MAGNETROL 384-2K00-003

Echotel® Models 344/345
Ultrasonic Non-Contact
Transmitters for Level,
Volume, or Open Channel Flow
D E S C R I P T I O N
Echotel® Models 344 and 345 are full-featured, ultrasonic
non-contact transmitters that provide continuous measurement for liquid level, volume, or open channel flow
applications. These versatile transmitters utilize the
latest in microprocessor-based electronics along with
powerful non-contact ultrasonic transducers, to provide
level measurement that is not affected by changes in
specific gravity, viscosity, or conductivity.
Model 344 and 345 are remote mounted transmitters
that feature a front panel keypad, and a large
16-character alphanumeric display of all parameters.
These transmitters are paired up with Kynar® and
316 stainless steel EchoMaster™ Ultrasonic Transducers
that have extensive agency approvals for hazardous
area locations.
F E A T U R E S
• Front panel keypad for ease of programming – no
need to open enclosure after wiring
• 4–20 mA isolated (1,000 Ω load) and RS-232 outputs
• Four 10 amp SPDT relays allow for simple alarm
configurations to complex pump control including
lead/lag alternation of pumps
• Password code prevents unauthorized tampering of
calibration parameters
A P P L I C A T I O N S
• 16-character alphanumeric display of all parameters.
• Water and wastewater
• Complete self-diagnostics assures unit is operating
properly by checking all relays, outputs, and system
functionality
• Temperature compensation integral to all ultrasonic
transducers
• Slurries
• Viscous fluids
• Fuel oils
• Acids
• False target buffering eliminates signal interference
from fixed obstructions in vessel
• Caustics
T E C H N O L O G Y
Model 344 and 345 systems consists of three main components: an ultrasonic transducer, a transmitter, and an
interconnecting cable package.
returned to the transducer. The piezoelectric crystal then
converts the returned echo into an electrical signal which
is analyzed by the transmitter. The elapsed time between
the generation of the ultrasonic pulse and the return echo
is proportional to the distance between the face of the
transducer and the liquid surface. The distance value is
used by the transmitter to compute level, volume, or flow
in the engineering units selected by the user.
The transducer contains a piezoelectric crystal that converts electrical signals generated by the transmitter into
ultrasonic pulses. These pulses, or sound waves, are
directed through the air toward the liquid surface. They
are then reflected off the liquid surface as an echo, and
E C H O M A S T E R
T R A N S D U C E R
EchoMaster transducers are available in a wide variety of
configurations to accommodate a broad range of industrial and municipal applications. The 344 uses the powerful
38 kHz Model 384 Kynar transducer, and is primarily used
for level and volume applications. The 345 uses the
Operating
Frequency
38 kHz
50 kHz
Model 384
Model 385
T Y P I C A L
50 kHz Model 385 transducer that is available in either
Kynar or 316 stainless steel. The higher frequency 50 kHz
transducer makes the 345 well suited for open channel
flow, and shorter range applications.
Insertion
Lengths
3" & 10"
3", 6", & 10"
Material
Kynar
Kynar or 316 SS
M O U N T I N G
NPT Process
Connection
1" or 2"
3
⁄4" or 2"
Housing
none, aluminum, or
316 stainless steel
C O N F I G U R A T I O N S
In Figure 1, the transducer is installed above the liquid
surface, and the transmitter is mounted as far as 500 feet
(152 meters) away. A minimum dead band distance must
be allowed between the face of the transducer and the
maximum level attainable. This dead band distance is
18 inches (460 mm) for the Model 384 transducer, and
12 inches (305 mm) for the Model 385 transducer.
Transducer
Dead Band
Air
Model 345
25 feet (7.6 m)
maximum
Minimum Model 344: 18 inches (460 mm)
Model 345: 12 inches (305 mm)
Range
Model 344
35 feet (10.7 m)
maximum
Span
Liquid
Maximum Model 345: 24 feet (7.3 m)
Model 344: 33.5 feet (10.2 m)
Figure 1
Typical Transducer Mounting – Level/Volume
2
T Y P I C A L
M O U N T I N G
Figure 2 shows a typical transducer mounting on a bracket for open channel flow measurement. Figure 3 shows
how the transducer can often be mounted further down in
a wet well or sump if the liquid will never reach the top
Electronics
C O N F I G U R A T I O N S
of the vessel. This helps to keep the 12 degree ultrasonic
beam away from pumps, ladders, side walls, or other
obstructions in the vessel.
Transducer
Flow
Parshall
Flume
Figure 2
Figure 3
Typical Transducer Mounting – Open Channel Flow
Typical Transducer Mounting – Wet Well or Sump
U L T R A S O N I C
B E A M
A 12° conical beam of ultrasonic energy is emitted from
the face of the transducer. The transducer should be
mounted in a location such that the ultrasonic signal does
not touch the side walls or any other obstructions in the
vessel. This is typically accomplished by using a bracket,
half-coupling, or rigid conduit to mount the transducer in
a spot where a strong echo can be received off of the
A N G L E
liquid surface. The chart below shows the distance the
transducer should be located away from side walls and
obstructions. The distances are based on a 6° beam radius
at different heights above the liquid surface. Generally
speaking, the transducer should be mounted one foot
away for every 10 feet of height.
Distance from
Transducer Face (feet)
12° Beam
Diameter (feet)
Minimum Distance from
Wall or Obstruction (inches)
3'
6'
9'
12'
15'
18'
21'
24'
27'
30'
33'
0.6'
1.3'
1.9'
2.5'
3.2'
3.8'
4.4'
5.0'
5.7'
6.3'
6.9'
4"
8"
11"
15"
19"
23"
26"
30"
34"
38"
42"
3
F A L S E
T A R G E T
D E T E C T I O N
When it is impossible to mount the transducer far
enough away from obstructions in the vessel a unique
false target detection feature can be used. This target
detection mode programs the transducer to search for,
and display, the distance of the target nearest the transducer. When this false target is detected, the level information of this unwanted target is stored in the buffer for
false targets. This process is repeated until all of the possible false target locations are programmed into the
transmitter or the buffer is full. A maximum of nine false
targets can be programmed into the buffer.
Successful configuration of false targets will eliminate the
possibility of unwanted target echoes being recognized
as the real material level in the vessel. This technique is
applicable to any obstruction which remains at the same
horizontal plane (i.e., ladder rungs, pipes, tank braces,
mixer blades, etc.) in the vessel.
T R A N S M I T T E R
Supply voltage
S P E C I F I C A T I O N S
120 VAC +10%/-15%, 50–60 Hz
240 VAC +10%/-15%, 50–60 Hz
24 VDC, ±20%
Power consumption
12 watts (without heater)
Fuse size
1
⁄4 amp replaceable, 250 VAC Slo-Blo® for AC units
2 amp replaceable, 250 VDC Slo-Blo for DC units
Output signal
4–20 mA isolated (1,000 Ω load), RS-232
Relays
Four 10 amp resistive, SPDT
Fail-safe
User selectable for analog and relay outputs
Display
Sixteen (16) character alphanumeric LCD
Keypad
Sixteen (16) button integral to front panel
Enclosure material
High-impact polycarbonate
Response time
2 seconds typical
Accuracy
± 0.25% of calibrated span
Humidity
95% Non-condensing
Ambient temperature
without heater & thermostat*
-4° to +160° F (-20° to +70° C)
with heater & thermostat
-40° to +160° F (-40° to +70° C)
* NOTE: The 31-day data logger has a +32° F (0° C) minimum when used without the heater and thermostat.
4
T R A N S D U C E R
S P E C I F I C A T I O N S
Model 384
Model 385
38 kHz
50 kHz
Maximum range
35 feet (10.7 meters)
25 feet (7.6 meters)
Maximum span
33.5 feet (10.2 meters)
24 feet (7.3 meters)
18 inches (460 mm) from
12 inches (305 mm) from
-40° to +163° F (-40° to +73° C)
-40° to + 140° F (-40° to +60° C)
Transducer frequency
Minimum dead band
18 inches (460 mm) from
+140° to +200° F (+60° to +93° C)
Operating temperature
-40° to +163° F (-40° to +73° C)
Operating pressure
-40° to +200° F (-40° to +93° C)
-10 to +50 psig (-0.69 to +3.45 bar)
Temperature compensation
Automatic over the operating temperature range of the transducer
Beam angle
12° conical
Cable length
500 feet (152 meters) maximum between transducer and transmitter
A G E N C Y
AGENCY
FM
A P P R O V A L S
MODEL APPROVED
APPROVAL CATEGORY
APPROVAL CLASSES
34X-X442-10X
Non-hazardous
NEMA 4X, IP65
Non-incendive
Class I, II, III, Div. 2;
Groups A, B, C, D, F, & G, T4A
Non-hazardous
NEMA 4X, IP65
Explosion proof
Class I, II, III, Div. 1;
Groups B, C, D, E, F, & G, T6
385-XXXX-XXX
Non-hazardous
NEMA 4X, IP65
385-XEXX-006
385-XEXX-010
Explosion proof
Class I, II, III, Div. 1;
Groups B, C, D, E, F, & G, T6
385-XEXX-003
Explosion proof
Class I, II, III, Div. 1;
Groups A, B, C, D, E, F, & G, T6
34X-X442-10X
Non-hazardous
Type 4X enclosure
344-X442-10X
Non-incendive
Class I, II, III, Div. 2;
Groups A, B, C, D, E, F, & G, T4A
384-XKXX-0XX
Non-hazardous
Type 4X enclosure
384-XK0X-0XX
Explosion proof
Class I, II, III, Div. 1;
Groups B, C, D, E, F, & G
384-XK1X-0XX
384-XKYX-0XX
Explosion proof
Class I, II, III, Div. 1;
Groups C, D, E, F, & G
385-XXXX-XXX
Non-hazardous
Type 4X enclosure
385-XE1X-0XX
385-XEYX-0XX
Explosion proof
Class I, II, III, Div. 1;
Groups C, D, E, F, & G
385-XE0X-0XX
Explosion proof
Class I, II, III, Div. 1;
Groups A, B, C, D, E, F, & G
385-XX1X-XXX
Non-incendive
Class I, II, III, Div. 2;
Groups A, B, C, D, E, F, & G
384-XKXX-0XX
CSA
5
M E A S U R E M E N T
R A N G E
C A L C U L A T I O N S
Ultrasonic non-contact devices are typically rated for a
maximum range in ideal conditions. Experience has shown
Sensor alignment
that maximum range must be reduced for certain factors.
Although the maximum range rating is somewhat conservative, each application must be evaluated for specific conditions in the tank.
H O W
T O
C A L C U L A T E
Beam spread
interference
Air movement
To evaluate the performance of a 344 or 345 in a particular application, use the chart on page 7, and follow the
steps below:
Beam spread
interference
1. Select one condition from each of the operating
parameters that best describes your application.
2. Enter the corresponding performance multiplier value
in the application column.
3. Multiply all of the selected values together.
Vapors
Surface
agitation
Dust
Foam
4. Multiply step 3 by the maximum potential range of the
unit. This yields a value that is the maximum allowable
measurement range for the application.
E X A M P L E
The vessel is a closed-top tank, 26-feet tall and is filled from the top.
Surface agitation
Expect slight agitation from fill line: Performance multiplier 0.9
Vapor and steam
The process temperature is +130° F, slight vapor is expected:
Performance multiplier 0.9
Beam interference
No interference exists: Performance multiplier 1.0
Transducer alignment
The transducer will be perpendicular to the liquid surface:
Foam
Dust
Air movement
Ambient temperature
Pressure
Performance multiplier 1.0
None: Performance multiplier 1.0
None: Performance multiplier 1.0
None: Performance multiplier 1.0
0 to +120° F: Performance multiplier 1.0
Atmospheric pressure: Performance multiplier 1.0
Will the Model 344 work for this application?
C A L C U L A T I O N
Multiply all values in the application column:
0.9 x 0.9 x 1.0 x 1.0 x 1.0 x 1.0 x 1.0 x 1.0 x 1.0 x 35 feet (maximum) = 28.35 feet
The calculation yields 28.35 feet as the new maximum range. Since the tank is 26 feet tall, this application will give
satisfactory results with the Model 344.
NOTE:
6
The performance multipliers provided are conservative estimates. Since these factors are subjective, the values have
been designed to provide very high confidence of system success. Contact the factory if there are any questions
concerning the interpretation of any of these performance multipliers.
M E A S U R E M E N T
R A N G E
C A L C U L A T I O N S
Operating Parameter
Condition
SURFACE AGITATION: Surface agitation or waves can degrade the
performance. Moderate agitation results in only slight degradation
of performance. The worst case is when the surface is a good
reflector, but in the wrong direction. (See also transducer alignment.)
VAPORS AND STEAM: Vapors in the air space, above the process,
become apparent, and cause problems when the liquid process
temperature is well above the temperature of the airspace. The
greater the difference, the more expected vapor problems. The
problems result from condensation or layering in the sound path,
both of which attenuate the sound signal, degrading performance.
To avoid these problems, ensure that the vessel is insulated so that
vapors are less likely to condense. If a vent is used, be sure that the
vent, which is where condensation will form, is well away from the
transducer.
BEAM SPREAD INTERFERENCE: It is strongly recommended that
nothing be allowed within the transducer’s beam, except the liquid
which is being monitored. Often, the signal from the liquid will be
strong, compared to the signal from other sources, such as ladder
rungs, filling process material, support struts, etc. For that reason,
some applications may provide satisfactory results, even with
interference. Interference from agitator blades is only an intermittent
interference that usually has little effect on performance.
It is recommended there be no interference within the 6° half angle of
the transducer beam. If interference is unavoidable, make the interference as far as possible from the transducer so that the real signal
at the longest distance is stronger than the interference signal.
Smooth, glass-like surface
1.0
Slight agitation, choppiness
0.9
Heavy agitation
0.8
Slight vortex (6°)
0.7
No condensation
1.0
Little condensation
0.9
Much condensation/
foggy appearance
0.8
No interference
1.0
Agitator at speed less than 60 RPM
1.0
Agitator at speed greater than 60 RPM
DUST: Dust attenuates the sound and results in poor performance.
Even barely perceptible haze in the air can cause significant
attenuation.
AIR MOVEMENT: The movement of air, as possible in an open top
vessel, can create a layer from which the sound will reflect. This will
be most noticeable in applications where vapors or steam tend to
form.
AMBIENT TEMPERATURE: The ambient temperature can have a
significant effect on the sound and on the transducer’s capability to
transmit and receive sound. The most noticeable effect on the
transducer is at the temperature extremes.
PRESSURE: Sound requires air molecules to be able to travel. Sound
will not travel in a vacuum. Likewise, higher pressures will allow the
sound to continue without decay, which can cause problems with
multiple echoes.
Consult
Factory
Interference outside 4°, far from
transducer (in bottom third of range)
0.8
Interference outside 4°, near to
transducer (in top third of range)
0.5
TRANSDUCER ALIGNMENT: Optimum performance is obtained when Beam perpendicular to liquid surface
the transducer is perfectly aligned. If the process is not perpendicular
to the sound beam, the sound will not reflect properly back to the
Beam 4° off from perpendicular
transducer. The effect is significant.
FOAM: Even small thicknesses of foam can attenuate the ultrasound and render the system inoperative. If possible, moving the
transducer to an area in the tank where there is less foam will improve
the performance. Thick, heavy-density foams can sometimes produce
a reflection from the top of the foam. The multipliers shown at right
are general guidelines. For further assistance consult the factory.
Performance
Application
Multiplier
No foam
1.0
0.5
1.0
Light froth, less than 0.25" thick
0.8
Light foam, less than 0.5" thick
0.5
Light foam, more than 1" thick
0.1
No dust
1.0
Haze, barely perceptible
0.7
Slight dust
0.4
Heavy dust
0.1
No air movement
1.0
Open vessel, but transducer below rim
0.8
Open air movement in sound path
0.7
-20° to +140° F (-29° to +50° C)
1.0
-40° to -20° F (-40° to -29° C)
0.9
+140° to +160° F (+50 to +70° C)
0.9
-10 to +50 PSIG (0.689 to +3.45 bar)
1.0
Pressures outside above rating
Consult
Factory
Multiply all values together in the application column
Multiply by maximum potential range (35 feet for Model 344 or 25 feet for Model 345 )
X
Maximum allowable measurement range for this application
=
7
D I M E N S I O N A L
I N C H E S
MODEL
S P E C I F I C A T I O N S
( M M )
344
&
345
TRANSMITTERS
9.50
(241)
6.75
(171)
13.00
(330)
9.50
(241)
6.00
(152)
Side View
Front View
MODEL
385
TRANSDUCERS
4.63 (118)
Dia.
3.00
(76)
2.75
(70)
4.00 3/4" NPT
(102)
2" NPT
1.90 (48)
2" NPT Transducer with Housing
2"
NPT
3/4"
NPT
3/4"
NPT
3.00 (76),
6.00 (152) or
10.00 (254)
depending
upon model
Optional
Mounting
Flange
8
3/4"
NPT
3.00
(76)
1.90 (48)
6.00 (152) or
10.00 (254)
depending
upon model
1.90 (48)
3.00 (76),
6.00 (152) or
10.00 (254)
depending
upon model
1.90 (48)
⁄4" and 2" NPT Transducer without Housing
3
D I M E N S I O N A L
I N C H E S
MODEL
S P E C I F I C A T I O N S
( M M )
384
1" NPT
Process
Connection
TRANSDUCERS
1" NPT
Process
Connection
3/4" NPT
4.63 (118)
Dia.
2" NPT
Process
Connection
3.00 (76)
2.75
(70)
2" NPT
Process Connection
10.00" (254)
Insertion Length
3.00" (76)
Insertion Length
1" NPT Transducer without Housing
4.50
(114)
10.00" (254)
Insertion Length
3.00" (76)
Insertion Length
2.12 (54)
Insertion Dia.
2" NPT
Process
Connection
2.12 (54)
Insertion Dia.
2" NPT Transducer with Housing
2" NPT
Process
Connection
10.00" (254)
Insertion Length
3.00" (76)
Insertion Length
2" NPT Transducer without Housing
OPTIONAL
MOUNTING
BRACKETS
3/4" Male NPT
(P/N 36-3813-002)
2" Female NPT
(P/N 36-3813-001)
3.00
(76)
29.00
(736)
3/4" Male NPT
(P/N 36-3812-002)
2" Female NPT
(P/N 36-3812-001)
3.12
(79)
2.00
(50)
1.50
(38)
20.50
(520)
20.50 (520)
2.00
(50)
3.12
(79)
6.12
(155)
22.50 (571)
Floor Mount Bracket
1.50
(38)
3.00
(76)
22.50
(571)
Wall Mount Bracket
9
T R A N S M I T T E R
M O D E L
N U M B E R
Models available for quick shipment, usually within one week after factory
receipt of a complete purchase order, through the Expedite Ship Plan (ESP)
BASIC MODEL
344
345
Ultrasonic non-contact transmitter, used with Model 384 transducer
Ultrasonic non-contact transmitter, used with Model 385 transducer
INPUT POWER
0
1
2
3
4
120
240
24
120
240
VAC, 50/60 Hz
VAC, 50/60 Hz
VDC
VAC with heater and thermostat
VAC with heater and thermostat
SPECIAL OPTIONS
0
1
2
3
4
M O D E L
M O D E L
3 8 4
4
2
3 8
1
None
Mechanical totalizer
31-day data logger
Mechanical totalizer & 31-day data logger
0
K H Z
T R A N S D U C E R
N U M B E R
PROCESS CONNECTION
2
5
1" NPT, not available with transducer housing code 1 or Y
2" NPT
TRANSDUCER MATERIAL
K
Kynar
TRANSDUCER HOUSING
0
1
Y
No housing, 35' (10.7 m) of cable potted into transducer
Cast aluminum, NEMA 4X/7/9 housing with 3⁄4" NPT single conduit,
connecting cable ordered separately
316 stainless steel, NEMA 4X/7/9 housing with 3⁄4" NPT single conduit
connecting cable ordered separately
TRANSDUCER MOUNTING BRACKET
0
3
4
No mounting bracket
Wall mount bracket for 2" NPT process connection only
Floor mount bracket for 2" NPT process connection only
TRANSDUCER INSERTION LENGTH
003
010
3
10
8
4
K
3" (76 mm) length
10" (254 mm) length
M O D E L
M O D E L
3 8 5
5 0
k H z
T R A N S D U C E R
N U M B E R
PROCESS CONNECTION
3
1
5
⁄4" NPT, not available with transducer housing code 1 or Y
2" NPT
TRANSDUCER MATERIAL
K
E
Kynar
316 stainless steel (for use in hazardous environments, refer to agency approvals)
TRANSDUCER HOUSING
0
1
Y
No housing, 35' (10.7 m) of cable potted into transducer
Cast aluminum, NEMA 4X/7/9 housing with 3⁄4" NPT single conduit,
connecting cable ordered separately
316 stainless steel, NEMA 4X/7/9 housing with 3⁄4" NPT single conduit
connecting cable ordered separately
TRANSDUCER MOUNTING BRACKET
0
1
2
3
4
No mounting bracket
Wall mount bracket for 3⁄4" NPT process connection only
Floor mount bracket for 3⁄4" NPT process connection only
Wall mount bracket for 2" NPT process connection only
Floor mount bracket for 2" NPT process connection only
TRANSDUCER INSERTION LENGTH
003
006
010
3
8
5
C O N N E C T I N G
P A R T
3" (76 mm) length
6" (152 mm) length
10" (254 mm) length
C A B L E
N U M B E R
CABLE LENGTH IN FEET
10 feet (3 m) minimum, 500 feet (152 m) maximum length
Example: 12 foot cable length = Code 012
0
3
7
3
1
7
6
11
Q U A L I T Y
The quality assurance system in place at
Magnetrol® guarantees the highest level
of quality throughout the company.
MAGNETROL is committed to providing
full customer satisfaction both in quality
products and quality service.
The MAGNETROL quality assurance system
is registered to ISO 9001 affirming its commitment to known international quality
standards providing the strongest assurance
of product/service quality available.
Several ECHOTEL Model 344 and 345
Ultrasonic Transmitters are available for
quick shipment, usually within one week
after factory receipt of a complete purchase
order, through the Expedite Ship Plan (ESP).
To take advantage of ESP, simply match the
color coded model number codes (standard
dimensions apply).
ESP service may not apply to orders of ten
units or more. Contact your local representa-
Models covered by ESP service are color
coded in the model selection charts.
tive for lead times on larger volume orders,
as well as other products and options.
E S P
Expedite
Ship
Plan
W A R R A N T Y
All MAGNETROL electronic level and flow
controls are warranted free of defects in
materials or workmanship for one full year
from the date of original factory shipment.
If returned within the warranty period; and,
upon factory inspection of the control, the
cause of the claim is determined to be covered under the warranty; then, MAGNETROL
will repair or replace the control at no cost
to the purchaser (or owner) other than
transportation.
MAGNETROL shall not be liable for misapplication, labor claims, direct or consequential damage or expense arising from the
installation or use of equipment. There are
no other warranties expressed or implied,
except special written warranties covering
some MAGNETROL products.
For additional information, see Instruction Manual 51-629.
5300 Belmont Road • Downers Grove, Illinois 60515-4499 • 630-969-4000 • Fax 630-969-9489 • www.magnetrol.com
145 Jardin Drive, Units 1 & 2 • Concord, Ontario Canada L4K 1X7 • 905-738-9600 • Fax 905-738-1306
Heikensstraat 6 • B 9240 Zele, Belgium • 052 45.11.11 • Fax 052 45.09.93
Regent Business Ctr., Jubilee Rd. • Burgess Hill, Sussex RH15 9TL U.K. • 01444-871313 • Fax 01444-871317
Copyright © 2011 MAGNETROL INTERNATIONAL, INCORPORATED. All rights reserved. Printed in the USA.
Performance specifications are effective with date of issue and are subject to change without notice.
MAGNETROL, MAGNETROL logotype and ECHOTEL are registered trademarks of MAGNETROL INTERNATIONAL, INCORPORATED.
BULLETIN: 51-129.6
EFFECTIVE: May 2004
SUPERSEDES: November 2002