STR93D 0 to 100 psid 0 to 7 bar
STR94G 0 to 500 psig 0 to 35 bar
In 1983, Honeywell introduced the first
Smart Pressure Transmitter― the ST
3000
the first all digital, bi-directional protocol
for smart field devices. Today, its
ST 3000 Series 900 Remote Seal
Transmitters continue to bring proven
“smart” technology to a wide spectrum
of pressure measurement applications.
For applications in which the
transmitter must be mounted remotely
from the process, Honeywell offers the
remote seal line of gauge, absolute and
differential pressure transmitters.
Typical applications include level
measurement in pressurized vessels in
the chemical and hydrocarbon
processing industries. A second
application is flow measurement for
slurries and high viscosity fluids in the
chemical industry. Honeywell remote
seal transmitters are available with
secondary fill fluids for corrosive or high
temperature process fluids
All ST 3000 transmitters can provide a
4-20 mA output, Honeywell Digitally
Enhanced (DE) output, HART
OUNDATION™ Fieldbus output.
or F
When digitally integrated with
Honeywell’s Process Knowledge
System™, EXPERION PKS™,
ST 3000 instruments provide a more
accurate process variable as well as
advanced diagnostics.
Honeywell’s cost-effective ST 3000
S900 transmitters lead the industry in
reliability and stability:
• Stability = ±0.01% per year
• Reliability = 470 years MTBF
Introduction
®
. In 1989, Honeywell launched
*
output,
Figure 1—Series 900 Remote Seal Pressure Transmitters feature proven
piezoresistive sensors and advanced seal technology with standard weld
connections.
The devices provide comprehensive self-diagnostics to help users
maintain high uptime, meet regulatory requirements, and attain high
quality standards. S900 transmitters allow smart performance at
analog prices. Accurate, reliable and stable, Series 900 transmitters
offer greater turndown ratio than conventional transmitters.
"Honeywell transmitters operating in the digital mode using
Honeywell's Digitally Enhanced (DE) protocol make diagnostics
available right at the control system's human interface. Equally
important, transmitter status information is continuously displayed to
alert the operator immediately of a fault condition. Because the
process variable (PV) status transmission precedes the PV value, we
are guaranteed that a bad PV is not used in a control algorithm. In
addition, bi-directional communication provides for remote transmitter
configuration directly from the human interface, enabling management
of the complete loop.”
Maureen Atchison, DuPont
Site Electrical & Instrumentation Leader
34-ST-03-57
3/07
Specification and
Model Selection
Guide
34-ST-03-57
Page 2
Description of Diaphragm Seals
Diaphragm seals are traditionally used when a standard pressure transmitter should not be exposed to the
process pressure directly. Diaphragm seals typically protect the pressure transmitter from one or more
damaging aspects of the process media. Consideration for using a diaphragm seal should be made in the
following circumstances.
• High Process Temperature
• Process Media is Viscous or Contains Suspended Solids
• Process Media is Subject to Solidifying
• Process Media is Corrosive
• Process Application Requires Sanitary Connections
• Process Application Subjects the Measuring Instrument to Hydrogen Permeation
• Tank Level Applications with Maintenance Intensive Wet Legs
• Tank Application with Density or Interface Measurements
• Measuring Instrument Requires Remote Mounting
The following diaphragm seals are standard from Honeywell (please call your local salesperson if you do not see
the product you need for your application):
Figure 2 -Flush Flange Seals can be used with
differential, gauge and absolute pressure transmitters
and are available with 3” ANSI Class 150, ANSI Class
300 and DIN DN80-PN40 process connections. Flush
flange seals can also be provided with Lowers.
Lowers are essentially calibration rings, which allow
flushing connections if needed – see Figure 31.
Figure 2
Figure 3 - Flange Seal with Extended Diaphragm
can be used with differential, gauge and absolute
pressure transmitters and are available with 3” and 4”
ANSI Class 150, ANSI Class 300, DIN DN80-PN40
and DIN DN100-PN40 process connections. 2”, 4” and
6” extension lengths are available.
Figure 3
Figure 4 - Pancake Seals can be used with
differential, gauge and absolute pressure transmitters
and are available with 3” ANSI Class 150, 300 and 600
process connections.
Figure 5 -Chemical Tee “Taylor” Wedge seals can
be used with differential pressure transmitters and are
available with Taylor Wedge 5” O.D. process
connection.
Figure 4
Figure 5
Description of Diaphragm Seals
Figure 6 - Seals with Threaded Process
Connections can be used with differential, gauge and
absolute pressure transmitters and are available with
½”, ¾” and 1” NPT Female process connections.
34-ST-03-57
Page 3
Figure 7 - Sanitary Seals can be used with
differential, gauge and absolute pressure transmitters
and are available with 3” and 4” Tri-Clover-Tri-Clamp
process connections.
Figure 8 - Saddle Seals can be used with differential,
gauge and absolute pressure transmitters and are
available with 3” and 4” (6 bolt or 8 bolt designs)
process connections.
Figure 9 - Calibration Rings are available with Flush
Flange Seals and Pancake Seals. Flushing ports (1/4”
or ½”) are available with calibration rings.
Figure 6
Figure 7
Figure 8
Figure 10 - Stainless Steel Armor and PVC Coated
Stainless Steel Armor Capillaries are available with Honeywell Remote Seal Solutions.
Figure 11 - 2” Stainless Steel Nipples are available
for Close-Coupled remote seal solutions.
Figure 9
Figure 10
Figure 11
34-ST-03-57
Page 4
Figure 12 - Welded Meter Body for All-Welded
Remote Seal Solution. The welded ST 3000 meter
body is an important part of an All-Welded Remote
Seal Solution, which is commonly used in Vacuum
applications.
Figure 12
Description Features
The ST 3000 transmitter can replace any 4 to 20 mA output transmitter in
•Choice of linear or square
use today and operates over a standard two-wire system.
The measuring means is a piezoresistive sensor, which actually contains
•Direct digital integration with
three sensors in one. It contains a differential pressure sensor, a
temperature sensor, and a static pressure sensor.
Microprocessor-based electronics provide higher span-turndown ratio,
improved temperature and pressure compensation, and improved
accuracy.
The transmitter’s meter body and electronics housing resist shock,
•Unique piezoresistive sensor
vibration, corrosion, and moisture. The electronics housing contains a
compartment for the single-board electronics, which is isolated from an
integral junction box. The single-board electronics is replaceable and
interchangeable with any other ST 3000 Series 100 or Series 900 model
transmitter.
Like other Honeywell transmitters, the ST 3000 features two-way
communication and configuration capability between the operator and the
transmitter through several Honeywell field-rated portable configuration
devices, including the Smart Field Communicator (SFC) and the Multiple
•Smart transmitter capabilities
Communication Configurator (MC ToolKit). While both are made for infield use, the MC Toolkit also can be ordered for use in intrinsically safe
environments.
The SCT 3000 Smartline
®
Configuration Toolkit provides an easy way to
configure instruments using a personal computer. The toolkit enables
configuration of devices before shipping or installation. The SCT 3000 can
operate in the offline mode to configure an unlimited number of devices.
The database can then be loaded down-line during commissioning.
root output conformity is a
simple configuration selection.
Experion PKS and other
control systems provides local
measurement accuracy to the
system level without adding
typical A/D and D/A converter
inaccuracies.
automatically compensates
input for temperature and
static pressure.Added “smart”
features include configuring
lower and upper range
values, simulating accurate
analog output, and selecting
preprogrammed engineering
units for display.
with local or remote
interfacing means significant
manpower efficiency
improvements in
commissioning, start-up, and
ongoing maintenance
functions.
Special High Vacuum
Construction required.
Consult STC.
450
500
193
psig
1Atm
0
psig
-9
psig
-14
psig
10000
9000
8000
7000
6000
5000
4000
3000
NEOBEE M-20
Syltherm 800
-40 to 600°F
30 to 400°F
2000
1000
900
800
700
600
500
400
300
200
100
90
80
70
60
50
40
30
Pressure
20
(mmHgA)
10
-100
-40
52530
0
100
175450
200400500
Process Temperature (Degrees F)
Figure 13—ST 3000 Remote Seals operable limits for pressure versus temperature
550
600
193
psig
90
psig
1Atm
0
psig
-9
psig
-14
psig
20335
1440
1440
1200
1200
Note: A minimum of 250 ohms
Loop
Loop
Resistance
Resistance
(ohms)
(ohms)
800
800
650
650
450
450
250
250
0 10.8 16.28 20.63 25 28.3 37.0 42.4
0 10.8 16.28 20.63 25 28.3 37.0 42.4
Operating Voltage (Vdc)
Operating Voltage (Vdc)
Note: A minimum of 250 ohms
of loop resistance is necessary
of loop resistance is necessary
to support communications.
to support communications.
Loop resistance equals barrier
Loop resistance equals barrier
resistance plus wire resistance
resistance plus wire resistance
plus receiver resistance.
plus receiver resistance.
= Operating Area
= Operating Area
Figure 14—Supply voltage and loop resistance chart
Performance Under Rated Conditions * - Model STR93D (0 to 100 psi/7 bar)
34-ST-03-57
Page 7
Parameter Description
Upper Range Limit psi
bar
Minimum Span psi
bar
Turndown Ratio
Zero Elevation and Suppression
Accuracy (Reference – Includes
combined effects of linearity,
hysteresis, and repeatability)
• Accuracy includes residual error
after averaging successive
readings.
• For F
Combined Zero and Span
Temperature Effect per 28°C
(50°F) **
OUNDATION Fieldbus use
Digital Mode specifications. For
HART use Analog Mode
specifications.
100 (Transmitter URL or maximum seal pressure rating, whichever is lower.)
7
0.9
0.063
110 to 1
No limit except minimum span within ±100% URL.
In Analog Mode: ±0.20% of calibrated span or upper range value (URV), whichever is
greater, terminal based.
For URV below reference point (50 inH2O), accuracy equals:
50 inH2O
±0.10 + 0.10
In Digital Mode: ±0.175% of calibrated span or upper range value (URV), whichever
is greater, terminal based.
For URV below reference point (50 inH2O), accuracy equals:
±0.075 + 0.10
In Analog Mode: ±1.5% of span.
For URV below reference point (200 inH2O), effect equals:
±0.30 + 1.2
±0.30 + 1.2
In Digital Mode: ±1.475% of span.
For URV below reference point (200 inH2O), effect equals:
⎛
span inH2O
⎝
50 inH2O
⎛
span inH2O
⎝
200 in H
200 in H
200 in H2O
⎛
⎛
⎛
⎝
⎝
⎝⎛⎝
span in H
span in H
span in H
⎞
or ±0.10 + 0.10
⎠
⎞
or ±0.075 + 0.10
⎠
O
O
2
2
⎞
⎞
⎞
or ±0.30 + 1.2
or ±0.30 + 1.2
⎠
⎠
⎠⎞⎠
O
O
O
2
2
2
125 mbar
()
span mbar
125 mbar
()
span mbar
500 mbar
500 mbar
500 mbar
⎛
⎛
⎛
⎝
⎝
⎝⎛⎝
span mbar
span mbar
span mbar
in % of span
in % of span
⎞
⎞
⎞
In % span
In % span
⎠
⎠
⎠⎞⎠
500 mbar
200 in H
200 in H2O
200 in H
⎛
⎛
±0.275 + 1.2
±0.275 + 1.2
* Performance specifications are based on reference conditions of 25°C (77°F), zero (0) static pressure, 10 to 55% RH, and
316L Stainless Steel barrier diaphragm.
** Specification applies to transmitters with 2 seals only. Apply 1.5 times factor to temperature effect for capillary lengths greater than 10 feet
or for 2-inch sanitary seals.
⎛
⎝
⎝
⎝⎛⎝
span in H
span in H
span in H
O
O
2
2
⎞
⎞
⎞
or ±0.275 + 1.2
or ±0.275 + 1.2
⎠
⎠
⎠⎞⎠
O
O
O
2
2
2
500 mbar
500 mbar
⎛
⎛
⎛
⎝
⎝
⎝⎛⎝
span mbar
span mbar
span mbar
⎞
⎞
⎞
In % span
In % span
⎠
⎠
⎠⎞⎠
34-ST-03-57
Page 8
Performance Under Rated Conditions * - Models STR94G (0 to 500 psi/35 bar)
Parameter Description
Upper Range Limit psi
bar
Minimum Span psi
bar
Turndown Ratio
Zero Elevation and Suppression
Accuracy (Reference – Includes
combined effects of linearity,
hysteresis, and repeatability)
Accuracy includes residual error
•
after averaging successive
readings.
• For FOUNDATION Fieldbus use
Digital Mode specifications. For
HART use Analog Mode
specifications.
* Performance specifications are based on reference conditions of 25°C (77°F), zero (0) static pressure, 10 to 55% RH, and
316L Stainless Steel barrier diaphragm.
Minimum recommended span for STR93D DP Transmitter with two Remote Seals
DiaphragmCapillary Length
Minimum recommended span for STR94G or STR93D DP Transmitter with one Remote Seal
Diaphragm Direct Capillary Length
Transmitter Minimum Span and Maximum Capillary Length
No limit except minimum span from absolute 0 (zero) to +100% URL.
In Analog Mode: ±0.10% of calibrated span or upper range value (URV), whichever is
greater, terminal based.
In Digital Mode: ±0.075% of calibrated span or upper range value (URV), whichever
is greater, terminal based.
Capillary
Capillary
Minimum span is the higher of the value from the table above or the value defined under Performance Conditions for the range transmitter
Figure 15— Maximum capillary length and diaphragm size chart.
Performance Under Rated Conditions - General for all Models
Parameter Description
Output (two-wire) Analog 4 to 20 mA or DE digital communications mode. Options available for
OUNDATION Fieldbus and HART protocols.
F
Supply Voltage Effect 0.005% of span per volt.
Damping Time Constant Adjustable from 0 to 32 seconds digital damping.
CE Conformity (Europe) 89/336/EEC, Electromagnetic Compatibility (EMC) Directive.
NAMUR NE 43 Compliance
Option
SIL 2/3 Compliance
Transmitter failure information is generated when the measuring information is invalid or
no longer present. Failure information is transmitted as a current signal but outside the
normal 4-20 mA measurement signal level. Transmitter failure values are:
≤ 3.6 mA and ≥ 21.0 mA. The normal signal range is ≥ 3.8 mA and ≤ 20.5 mA.
SIL certified to IEC 61508 for non-redundant use in SIL 2 related Safety Systems
(single use) and for redundant (multiple) use in SIL 3 Safety Systems through
TÜV Nord Sys Tec GmbH & Co. KG under the following standards: IEC61508-1: 1998;
IEC 61508-2: 2000; IEC61508-3: 1998.
34-ST-03-57
Physical and Approval Bodies
Parameter Description
Process Interface See Model Selection Guide for Material Options for desired Seal Type.
Seal Barrier Diaphragm 316L Stainless Steel, Monel, Hastelloy C, Tantalum
Seal Gasket Materials Klinger C-4401 (non-asbestos)
Grafoil Teflon Gylon 3510
Mounting Bracket Carbon Steel (zinc-plated) or Stainless Steel angle bracket or Carbon Steel flat
15, 20, 25 and 35 feet (1.5, 3, 4.6, 6.1, 7.5 and 10.7m). A 2” (51 millimeter) S.S.
close-coupled nipple is also available. See Model Selection Guide.
Wiring Accepts up to 16 AWG (1.5 mm diameter)
Mounting See Figure 16.
Dimensions See Figures 19 and 20 for transmitter dimensions. See Model Selection Guide for
Seal dimensions
Net Weight Transmitter: 4.1 Kg (9 lbs). Total weight is dependent on seal type and capillary
length.
Approval Bodies
Factory Mutual
Explosion Proof: Approved as Explosion Proof for Class I, Division 1, Groups A,
B, C, D locations,
Dust Ignition Proof: Approved as Dust Ignition Proof for Class II, III, Division 1,
Groups E, F, G locations,
Intrincically Safe: Approved as Intrinsically Safe for for Class I, II, III, Division 1,
Groups A, B, C, D, E, F, G locations.
Nonincendive: Approved as Nonincendivefor Class I, Division 2, Groups A, B, C,
D locations.
CSA
Explosion Proof:
C, D locations,
Dust Ignition Proof: Approved as Dust Ignition Proof for Class II, III, Division 1,
Groups E, F, G locations,
Intrincically Safe: Approved as Intrinsically Safe for Class I, II, III, Division 1,
Approved as Explosion Proof for Class I, Division 1, Groups B,
Groups A, B, C, D, E, F, G locations.
Canadian Registration
Number (CRN)
All ST 3000 model designs, except SATG19L, STG99L, STG170 and STG180
have been registered in all provinces and territories in Canada and are marked
CRN:0F8914.5c.
Intrinsically Safe, Zone 0/1: EEx ia IIC T4, T5, T6
Flameproof/Zone 1: EEx d IIC T5, T6 (enclosure IP 66/67)
ATEX
SA (Australian)
INMETRO (Brazil) Flame-Proof, Zone 1: EX d IIC T5
Non-Sparking, Zone 2: EEx nA, IIC T6 (enclosure IP 66/67)
Multiple Markings:
Intrinsically Safe:
Non-Sparking: Ex n IIC T6 (T4 with SM option)
Ex II 1 G: EEx ia IIC T4, T5, T6, Ex II 2 G: EExd IIC T5, T6
Ex II 3 G: EEx nA, IIC T6 (Honeywell) (enclosure IP 66/67)
EX ia IIC T4
34-ST-03-57
Page 10
Parameter Description
Pressure Equipment Directive
(97/23/EC)
* See Figure 13 for Fill Fluid temperature limits.
** 2-inch Sanitary Seals are limited to 15 ft. (4.6 m) capillary length.
NOTE: Pressure transmitters that are part of safety equipment for the protection of piping (systems) or vessel(s) from
exceeding allowable pressure limits, (equipment with safety functions in accordance with Pressure Equipment Directive
97/23/EC article 1, 2.1.3), require separate examination.
The ST 3000 pressure transmitters listed in this Specification have no pressurized
internal volume or have a pressurized internal volume rated less than 1,000 bar
(14,500 psig) and/or have a maximum volume of less than 0.1 liter. Therefore,
these transmitters are either; not subject to the essential requirements of the
directive 97/23/EC (PED, Annex 1) and shall not have the CE mark, or the
manufacturer has the free choice of a module when the CE mark is required for
pressures > 200 bar (2,900 psig).
LP Side
Maximum level
H2
Fixed
ref. leg
Minimum level
.
HP Side
NOTE: Lower flange seal should not be mounted over 22 feet below the
transmitter for silicone fill fluid (11 feet for CTFE fill fluid) with tank at one
atmosphere. The combination of tank vacuum and high pressure capillary
head effect should not exceed 9 psi vacuum (300 mmHg absolute).
Consult Honeywell for installation of STR93D
Figure 16—Typical mounting arrangement for ST 3000 Transmitter with Remote Diaphragm Seals
Variable
Head
H1
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