ORI-150.1 Jupiter JM4 Sales Brochure

®
JUPITER Model JM4
MAGNETOSTRICTIVE LEVEL TRANSMITTER
HOW
A Versatile, High-Performance Level Measurement Solution
MAGNETOSTRICTION
The Jupiter™ Model JM4 magnetostrictive transmitter can solve challenging
level applications in a variety of ways. With its magnetic-based operating
principle, Jupiter can be directly inserted into the top of a vessel via an
assortment of connection types, or mounted on the outside of a magnetic
level indicator (MLI).
WORKS
1
1
LOW-VOLTAGE PULSE
On-board electronics send a low-voltage electrical pulse
down the magnetostrictive wire at the speed of light, ten
times per second.
STILLING WELL
DUAL-LEVEL
MEASUREMENT
CUSTOM
FLOAT
DESIGN
JUPITER™ ON
ATLAS TOP
MOUNT MLI
2
4
MAGNETS
Magnets contained within the float focus their energy
toward the wire at the precise location of the liquid level.
3
3
2
1
DIRECT
INSERTION
TWIST
Interaction between the magnetic field, electrical pulse,
and magnetostrictive wire cause a slight mechanical
disturbance in the wire that travels back up the probe at
the speed of sound.
JUPITER™
MOUNTED
ON MLI
JUPITER™ IN
EXTERNAL
CHAMBER
4
PIEZOELECTRIC CRYSTALS
The mechanical wave is converted back into electrical
energy by two piezoelectric crystals. The on-board
electronics interpret the time-of-flight data and indicate
the position of the float magnets.
2
±0.05”
HIGH ACCURACY MEASUREMENT
In an era of technologically advanced “smart” instruments, plants
and operators are investing and placing more reliance in device
networks which deliver reliable level measurement with a high
degree of accuracy.
The Jupiter magnetostrictive level transmitter is capable of
measuring with an impressive accuracy of ±0.05 inches (1.3
mm), allowing facilities tighter level tolerances, optimizing their
process operations and generating greater ROI.
SAFER
In addition, such features as non-volatile
event history information, hot swappable
control modules, configurable alarm delays
and context sensitive help screens and
parameters makes this one of the easiest
transmitters on the market to work with.
2
3
A first among magnetostrictive devices, Jupiter
revolutionizes installation options and flexibility with a
transmitter head which can rotate up to 310 degrees,
drastically improving LCD visibility and access to the
user interface in hard-to-reach places. In addition, a
removable head minimizes installation challenges,
permits interchangeability without breaching the
process seal, and allows for remote transmitter
placement.
SIMPLER
Jupiter possesses a comprehensive array
of advanced diagnostics and real-time
performance monitoring which make gathering
transmitter insight faster and easier than ever
before. With profound focus on SIS (Safety
Instrumented Systems), Jupiter was developed
with SSA (Safety Suitable Architecture), as well
as memory protection hardware & software.
FEATURES
REMOVABLE & ROTATABLE TRANSMITTER HEAD
1.3mm
With the goal of simplifying interaction with the
transmitter, Jupiter was designed with the user
in mind:
• User-friendly local push-button interface
allows for easier and more intuitive
navigation
• Bottom-mount option improves
accessibility for many MLI installations
• 310° head rotation enhances line-of-sight
to the display
• Advanced EDDL and DTM capability make
remote interaction with Jupiter very effective for
configuration and diagnostic purposes
SMARTER
Orion introduces auto-configuration to
magnetostrictive technology with Jupiter’s
new Smart Probe. When the transmitter
head connects to a probe for the first time,
configuration settings stored within the probe’s
memory are instantly transferred. In addition,
parameters critical to the instrument’s
calibration are transferred as well,
eliminating the need for Jupiter
to be manually calibrated
in the field. This unique
capability expedites the
setup process and simplifies
the task of installing spare
transmitter heads on existing
or replacement probes.
REMOTE MOUNT OPTION
IDEAL FOR INSTALLATION SPACE CONSTRAINTS
45° ANGLED ENCLOSURE
CONVENIENT VISIBILITY & ACCESSIBILITY
4
BUOYANCY
A VERSATILE SOLUTION FOR A VARIETY OF APPLICATION CHALLENGES
Buoyancy-based technologies have been utilized in the process instrumentation
world for generations and are widely considered to provide reliable, accurate level
measurement in an extensive range of applications and service conditions.
A SIMPLE, FEATURE-RICH USER INTERFACE
Jupiter capitalizes on the benefits of
buoyancy such as ease of installation,
minimized configuration, ability to
check calibration either by moving the
float or utilizing an external magnetic
field, customization of float size/shape/
materials, and high pressures. With the
amazing accuracy of Jupiter, cost-toaccuracy ratio exceeds virtually any other
comparable technology.
Jupiter™ takes the user experience to new levels of convenience and functionality with an information-rich display and an easy-to-navigate
menu. With the new graphic LCD, waveforms are viewable locally at the device. You can also interface with Jupiter via a capable DCS or
handheld communicator that utilize DDs/EDDL for remote connectivity.
A fully redesigned and upgraded DTM puts real-time and historical trend data at your fingertips. With a basic laptop,
a HART modem, and the free-to-download program PACTware™, the transmitter can be accessed locally or from
anywhere in the loop. You can also
capture live waveforms, which are
invaluable
when
configuring
the
transmitter for optimal performance.
.
OPTIONS
Sun Shade
5
Interface & Emulsions
Foaming
Media Buildup
Given the long and successful use of buoyancy based devices
in the process world, the synergistic combination of Jupiter’s
buoyancy with 4th generation electronics is the starting point
for superior performance in interface applications. With precise
weighting of the float to customer specifications, emulsion
layers pose no problem since the float will sink all the way to
the lower liquid layer. Even mild to moderate fluctuations in
media specific gravity will have limited impact on float position
creating greater reliability and less chance for complete loss of
signal with other strictly electronic measurements.
Foam can be a surprising and unwelcome
process condition to many applications. Unlike
many other electronic level technologies,
Magnetostriction, with its float-based principle,
is not as vulnerable to signal loss given the
known or unexpected presence of foam. Since
the float is intended to operate in much denser
media, the foam will not inhibit or restrict the
float from finding its correct equilibrium.
Many applications which are prone to increase the risk
of coating and buildup can hinder the effectiveness of
level measurement. Magnetostrictive floats can be sized
to achieve substantial buoyancy force, overcoming the
added resistance. Floats and chambers can also be
coated in a variety of low-friction polymers to reduce
the adhesion coefficient making certain processes
and media suitable for Jupiter. In addition, given
the customizable nature of magnetostrictive floats,
accommodations can be made for additional safety gap
margins between the float and the transmitter probe to
allow for extra clearance.
• Reduces glare and radiant heating of the transmitter
enclosure. Also minimizes impact of direct solar
radiation to the graphic liquid crystal display.
Vibration Kit
Centering Disc (direct insertion model)
• Silicone-based damping material eliminates
metal-on-metal contact between the probe and the
chamber
• Increases signal stability in high vibration
applications by reducing mechanical noise.
• The centering disk is an invaluable
aid when utilizing the Jupiter in
a direct insertion environment,
such as a stilling well or modular
instrumentation bridle (MIB). By
keeping the transmitter probe
centered in the MIB, potential for
impingement is mitigated.
6
JUPITER MODEL JM4 LEVEL TRANSMITTER | SPECIFICATIONS
System Design
Performance
Magnetostriction-based mechanical response signal
Measurement Principle
Input
Linearity
0.030 in. (8 mm) or 0.01% of probe length, whichever is greater
Accuracy
±0.01% full scale or ±0.05 in (1.3 mm), whichever is greater
Measured Variable
Level, response signal time of flight
Resolution
.014” (.4 mm)
Span
6 inches to 400 inches (15 cm to 999 cm)
Repeatability
±0.005% of full span or 0.014 in, whichever is greater
Response Time
1 second
4 to 20 mA with HART: 3.8 mA to 20.5 mA usable (per NAMUR NE43)
Initialization Time
Less than 10 seconds
Foundation fieldbus : H1 (ITK Ver. 6.1.1)
Ambient Temperature Effect
Approx. ±0.02% of probe length/degree C
0.003 mA
Execution Time
15 msec (30 msec PID, Signal Characterizer Block)
Output
Type
TM
Resolution
Analog:
Digital Display:
1 mm
Loop Resistance
591 ohms @ 24 VDC and 22 mA
Diagnostic Alarm
Selectable: 3.6 mA, 22 mA (meets requirements of NAMUR NE 43), or HOLD last output
Damping
Adjustable 0-10 seconds
User Interface
Keypad
4-button menu-driven data entry
Display
Graphic liquid crystal display with viewable echo curve
Digital Communication
HART Version 7­—with Field Communicator, Foundation fieldbusTM,
DTM (PACTwareTM), AMS, FDT, EDDL
Menu Languages
ITK Version
6.1.1
H1 Device Class
Link Master (LAS)—selectable ON/OFF
H1 Profile Class
31PS, 32L
Function Blocks
(6) Al, (2) Transducer, (1) Resource, (1) Arithmetic, (1) Input Selector, (1) Signal Characterizer, (2) PID, (1) Integrator
Quiescent Current
15 mA
Execution Time
15 msec (30 msec PID, Signal Characterizer Block)
Transmitter LCD: English, French, German, Spanish, Russian, Portuguese
HART DD: English, French, German, Spanish, Russian, Chinese, Portuguese
Foundation fieldbus
Power (at transmitter terminals)
Foundation fieldbusTM
TM
Host System: English
Environment
Ambient Temperature Range
Transmitter:
Display:
HART: General Purpose (Weather proof)/Intrinsically Safe/Explosion-proof: 16 to 36 VDC
11 VDC minimum under certain conditions (refer to IO manual section 2.5.5)
-50° to +185°F (-45°C to +85°C)
FOUNDATION fieldbus™: FISCO 9 to 17.5 VDC
Process Pressure (Direct Insertion)
Vacuum to 3000 psig (207bar)
FISCO, FNICO, Explosion Proof, General Purpose (Weather Proof): 9 to 32 VDC
Humidity
0 to 99%, non-condensing
Electromagnetic Compatibility
Meets CE requirement (EN 61326) and NAMUR NE 21
1136 Ω
R Loop
Material
IP67/die cast aluminum A413 (<0.6% copper); optional 316 stainless steel
Surge Protection
Meets CE EN 61326 (1000V)
591 Ω
Net/Gross Weight
Aluminum: 4.5 lbs. (2.0 kg)
Shock/Vibration
ANSI/ISA-S71.03 Class SA1 (Shock);
ANSI/ISA-S71.03Class VC2 (Vibration)
360 Ω
Stainless Steel: 10.0 lbs. (4.50 kg)
Overall Dimensions
Transmitter Head: H 8.34” (212 mm) x W 4.03” (102 mm) x D 7.56” (192 mm)
Cable Entry
1/2” NPT or M20
PROCESS CONDITIONS
SIL 2 Hardware (Safety Integrity Level)
Safe Failure Fraction = 93.1% for Single Float version, 91.9% for Dual Float version (HART only)
Process Temperature
Functional Safety to SIL 2 as 1oo1 in accordance with IEC 61508
(Full FMEDA report available upon request)
7
-5° to +176°F (-20°C to +80°C)
Storage Temperature
Housing
Safe Operating Area
-40° to +176°F (-40°C to +80°C)
Process Pressure
External Mount:
-320°F (-196°C) to +850°F (450°C)
Direct Insertion:
-320°F (-196°C) to 800°F (425°C)
Direct Insertion:
Vacuum to 3000 psig (207bar)
Digital Solar Mode
0
Typical HART
4-20 mA
Operating Area
16.25 V 18.9 V 24 V
36 V
Vsupply (Loop Supply Voltage)
8
JUPITER JM4 MODEL NUMBER | TRANSMITTER HEAD
PHYSICAL DIMENSIONS
J M 4
DIRECT INSERTION
1
EXTERNAL MOUNT
A
E
B
F
3
3
3
3
2
2
2
2
9
9
9
9
6
6
6
6
3
3
1
1
ft.
ft.
9
9
9
9
6
6
6
6
3in.
3in.
3in.
3in.
0
0
0
ft.
ft.
5
6
7
8
9
10
9 HOUSING
1
4-20 mA with HART
1
Aluminum, Dual-Compartment
2
Foundation Fieldbus Communications
2
316 SS, Dual-Compartment
6 SAFETY OPTIONS
ft.
4
C
ft.
ft.
D
C
ft.
E
0
dashed line represents cryogenic insulation
21.00
[533]
3
5 SIGNAL OUTPUT
D
17.00
[432]
2
5
0
None
1
SIL 2 Hardware
10 CONDUIT CONNECTION & SUNSHADE OPTION
required for FOUNDATION fieldbus™
SEE NOTE 1
7 ACCESSORIES/MOUNTING
0
No Digital Display and Keypad- Integral
1
No Digital Display and Keypad - Remote 36” (0.91m)
SEE NOTE 2
2
No Digital Display and Keypad - Remote 144” (3.6m)
SEE NOTE 2
A
Digital Display and Keypad - Integral
B
Digital Display and Keypad - Remote 36” (0.91m)
SEE NOTE 2
C
Digital Display and Keypad - Remote 144” (3.6m)
SEE NOTE 2
0
1/2” NPT
1
M20
2
1/2” NPT with Sunshade
3
M20 with Sunshade
Transmitter Head Dimensions
3.97
3.39
4.18
[101]
[86]
[106]
3.78
8 AREA CLASSIFICATION
F
19.00
[483]
23.00
[584]
Dimensions
inches [mm]
Configuration
Top Mount
A = 16.4 [417]
Top Mount Hi-Temp/Cryogenic
B = 20.4 [518]
Offset Mount
9
General Purpose, Weatherproof (IP 67)
1
Intrinsically Safe / FISCO (cFMus)
3
Explosion-Proof / FNICO (cFMus)
A
Intrinsically Safe (ATEX & IEC)
B
Flame-Proof (ATEX & IEC) approvals pending -- inquire for availability
C
Ex n (ATEX & IEC)
D
Dust Ex (ATEX & IEC)
1
FISCO Field Device (cFMus)
3
Explosion-Proof & FNICO Field Device (cFMus)
[96]
10.05
[255]
45°
8.35
5.10
NOTES:
C = 8 [203]
D = 12.7 [323]
E = 16.6 [422]
F = 16.5 [419]
1
Cryogenic Offset Mount
0
2
Inches
[mm]
[212]
[130]
3rd Party FMEDA report available
Remote-mount transmitter not available with XP / Flame Proof approvals
10
JUPITER JM4 MODEL NUMBER | EXTERNAL MOUNT PROBE
2
1
2
3
4
5
6
7
8
0
9
10
0 0
11
12
13
14
2
15
1
2 MEASUREMENT SYSTEM
A
English
C
Metric
3 CONFIGURATION
F
STANDARD Top Mount Offset
H
STANDARD Bottom Mount Offset
K
HIGH-TEMP Top Mount
L
HIGH-TEMP Top Mount Offset
M
HIGH-TEMP Bottom Mount Offset
R
CRYOGENIC Top Mount
S
CRYOGENIC Top Mount Offset
T
CRYOGENIC Bottom Mount Offset
suitable for process temperatures
-40° F to +500° F
(-40° C to +260° C)
Left-Side MLI Mount
01
Right-side MLI Mount
suitable for process temperatures
+501° F to +850° F
(+261° C to +454° C)
suitable for process temperatures
-320° F to +150° F
(-196° C to +66° C)
Left side
mount
(standard)
Right side
mount
316 SS Sensor Enclosure with 316 SS Probe
None
V
Vibration-resistant probe mounting
Cryogenic Offset (316 SS only)
1
N
7
8
9
10
11
12
13
14
15
2” (or if digit 20 of MLI model code is 1, 2, or 7)
2
2 1/2” or if digit 20 of MLI model code is 3, 4, 5, or 6)
3
3” (or if digit 20 of MLI model code is A, B, C, or D)
4
4” (or if digit 20 of MLI model code is E, F, G, H, or J)
5
3/4” (for Atlas Top Mount Configuration only)
0
None. No mounting clamps required.
E
2” (or if digit 20 of MLI model code is 1, 2, or 7)
F
2 1/2” or if digit 20 of MLI model code is 3, 4, 5, or 6)
G
3” (or if digit 20 of MLI model code is A, B, C, or D)
H
4” (or if digit 20 of MLI model code is E, F, G, H, or J)
J
3/4” (for Atlas Top Mount Configuration only)
0
None. No mounting clamps required.
FLOAT
Probe mounting positions on
Atlas™, Vector™, and Gemini™
Magnetic Level Indicators
Probe mounting positions
on Aurora® MLI
Probe proximity to the float is critical
None
10 LEVEL/INTERFACE MEASUREMENT PREFERENCE
Offset (Aluminum or 316 SS)
Powder-Coated Aluminum Sensor Enclosure with 316 SS Probe SEE NOTE1
7 PROBE OPTIONS
1
0
Top Mount (316 SS only)
A
Only available with Digit 3, Options F, H, L, M
6
9 UNUSED
6 PROBE MATERIAL OF CONSTRUCTION
1
5
Select these options if chamber DOES contain high-temp insulation
4&5 MOUNTING SIDE
00
4
Select these options if chamber DOES NOT contain high-temp insulation
Probe length to be provided in centimeters
STANDARD Top Mount
3
0 0
8 CHAMBER SIZE (FOR MOUNTING HARDWARE)
Probe length to be provided in inches
E
2
0
Sensor Enclosures (shaded)
refer to Model Code digit 6
1
Measure Only the Total Liquid Level
2
Measure Only the Interface Level
3
Measure Both Total and Interface Level
11,12 UNUSED
00
None
13-15 PROBE LENGTH
Specify required insertion length. See right.
Example: 87 inches = 087
XXX
Code 2 must be "A"
Example: 120 centimeters = 120
Code 2 must be “C”
Top/Bottom Mount Offset Configuration
Top Mount Configuration
Probe Length = Center-to-Center + 6 in. (15 cm)
Probe Length = Center-to-Center + 8 in. (20 cm)
Note: Maximum Probe Length = 400 inches (999 cm)
11
12
JUPITER JM4 MODEL NUMBER | DIRECT INSERTION PROBE
2
1
2
3
4
5
6
N
7
8
9
10
11
12
13
14
2
15
1
2 MEASUREMENT SYSTEM
A
English
C
Metric
probe length to be provided in centimeters
Probes designed for high-temp and
cryogenic process temperatures contain
an extended neck to reduce thermal
stress on critical probe components.
3 CONFIGURATION
Standard
2
High-Temperature
8
Cryogenic
suitable for process temperatures between -40° F to +500° F (-40° C to +260° C)
Be aware of overhead clearance at the
desired installation location.
suitable for process temperatures between +501° F to +800° F (+261° C to +425° C)
4
5
6
7
8
9
10
11
12
13
14
15
316 SS
B
Hastelloy® C276
C
Monel® 400
L
316 SS w/Teflon®-S coating on probe tubing and float
P
316 SS w/PFA coating on probe tubing and float
7 UNUSED
THREADED (MALE)
3/4” NPT
22
1” BSP
41
2” NPT
42
2” BSP
None
8 INSTALLATION CONSIDERATIONS
4&5 PROCESS CONNECTION SIZE & TYPE (Select from below)
11
Standard
ANSI FLANGES
N
Direct Insertion unit mounted in vessel without stilling well.
C
Direct Insertion unit mounted in chamber, bridle, or stilling well.
0
Industrial Grade
K
ASME B31.1
2” 150# Raised Face
53
3” 150# Raised Face
63
4” 150# Raised Face
L
ASME B31.3
44
2” 300# Raised Face
54
3” 300# Raised Face
64
4” 300# Raised Face
M
ASME B31.3 & NACE MR0103/MR0175
45
2” 600# Raised Face
55
3” 600# Raised Face
65
4” 600# Raised Face
N
Industrial Grade & NACE MR0103/MR0175
47
2” 900/1500# Raised Face
56
3” 900# Raised Face
66
4” 900# Raised Face
57
3” 1500# Raised Face
67
4” 1500# Raised Face
DN 80 : PN 16 Type A
FA
DN 100 : PN 16 Type A
CC
DN 40 : PN 63/100 Type B2
EB
DN 80 : PN 25/40 Type A
FB
DN 100 : PN 25/40 Type A
DA
DN 50 : PN 16 Type A
ED
DN 80 : PN 63 Type B2
FD
DN 100 : PN 63 Type B2
DB
DN 50 : PN 25/40 Type A
EE
DN 80 : PN 100 Type B2
FE
DN 100 : PN 100 Type B2
DD
DN 50 : PN 63 Type B2
FF
DN 100 : PN 160 Type B2
DE
DN 50 : PN 100 Type B2
FG
DN 100 : PN 250 Type B2
Note: Maximum Probe Length = 400 inches (999 cm)
10 LEVEL/INTERFACE MEASUREMENT PREFERENCE
EN 1092-1 FLANGES
EA
Specify required insertion length. See figures to the right.
XXX Example: 87 inches = 087 Code 2 must be "A"
Example: 120 centimeters = 120 Code 2 must be “C”
9 CONSTRUCTION CODE
43
DN 40 : PN 16/25/40 Type A
See next page for our standard direct insertion float offerings. If a
listed float does not meet your application requirements, consult
factory for a custom design.
High-Temp &
Cryogenic Models
CB
11&12 MAGNETIC FLOAT(S)
13-15 PROBE LENGTH
Dimensions can be found on page 9
suitable for process temperatures between -320° F to +150° F (-196° C to +66° C)
A
N
13
3
6 MATERIAL OF CONSTRUCTION wetted materials only
probe length to be provided in inches
1
2
N
1
Measure Only the Total Liquid Level
2
Measure Only the Interface Level
3
Measure Both Total and Interface Level
Units mounted in stilling wells or chambers are
provided with centering discs at the base of the probe
Threaded
Flanged
14
JUPITER JM4 MODEL NUMBER | DIRECT INSERTION FLOAT SELECTION
Direct Insertion Total Level Float (uppermost liquid layer)
Float Dimensions
Minimum Liquid
Specific Gravity
316/316L SS
Titanium
Hastelloy® C
Hygienic Service
316/316L SS
SF1: 20 µin (0.51 µm)
Hygienic Service
316/316L SS
SF4: 15 µin (0.38 µm)
≥ 0.86
AA
2.0" (51 mm) dia.
BA
2.0" (51 mm) dia.
CA
1.85" (47 mm) dia.
DA
2.0" (51 mm) dia.
AA
2.0" (51 mm) dia.
BA
2.0" (51 mm) dia.
CB
2.25" (57 mm) dia.
≥ 0.7
AB
2.3" (58 mm) dia.
BA
2.0" (51 mm) dia.
≥ 0.68
AB
2.3" (58 mm) dia.
≥ 0.64
AC
2.5" (64 mm) dia.
≥ 0.83
Float
Code
Dim. A
in. (mm)
Dim. B
in. (mm)
Dim. C
in. (mm)
FA
2.0" (51 mm) dia.
AA,DA,FA
2.0 (51)
2.7 (69)
1.84 (47)
AB,DB,FB
2.3 (58)
3.0 (76)
2.0 (51)
DA
2.0" (51 mm) dia.
FA
2.0" (51 mm) dia.
AC,DC,FC
2.5 (64)
3.0 (76)
2.14 (54)
BA
2.0 (51)
2.8 (71)
1.98 (50)
CB
2.25" (57 mm) dia.
DB
2.3" (58 mm) dia.
FB
2.3" (58 mm) dia.
BB
2.25 (57)
3.0 (76)
CA
1.85 (47)
BB
2.25" (57 mm) dia.
99
consult factory
DB
2.3" (58 mm) dia.
FB
2.3" (58 mm) dia.
CB
BB
2.25" (57 mm) dia.
99
consult factory
DC
2.5" (64 mm) dia.
FC
2.5" (64 mm) dia.
≥ 0.52
99
consult factory dia.
BB
2.25"(57 mm) dia.
99
consult factory
99
consult factory dia.
99
consult factory dia.
< 0.52
99
consult factory
99
consult factory
99
consult factory
99
consult factory
99
consult factory
Reference the chart below to identify an appropriate chamber or stilling well size for your
application. Adequate clearance is recommended to ensure proper float operation.
Sizing Chart for Chambers & Stilling Wells
Float
Diameter
Probe Lengths >
144 in (366 cm)
Probe Lengths ≤ 144 inches (366 cm)
inches (mm)
3"
sch. 5/10
3"
sch. 40
4"
sch. 5/10
4"
sch. 40
4"
sch. 80
4"
sch. 160
4"
sch. 10
4"
sch. 40
2.08 (53)
1.85 (47)








3.0 (76)
2.06 (52)
2 (51)







2.25 (57)
4.3 (109)
3.01 (76)
2.3 (58)



MA,QA,RA
2.0 (51)
2.7 (69)
1.35 (34)
2.5 (64)


MB,QB,RB
2.0 (51)
2.7 (69)
1.35 (34)
3 (76)
NA
2.0 (51)
2.8 (71)
1.4 (36)
NB
2.0 (51)
2.8 (71)
1.4 (36)
PA
1.85 (47)
3.0 (76)
1.5 (38)
PB
1.85 (47)
3.0 (76)
1.5 (38)
Temp
ºF (ºC)

Pressure Rating (includes 1.5x safety factor)
psig (bar)
AA, AB, AC, MA, MB
DA, DB, DC, QA,
BA, NA, NB
QB
FA, FB, FC, RA, RB
Direct Insertion Interface Level Float (lower or middle liquid layer)
Minimum Liquid
Specific Gravities
upper / lower
sinks thru
≤ 0.89
floats on
/
sinks thru
≤ 1.00
≥ 1.00
floats on
/
≥ 1.12
316/316L SS
Titanium
Hastelloy® C
Hygienic Service
316/316L SS
SF1: 20 µin (0.51 µin)
Hygienic Service
316/316L SS
SF4: 15 µin (0.38 µin)
MA
2.0" (51 mm) dia.
NA
2.0" (51 mm) dia.
PA
1.85" (47 mm) dia.
QA
2.0" (51 mm) dia.
RA
2.0" (51 mm) dia.
MB
2.0" (51 mm) dia.
NB
2.0" (51 mm) dia.
PB
1.85" (47 mm) dia.
QB
2.0" (51 mm) dia.
RB
2.0" (51 mm) dia.
DIM. "B"
HEIGHT
Two Floats for Total Level and Interface Measurement
Code
11
12
13
21
22
23
31
15
Total
AA
AB
AC
AA
AB
AC
BA
Interface
MA
MB
NA
Code
32
41
42
51
52
61
62
DIM "A"
DIAMETER
Total
BB
BA
BB
CA
CB
CA
CB
Interface
NA
NB
PA
PB
When utilizing two floats to measure total and
interface liquid levels, reference the chart on the left
to determine the appropriate float code to insert into
the Jupiter model number.
If the desired combination is not shown, consult your
local sales representative or Orion to inquire about a
custom float deisgn.
DIM. "C"
MAGNET LOCATION
(Submergence Depth)
BB
CA, PA, PB
CB
70 (20)
440 (30.3)
750 (51.7)
400 (27.6)
340 (23.4)
320 (22.1)
100 (40)
440 (30.3)
709 (48.9)
378 (26.1)
340 (23.4)
320 (22.1)
200 (95)
440 (30.3)
559 (38.5)
298 (20.6)
340 (23.4)
320 (22.1)
250 (120)
427 (29.4)
494 (34.0)
263 (18.2)
340 (23.4)
320 (22.1)
300 (150)
411 (28.4)
437 (30.1)
233 (16.1)
340 (23.4)
320 (22.1)
350 (175)
433 (29.9)
386 (26.6)
206 (14.2)
340 (23.4)
320 (22.1)
400 (200)
427 (29.4)
341 (23.5)
182 (12.6)
340 (23.4)
320 (22.1)
450 (230)
411 (28.4)
303 (20.9)
162 (11.1)
337 (23.2)
318 (21.9)
500 (260)
396 (27.3)
273 (18.8)
146 (10.0)
335 (23.1)
315 (21.7)
550 (290)
385 (26.5)
250 (17.2)
133 (9.2)
326 (22.5)
306 (21.1)
600 (315)
374 (25.8)
232 (16.0)
124 (8.5)
316 (21.8)
298 (20.5)
650 (345)
367 (25.3)
217 (14.9)
116 (8.0)
308 (21.2)
289 (19.9)
700 (370)
361 (24.9)
205 (14.1)
109 (7.5)
299 (20.6)
281 (19.4)
750 (400)
356 (24.6)
192 (13.2)
102 (7.1)
296 (20.4)
278 (19.2)
800 (425)
352 (24.3)
177 (12.2)
94 (6.5)
293 (20.2)
276 (19.0)
16
HAZARDOUS LOCATION APPROVALS
Agency
Protection Method
Area Classification
Explosion Proof
Class I, Div 1, Group B, C and D, T4 Ta = -40ºC to +70ºC
Type 4X, IP67
Class I, II, III, Div 1, Group A, B, C, D, E, F, G, T4
Class I, Zone 0 AEx ia IIC T4 Ga
Class I, Zone 0 Ex ia IIC T4 Ga
Ta =-40ºC to + 70ºC
Type 4X, IP67
U.S.: Class I, II, III, Division 2, Group A, B, C, D, E, F, G, T4, Ta = -40ºC to 70ºC
CANADA: Class I, Division 2, Group A,B,C,D T4, Ta = -40ºC to 70ºC
Class I, Zone 2 AEx nA IIC T4 Gc Ta = -15ºC to 70ºC
Class I, Zone 2 Ex nA IIC T4 Gc Ta = -15ºC to +70ºC
Type 4X, IP67
Class II, III, Division 1, Group E, F and G, T4 Ta = -40ºC to +70ºC
Type 4X, IP67
Pending -- inquire for availability
II 1 G Ex ia IIC T4 Ga Ta = -40ºC to +70ºC
IP67
II 3 G Ex nA IIC T4 Gc
Ta = -15ºC to +70ºC
IP67
II 2 D Ex tb IIIC T85ºC … T120ºC Db
Ta = -15ºC to +70ºC
IP67
Pending -- inquire for availability
Ex ia IIC T4 Ga
Ta = -40ºC to +70ºC
IP67
Ex nA IIC T4 Gc
Ta = -15ºC to + 70ºC
IP67
Ex tb IIIC Db T85ºC … T120ºC Db
Ta = -15ºC to +70ºC
IP67
Intrinsically Safe
Non-Incendive
Dust Ignition Proof
Flame Proof
Intrinsically Safe
ATEX
Non Sparking
Dust Ignition Proof
Flame Proof
Intrinsically Safe
Non Sparking
Dust Ignition Proof
THE FOLLOWING APPROVAL STANDARDS ARE APPLICABLE:
FM3600:2011,
FM3610:2010,
FM3611:2004,
FM3615:2006,
FM3616:2011,
FM3810:2005,
ANSI/ISA60079-0:2013,
ANSI/ISA
60079-1:2009,
ANSI/ISA
60079-11:2013,
ANSI/ISA 60079-15:2012, ANSI/ISA 60079-26:2011, NEMA 250:2003, ANSI/IEC 60529:2004, C22.2 No. 0.4:2009, C22.2 No. 0.5:2008 C22.2 No. 30:2007 C22.2 No. 94:2001,
C22.2
No.
157:2012,
C22.2
No.
213:2012
C22.2
No.
1010.1:2009
CAN/CSA
60079-0:2011
CAN/CSA
60079-1:2011
CAN/CSA
60079-11:2011
CAN/CSA
60079-15:2012
C22.2 No. 60529:2005 EN60079-0:2012, EN60079-11:2012 EN60079-15:2010 EN60079-31:2009 EN60529+A1:1991-2000 IEC60079-0:2011 IEC60079-11:2011 IEC60079-15:2010 IEC60079-31:2008
SPECIAL CONDITIONS FOR SAFE USE:
1. The enclosure contains aluminum and is considered to present a potential risk of ignition by impact or friction. Care must be taken during installation and use to prevent impact or friction. 2. To maintain
the T4 temperature code care shall be taken to ensure the enclosure temperature does not exceed 70ºC. 3. The risk of electrostatic discharge shall be minimized at installation, following the direction given in
the instruction. 4. For Installation with ambient temperature of 70ºC, refer to the manufacturer’s instructions for guidance on proper selection of conductors. 5. Provisions shall be made to provide transient
overvoltage protection to a level not to exceed 119Vdc. 6. WARNING – Explosion Hazard do not disconnect equipment when flammable or combustible atmosphere is present 7. When equipment is used in
explosive dust atmospheres, the end user shall take precautions so that the thermal effects of the process temperature shall limit the equipment enclosure and probe surface temperatures to not exceed the
required installation location temperature and shall be between T85ºC and T120ºC.
NOTES:
1. For Explosion proof installations the I.S. ground terminal shall be connected to appropriate intrinsically safe ground in accordance with the Canadian Electrical code (CEC) or the national electrical code (NEC).
For intrinsically safe installations the I.S. ground terminal does not require grounding. 2. Manufacturer’s installation instructions supplied with the protective barrier and the CEC or the NEC must be followed
when installing this equipment. Barrier must be certified for Canadian & U.S. installation. 3. Control equipment connected to protective barriers must not use or generate more than 250 VDC or VRMS. 4. Agency
approved dust tight seals must be used when transmitter is installed in Class II & III environments. 5. For supply connections, use wire suitable for the operating temperature. 6. Agency approved barriers with
linear output characteristics must be used.
These units are in compliance with the EMC directive 2004/108/EC,
the PED directive 97/23/EC and the ATEX directive 94/9/EC.
17
18
2105 Oak Villa Blvd. | Baton Rouge, LA 70815
office 225.906.2343 | fax 225.906.2344 | [email protected]
www.orioninstruments.com
Bulletin: ORI-150.1
Effective: February 2016