.  
The sensor converts the magnetic field signal to an electronic signal.  
The microcontroller accepts the electronic signal, which is ambient‐temperature‐compensated and linearized. The  
microcontroller can also actively compensate for changes in liquid specific gravity due to changes in process  
temperature based on an input via HART protocol or via an optional RTD, if it is connected. The D/A output circuit  
accepts the microcontroller output and provides a 4 to 20 mA current output signal.  
During normal operation, when the input is between the lower and upper range values, the digital level controller  
the lower and upper range values, the output will continue to be proportional to the input until the output reaches  
either 3.8 or 20.5 mA. At this time the output is considered saturated and will remain at this value until the input  
returns to the normal operating range. However, should an alarm occur, the output is driven to either > 21 mA or < 3.6  
mA, depending on the Alarm High/Low switch setting.  
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DLC3100 Digital Level Controller  
July 2019  
Instruction Manual  
D104213X012  
Figure 26. Digital Level Controller Analog Output Signal  
24  
22  
20  
Output Saturated  
(20.5 mA)  
Output during Alarm with  
Alarm Switch in High Position  
18  
16  
14  
12  
10  
8
> 21.0 mA  
Normal Operation  
Output Saturated  
(3.8 mA)  
Output during Alarm with  
Alarm Switch in Low  
Position  
6
< 3.6 mA  
4
2
-20%  
0%  
20%  
40%  
PV Range  
60%  
80%  
100%  
120%  
Note  
The alarm values are compliant with NAMUR NE‐43.  
Other circuits in the digital level controller provide reverse polarity protection, transient power surge protection, and  
electromagnetic interference (EMI) protection.  
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DLC3100 Digital Level Controller  
Instruction Manual  
D104213X012  
July 2019  
Appendix B  
Field Communicator Fast-Key Sequence and Menu Tree  
Fast-Key Sequence  
Function/Variable  
Active Alerts  
Fast-Key-Sequence  
3-1-1  
Function/Variable  
Clear Rate Alert  
Cold Start  
Fast-Key-Sequence  
2-4-2-1  
Alarm Switch  
1-7-3-1-1  
1-7-3-1-3  
2-4-9-5  
2-4-5-1  
Alarm/Sat Levels  
Alert Record Full  
Alerts Recorded  
Comm Status  
1-1-2  
Communication  
2-3-5-1  
2-4-9-4  
2-3-3-3-1  
3-2-1-4  
Comp. Torque Rate  
1-2-3  
2-3-4-3-1  
3-2-2-3-1  
2-3-3-3-4  
2-4-5-2  
3-2-1-5  
Analog Output  
3-3-2  
Compensation  
Analog Output Action  
AO Fixed  
2-3-2-2  
Config Changed  
Daily Write Accum  
Date  
2-4-4-4  
2-4-8-6  
AO Readback Fail  
AO Saturated  
2-4-4-6  
2-3-1-2  
2-4-4-3  
1-4-2  
Hot Key - 3  
1-3  
2-3-4-1-2  
3-2-1-3-2  
2-3-1-3  
Density, PrcFld  
Application  
2-3-2-1-1  
3-2-1-1  
Descriptor  
DD Information  
Dev Config Locked  
Device ID  
1-7-2-5  
Assembly Code  
1-7-1-5-3  
Hot Key - 6  
2-5-1  
2-4-5-4  
Calibration  
1-7-1-4  
Cal in Progress  
2-4-4-9  
Device Malfunction  
Device Revision  
Device Setup  
2-4-4-5  
2-5-3  
1-7-2-2  
Calibration in Use  
Calibration Invalid  
3-4-1-1  
2-2-1  
2-4-4-8  
Device Status  
1-1-1  
2-5-3-2  
Displacer Length  
Displacer Volume  
Displacer Weight  
Distributor  
2-3-3-2-1  
2-3-3-2-2  
2-3-3-2-3  
1-7-1-2  
Calibration Method  
3-4-1-1-2  
3-4-1  
Calibration/Setup Logs  
Change AO Action  
2-3-2-3  
Hot Key - 4  
2-3-2-1-2  
Hot Key - 5  
2-3-4-1-3  
2-3-2-1-7  
2-3-2-1-5  
2-4-2-2  
Driver Rod Length  
Fall Rate Alert  
2-3-3-2-4  
2-4-2-4  
Change Application  
Change Fluid  
Firmware, Revision  
Fluid Density Table  
1-7-2-4  
2-3-4-1-4  
2-3-3-1-5  
2-3-4-1-5  
2-4-6-3  
Change Level Offset  
Change PV Range  
Change/Sec Limit  
Clear Alert Record  
Fluid Density Units  
Fluid Values Crossed  
2-4-9-2  
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DLC3100 Digital Level Controller  
July 2019  
Instruction Manual  
D104213X012  
Function/Variable  
Gain Trim  
Fast-Key-Sequence  
Function/Variable  
Proc Temp D/band  
Proc Temp Hi Alert  
Fast-Key-Sequence  
2-4-3-3  
2-4-3-5  
1-5  
2-5-2-2  
2-4-7-4  
2-4-7-5  
1-7-2-3  
2-2-4  
Hall Diagn Fail  
Hall Sensor Alert  
Hardware, Revision  
Help, Device Setup  
HW Information  
Input Filter Time  
Inst Temp D/band  
Inst Temp Hi Alert  
Inst Temp Lo Alert  
Inst Temp Snsr Alert  
2-3-4-2  
3-2-2-2  
2-4-3-6  
3-2-1-3-1  
2-3-4-1-1  
1-4-1  
Proc Temp Input  
Proc Temp Lo Alert  
Process Density  
2-3-3-4  
2-3-2-5-2  
2-4-3-4  
2-4-3-7  
2-4-3-8  
2-4-7-6  
2-4-3-2  
3-2-2-1-1  
3-3-3  
Process Fluid  
Process Setup  
2-2-3  
2-3-4-3-2  
2-4-3-1  
3-2-2-3-2  
2-4-8-4  
2-4-8-5  
Hot Key - 2  
1-7-3-2  
3-2-1-2-2  
2-4-1-3  
2-3-2-5-1  
2-4-1-4  
2-4-1-6  
2-4-1-5  
2-4-1-7  
2-4-1-8  
2-3-2-4-2  
2-4-4-1  
2-2-2  
Process Temperature  
Inst Temperature  
Prog Memory Failed  
Program Flow Error  
Inst Time Not Set  
Instrument Date  
2-4-9-3  
2-3-1-5  
2-3-3-2-5  
2-3-1-7-1  
1-7-1-5-1  
2-3-1-6  
2-4-6-1  
3-4-2-1  
2-3-3-1-1  
2-3-2-1-6  
2-4-4-7  
3-4-2-2  
2-3-2-1-4  
2-4-1-2  
Protection  
Instrument Mounting  
PV  
Instrument SN  
PV Alert Units  
PV Damping  
PV Deadband  
PV Hi Alert  
Instrument Time  
Invalid Custom Table  
LCD Test  
PV Hi Hi Alert  
PV Lo Alert  
Length Units  
Level Offset  
PV Lo Lo Alert  
PV Lower Sensor Limit  
PV Out of Limits  
PV Setup  
Lever Assy Locked  
LOOP Test  
Lower Range Value  
PV Upper Sensor Limit  
2-3-2-4-1  
1-2-2  
Max Recorded,  
Temperature Limit  
3-2-2-1-2  
PV Value  
Message  
2-3-1-4  
2-5-1-1  
3-2-1-2-1  
2-4-8-2  
2-4-7-3  
1-7-3-1-2  
3-4-3-2  
2-4-2-3  
2-4-7-2  
2-4-7-1  
1-7-1-5-2  
2-3-1-7-2  
2-3-3-3-6  
3-4-3-1  
2-5-1-5  
Min/Max, Calibration  
RAM Test Error  
Ref Voltage Fail  
Refresh Switch  
Reset Device  
Min Recorded,  
Temperature Limit  
3-2-2-1-3  
Hot Key - 1  
1-1-3  
Mode  
Rise Rate Alert  
RTD Diagn Fail  
RTD Sensor Alert  
2-1  
Model  
1-7-1-3  
2-3-3-2-6  
2-4-4-2  
2-4-8-1  
2-4-5-3  
2-3-5-2  
3-3-1  
Mounting Illustration  
Non-PV Out of Limits  
NVM Error  
Sensor SN  
Sensor Type  
Out of Service  
Polling Address  
Primary Variable  
Set Factory Defaults  
Simple Zero/Span  
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July 2019  
Function/Variable  
Fast-Key-Sequence  
1-7-1-1  
Function/Variable  
Variable Mapping  
Volume Units  
Fast-Key-Sequence  
2-3-5-3  
Tag  
2-3-1-1  
2-3-3-1-2  
Temp Compensation  
Temp Out of Comp  
Temperature Limit  
1-6  
Watchdog Executed  
Weight, Calibration  
Weight Units  
2-4-8-3  
2-5-1-4  
2-3-3-1-3  
2-4-87  
2-4-6-2  
3-2-2-1  
2-3-3-1-4  
2-3-4-3-3  
2-3-3-1-6  
2-3-3-3-2  
2-5-2-3  
Write Accum Alert  
View Record  
Temperature Units  
Torque Rate Units  
2-4-9-1  
2-5-2-1  
Zero Trim  
Torque Tube Gain  
Menu Tree  
Torque Tube Wall  
Tube Material  
2-3-3-3-5  
2-3-3-3-3  
2-5-1-2  
Figure 27. Hot Key  
Two-Point, Calibration  
Two-Point Time Delay  
Universal Revision  
Hot Key  
2-5-1-3  
1 Mode  
2 Protection  
1-7-2-1  
3 Application  
4 Change Application  
5 Change Fluid  
6 Calibration  
2-3-2-1-3  
2-4-1-1  
Upper Range Value  
Figure 28. Overview  
1
1-7-1-5  
Serial Numbers  
1-1  
Status  
1-1-1  
Device Status  
Overview  
1 Status  
2 PV  
1 Instrument SN  
2 Sensor SN  
3 Assembly Code  
1 Device Status  
2 Comm Status  
3 Mode  
1 Refresh Alerts  
2 No Active Alerts  
3 Application  
4 Fluid Type  
5 Proc Temp Input  
6 Temp Compensation  
7 Device Information  
1-7-1  
Identification  
1-7-3-1  
Alarm Configuration  
1-2  
PV  
1 Tag  
2 Distributor  
3 Model  
4 Device ID  
5 Serial Numbers  
1 Alarm Switch  
2 Refresh Switch  
3 Alarm/Sat Levels  
1 PV  
2 PV Value  
3 Analog Output  
1-7-3-2  
1-4  
Protection  
Fluid Type  
1-7-2  
Revisions  
1 Protection  
1 Process Fluid  
2 Change Protection  
2 Density, PrcFld  
1 Universal Revision  
2 Device Revision  
3 Hardware  
1-6  
Temp Compensation  
4 Firmware  
5 DD Information  
1 Compensation  
2 Process Temperature  
1-7  
1-7-3  
Device Information  
Alarm Type and Security  
1 Identification  
2 Revisions  
1 Alarm Configuration  
2 Protection  
3 Alarm Type and Security  
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July 2019  
Instruction Manual  
D104213X012  
Figure 29. Configure > Mode, Guided Setup & Manual Setup  
2-3-1-7  
Serial Numbers  
2
1 Instrument SN  
2 Sensor SN  
Configure  
2-3-1  
General  
2-1  
Mode  
1 Mode  
2 Guided Setup  
3 Manual Setup  
4 Alert Setup  
5 Calibration  
1 Tag  
2 Date  
1 Mode  
2 Change Mode  
2-3-2-1  
Primary Variables  
3 Descriptor  
4 Message  
5 Instrument Date  
6 Instrument Time  
7 Serial Numbers  
1 Application  
2 Change Application  
3 Upper Range Value  
4 Lower Range Value  
5 Change PV Range  
6 Level Offset  
2-2  
Guided Setup  
1 Device Setup  
2 PV Setup  
3 Process Setup  
4 Help  
7 Change Level Offset  
2-3-2  
Device  
2-3-2-4  
Sensor Limits  
1 Primary Variables  
2 Analog Output Action  
3 Change AO Action  
4 Sensor Limits  
2-3  
Manual Setup  
1 PV Upper Sensor Limit  
2 PV Lower Sensor Limit  
1 General  
2 Device  
5 Damping  
3 Sensor  
4 Process  
5 HART  
6 Safety Recovery (only  
6 available for DLC3100 SIS)  
2-3-2-5  
Damping  
2-3-3  
Sensor  
1 PV Damping  
2 Input Filter Time  
1 Units  
2 Dimensions  
3 Torque Tube  
4 HW Information  
2-3-3-1  
Units  
1 Length Units  
2 Volume Units  
2-3-4  
3 Weight Units  
Process  
4 Temperature Units  
5 Fluid Density Units  
6 Torque Rate Units  
1 Process Fluid  
2 Proc Temp Input  
3 Compensation  
2-3-3-2  
Dimensions  
2-3-5  
HART  
1 Displacer Length  
2 Displacer Volume  
3 Displacer Weight  
4 Driver Rod Length  
5 Instrument Mounting  
6 Mounting Illustration  
1 Communication  
2 Polling Address  
3 Variable Mapping  
2-3-3-3  
Torque Tube  
1 Comp. Torque Rate  
2 Torque Tube Gain  
3 Tube Material  
4 Compensation Table  
5 Torque Tube Wall  
6 Sensor Type  
2-3-4-1  
Process Fluid  
1 Process Fluid  
2 Density, PrcFld  
3 Change Fluid  
4 Fluid Density Table  
5 Fluid Density Units  
2-3-4-3  
Compensation  
1 Compensation  
2 Process Temperature  
3 Temperature Units  
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July 2019  
Figure 30. Configure > Alert Setup  
2
Configure  
2-4-1  
2-4-1-5  
2-4  
Primary Variable  
PV Hi Hi Alert  
Alert Setup  
1 Mode  
2 Guided Setup  
3 Manual Setup  
4 Alert Setup  
5 Calibration  
1 Upper Range Value  
2 Lower Range Value  
3 PV Alert Units  
4 PV Deadband  
5 PV Hi Hi Alert  
6 PV Hi Alert  
1 PVHiHi St  
2 Priority  
3 Enable Alert  
4 Hi Hi Alert Point  
5 Enable Trip Current  
1 Primary Variable  
2 Rate Limit  
3 Temperature  
4 Operational  
5 Informational  
6 Input Compensation  
7 Hardware  
7 PV Lo Alert  
2-4-1-6  
8 PV Lo Lo Alert  
8 Program and Memory  
9 Alert Record  
PV Hi Alert  
1 PVHi St  
2 Priority  
2-4-2  
3 Enable Alert  
4 Hi Alert Point  
5 Trip Alarm OFF  
Rate Limit  
1 Clear Rate Alert  
2 Change/Sec Limit  
3 Rise Rate Alert  
4 Fall Rate Alert  
2-4-1-7  
PV Lo Alert  
1 PVLo St  
2 Priority  
3 Enable Alert  
4 Lo Alert Point  
5 Trip Alarm OFF  
2-4-1-8  
PV Lo Lo Alert  
1 PVLoLo St  
2 Priority  
3 Enable Alert  
4 Lo Lo Alert Point  
5 Enable Trip Current  
2-4-2-3  
Rise Rate Alert  
1 RiseRate St  
2 Priority  
3 Enable Alert  
4 Trip Alarm OFF  
2-4-2-4  
Fall Rate Alert  
1 FallRate St  
2 Priority  
3 Enable Alert  
4 Trip Alarm OFF  
Alert Setup  
Continued on next page  
69  
 
DLC3100 Digital Level Controller  
July 2019  
Instruction Manual  
D104213X012  
2-4-3-5  
Proc Temp Hi Alert  
1 ProcTempHi St  
2 Priority  
2
3 Enable Alert  
4 ProcTempHi Limit  
5 Trip Alarm OFF  
Configure  
2-4  
2-4-3  
Temperature  
Alert Setup  
1 Mode  
2 Guided Setup  
3 Manual Setup  
4 Alert Setup  
5 Calibration  
1 Process Temperature  
2 Inst Temperature  
3 Proc Temp D/band  
4 Inst Temp D/band  
5 Proc Temp Hi Alert  
6 Proc Temp Lo Alert  
7 Inst Temp Hi Alert  
8 Inst Temp Lo Alert  
1 Primary Variable  
2 Rate Limit  
3 Temperature  
4 Operational  
2-4-3-6  
Proc Temp Lo Alert  
1 ProcTempLo St  
2 Priority  
3 Enable Alert  
4 ProcTempLo Limit  
5 Trip Alarm OFF  
5 Informational  
6 Input Compensation  
7 Hardware  
8 Program and Memory  
9 Alert Record  
2-4-3-7  
2-4-4  
Inst Temp Hi Alert  
Operation  
1 InstTempHi St  
2 Priority  
3 Enable Alert  
4 InstTempHi Limit  
5 Trip Alarm OFF  
1 PV Out of Limits  
2 Non-PV Out of Limits  
3 AO Saturated  
4 AO Fixed  
5 Device Malfunction  
6 AO Readback Fail  
7 Lever Assy Locked  
8 Calibration Invalid  
9 Cal in Progress  
2-4-3-8  
Inst Temp Lo Alert  
1 InstTempLo St  
2 Priority  
3 Enable Alert  
4 InstTempLo Limit  
5 Trip Alarm OFF  
2-4-4-1  
PV Out of Limits  
1 PVLimitOut St  
2 Priority  
3 Enabled  
2-4-4-6  
AO Readback Fail  
4 Trip Alarm OFF  
1 AORead Fail St  
2 Priority  
3 Enable Alert  
4 Enable Trip Current  
2-4-4-2  
Non-PV Out of Limits  
1 NonPVLimitOut St  
2 Priority  
3 Enabled  
2-4-4-7  
Lever Assy Locked  
4 Trip Alarm OFF  
1 LeverAssyLocked St  
2 Priority  
2-4-4-3  
3 Enable Alert  
4 Trip Alarm OFF  
AO Saturated  
1 AOSaturated St  
2 Priority  
3 Enabled  
2-4-4-8  
Calibration Invalid  
4 Trip Alarm OFF  
1 CalInvalid St  
2 Priority  
3 Enable Alert  
4 Trip Alarm OFF  
2-4-4-4  
AO Fixed  
1 AOFixed St  
2 Priority  
3 Enabled  
2-4-4-9  
Cal in Progress  
4 Trip Alarm OFF  
1 CalProgress St  
2 Priority  
3 Enable Alert  
4 Trip Alarm OFF  
2-4-4-5  
Device Malfunction  
1 DevMalf St  
2 Priority  
3 Enabled  
4 Enable Trip Current  
Alert Setup  
Continued on next page  
70  
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Instruction Manual  
D104213X012  
July 2019  
2
Configure  
2-4-5-1  
Cold Start  
2-4-5  
Informational  
2-4  
Alert Setup  
1 Mode  
2 Guided Setup  
3 Manual Setup  
4 Alert Setup  
5 Calibration  
1 ColdStart St  
2 Priority  
3 Enabled  
1 Cold Start  
1 Primary Variable  
2 Rate Limit  
3 Temperature  
4 Operational  
2 Config Changed  
3 Out of Service  
4 Dev Config Locked  
4 Trip Alarm OFF  
5 Informational  
6 Input Compensation  
7 Hardware  
8 Program and Memory  
9 Alert Record  
2-4-5-2  
Config Changed  
2-4-6  
Input Compensation  
1 ConfigChange St  
2 Priority  
3 Enabled  
1 Invalid Custom Table  
2 Temp Out of Comp  
3 Fluid Values Crossed  
4 Trip Alarm OFF  
2-4-5-3  
Out of Service  
1 OutofService St  
2 Priority  
3 Enabled  
4 Trip Alarm OFF  
2-4-5-4  
Dev Config Locked  
1 DevConfigLock St  
2 Priority  
3 Enabled  
4 Trip Alarm OFF  
2-4-6-1  
Invalid Custom Table  
1 InvCustomTbl St  
2 Priority  
3 Enable Alert  
4 Trip Alarm OFF  
2-4-6-2  
Temp Out of Comp  
1 TempCompOut St  
2 Priority  
3 Enable Alert  
4 Trip Alarm OFF  
2-4-6-3  
Fluid Values Crossed  
1 FluidValueX St  
2 Priority  
3 Enable Alert  
4 Trip Alarm OFF  
Alert Setup  
Continued on next page  
71  
DLC3100 Digital Level Controller  
July 2019  
Instruction Manual  
D104213X012  
2
Configure  
2-4-7-1  
2-4  
2-4-7  
RTDSensor Alert  
Alert Setup  
Hardware  
1 Mode  
2 Guided Setup  
3 Manual Setup  
2 Rate Limit  
4 Alert Setup  
1 RTD Sensor St  
2 Priority  
3 Enable Alert  
4 Enable Trip Current  
1 Primary Variable  
1 RTD Sensor Alert  
2 RTD Diagn Fail  
3 Ref Voltage Fail  
4 Hall Diagn Fail  
3 Temperature  
5 Calibration  
4 Operational  
5 Informational  
6 Input Compensation  
7 Hardware  
5 Hall Sensor Alert  
6 Inst Temp Snsr Alert  
2-4-7-2  
RTD Diagn Fail  
8 Program and Memory  
9 Alert Record  
1 RTDDiagFail St  
2 Priority  
3 Enable Alert  
4 Enable Trip Current  
2-4-7-3  
Ref Voltage Fail  
1 RefVoltFail St  
2 Priority  
3 Enable Alert  
4 Enable Trip Current  
2-4-7-4  
Hall Diagn Fail  
1 HallDiagFail St  
2 Priority  
3 Enable Alert  
4 Enable Trip Current  
2-4-7-5  
Hall Sensor Alert  
1 HallSensor St  
2 Priority  
3 Enable Alert  
4 Enable Trip Current  
2-4-7-6  
Inst Temp Snsr Alert  
1 InstTempSensor St  
2 Priority  
3 Enable Alert  
4 Enable Trip Current  
Alert Setup  
Continued on next page  
72  
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Instruction Manual  
D104213X012  
July 2019  
2-4-8-1  
NVM Error  
1 NVMError St  
2 Priority  
3 Enable Alert  
4 Enable Trip Current  
2
Configure  
2-4  
2-4-8  
Program and Memory  
Alert Setup  
1 Mode  
2 Guided Setup  
3 Manual Setup  
2 Rate Limit  
4 Alert Setup  
2-4-8-2  
RAM Test Error  
1 NVM Error  
2 RAM Test Error  
1 Primary Variable  
1 RAMTestError St  
2 Priority  
3 Enable Alert  
3 Watchdog Executed  
4 Prog Memory Failed  
5 Program Flow Error  
6 Daily Write Accum  
7 Write Accum Alert  
3 Temperature  
5 Calibration  
4 Operational  
5 Informational  
6 Input Compensation  
7 Hardware  
8 Program and Memory  
9 Alert Record  
4 Enable Trip Current  
2-4-8-3  
Watchdog Executed  
2-4-9  
Alert Record  
1 WatchdogExec St  
2 Priority  
3 Enable Alert  
1 View Record  
4 Enable Trip Current  
2 Clear Alert Record  
3 Inst Time Not Set  
4 Alerts Recorded  
5 Alert Record Full  
2-4-8-4  
Prog Memory Failed  
1 ProgMemFail  
2 Priority  
3 Enable Alert  
4 Enable Trip Current  
2-4-8-5  
Program Flow Error  
1 ProgFlowError St  
2 Priority  
3 Enable Alert  
4 Enable Trip Current  
2-4-8-6  
Daily Write Accum  
1 WriteDaily St  
2 Priority  
3 Enable Alert  
4 Trip Alarm OFF  
2-4-8-7  
Write Accum Alert  
1 WriteAccum St  
2 Priority  
3 Enable Alert  
4 Trip Alarm OFF  
2-4-9-3  
Inst Time Not Set  
1 InstTimeNoSet St  
2 Priority  
3 Enable Alert  
4 Trip Alarm OFF  
2-4-9-4  
Alert Recorded  
1 AlertRecord St  
2 Priority  
3 Enable Alert  
4 Trip Alarm OFF  
2-4-9-5  
Alert Record Full  
1 AlertRecFull St  
2 Priority  
3 Enable Alert  
4 Trip Alarm OFF  
73  
DLC3100 Digital Level Controller  
July 2019  
Instruction Manual  
D104213X012  
Figure 31. Calibration  
2
Configure  
2-5-1  
2-5  
Calibration  
Calibration  
1 Mode  
2 Guided Setup  
3 Manual Setup  
4 Alert Setup  
5 Calibration  
1 Min/Max  
2 Two-Point  
3 Two-Point Time Delay  
4 Weight  
1 Calibration  
2 Trim Current Calibration  
3 Calibration in Use  
5 Simple Zero/Span  
2-5-2  
Trim Current Calibration  
1 Zero Trim  
2 Gain Trim  
3 Torque Tube Gain  
2-5-3  
Calibration in Use  
1 Name  
2 Calibration Method  
3 Hours  
4 Minutes  
5 Calibration Date  
6 Calibrator  
74  
DLC3100 Digital Level Controller  
Instruction Manual  
D104213X012  
July 2019  
Figure 32. Service Tools  
3
Service Tools  
3-1  
Status  
3-1-1  
Active Alerts  
3-2-1-2  
Primary Value  
1 Alerts  
2 Variables  
3 Trends  
1 Active Alerts  
1 Refresh Alerts  
2 No Active Alerts  
1 PV Value  
2 PV  
4 Maintenance  
3-2  
Variables  
3-2-1  
Process  
3-2-1-3  
Process Fluid  
1 Process  
2 Temperature  
1 Application  
2 Primary Value  
3 Process Fluid  
1 Process Density  
2 Density, PrcFld  
4 Comp. Torque Rate  
5 Analog Output  
3-3  
Trends  
3-2-2-1  
Temperature Limit  
1 Primary Variable  
2 Analog Output  
3 Inst Temperature  
3-2-2  
Temperature  
1 Inst Temperature  
2 Max Recorded  
3 Min Recorded  
1 Temperature Limit  
2 Proc Temp Input  
3 Compensation  
3-4  
Maintenance  
3-2-2-3  
Compensation  
1 Calibration/Setup Logs  
2 Tests  
3 Rest/Restore Device  
3-3-1  
Primary Variable  
1 Compensation  
2 Process Temperature  
1 Graph  
2 PV  
3-4-1-1  
Calibration in Use  
3-3-2  
Analog Output  
1 Name  
2 Calibration Method  
3 Hours  
1 Graph  
2 Analog Output  
4 Minutes  
5 Calibration Date  
6 Calibrator  
3-3-3  
Inst Temperature  
1 Graph  
2 Inst Temperature  
3-4-1  
Calibration/Setup Logs  
1 Calibration in Use  
3-4-2  
Tests  
1 LCD Test  
2 LOOP TEST  
3-4-3  
Reset/Restore Device  
1 Set Factory Defaults  
2 Reset Device  
75  
DLC3100 Digital Level Controller  
July 2019  
Instruction Manual  
D104213X012  
Neither Emerson, Emerson Automation Solutions, nor any of their affiliated entities assumes responsibility for the selection, use or maintenance  
of any product. Responsibility for proper selection, use, and maintenance of any product remains solely with the purchaser and end user.  
Fisher and FIELDVUE are marks owned by one of the companies in the Emerson Automation Solutions business unit of Emerson Electric Co. Emerson  
Automation Solutions, Emerson, and the Emerson logo are trademarks and service marks of Emerson Electric Co. All other marks are the property of their  
respective owners.  
The contents of this publication are presented for informational purposes only, and while every effort has been made to ensure their accuracy, they are not  
to be construed as warranties or guarantees, express or implied, regarding the products or services described herein or their use or applicability. All sales are  
governed by our terms and conditions, which are available upon request. We reserve the right to modify or improve the designs or specifications of such  
products at any time without notice.  
Emerson Automation Solutions  
Marshalltown, Iowa 50158 USA  
Sorocaba, 18087 Brazil  
Cernay, 68700 France  
Dubai, United Arab Emirates  
Singapore 128461 Singapore  
E 2017, 2019 Fisher Controls International LLC. All rights reserved.  

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