®
FFM100
Fuel Flow Monitor
User’s Manual
Revision 1.2
Copyright © 2012 Maretron, LLP All Rights Reserved
Maretron, LLP
9014 N. 23rd Ave #10
Phoenix, AZ 85021
Maretron Manual Part #: M003010
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Table of Contents
1.1 Introduction....................................................................................................................1
1.2 Firmware Revision.........................................................................................................1
1.4 FFM100 Accessories.....................................................................................................1
1.5 Quick Install ...................................................................................................................1
1.6 Theory of Operation.......................................................................................................2
1.6.1 Operating Modes ................................................................................................2
1.6.2 Sensor Accuracy.................................................................................................2
1.6.3 Diesel Fuel Flow Measurement...........................................................................4
1.6.4 Temperature Compensation ...............................................................................5
1.6.5 Fuel Flow Sensor Selection ................................................................................6
1.6.6 Accuracy of Diesel Fuel Flow Measurement.......................................................7
Installation............................................................................................................................8
2.5.1 Fluid flow sensor Connections ............................................................................9
2.5.2 NMEA 2000® Connection..................................................................................10
3.1.1 Configuring Device Instance .............................................................................12
3.1.2 Configuring Channel #0 Installation Orientation................................................12
3.1.3 Configuring Channel #1 Installation Orientation................................................12
3.1.4 Configuring Channel #0 Allow Negative Flow ...................................................12
3.1.5 Configuring Channel #1 Allow Negative Flow ...................................................13
3.1.6 Configuring Differential Mode Allow Negative Flow ..........................................13
3.1.7 Configuring Installation Description...................................................................13
3.1.9 Restoring Factory Default Settings ...................................................................13
3.4 Configuring Channel #0...............................................................................................14
3.4.1 Enabling/Disabling Channel #0.........................................................................14
3.4.2 Configuring Channel #0 Engine Instance..........................................................14
3.4.3 Configuring Channel #0 Engine Label...............................................................14
3.4.4 Configuring Channel #0 K-factor.......................................................................14
3.4.5 Configuring Channel #0 Data Damping Period .................................................14
3.4.7 Configuring Channel #0 Temperature Instance ................................................14
3.4.8 Configuring Channel #0 Temperature Source...................................................14
3.4.9 Configuring Channel #0 Temperature Label .....................................................15
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3.5 Configuring Channel #1...............................................................................................15
3.5.1 Enabling/Disabling Channel #1.........................................................................15
3.5.2 Configuring Channel #1 Engine Instance..........................................................15
3.5.3 Configuring Channel #1 Engine Label...............................................................15
3.5.4 Configuring Channel #1 K-factor.......................................................................15
3.5.6 Configuring Channel #1 Data Damping Period .................................................16
3.5.8 Configuring Channel #1 Temperature Instance ................................................16
3.5.9 Configuring Channel #1 Temperature Source...................................................16
Installation Template..........................................................................................................21
Maretron (2 Year) Limited Warranty...................................................................................22
Table of Figures
Figure 3 - Diesel Fuel Rate Measurement Fluid Flow Sensor Locations................................... 5
Figure 4 – Fluid Flow Sensor Selection Chart for Diesel Engine Applications........................... 6
Figure 6 – Fluid flow sensor Connection Diagram................................................................... 10
Figure 7 – NMEA 2000® Connector Face Views ..................................................................... 11
Table of Appendices
Appendix A – NMEA 2000® Interfacing.................................................................................... A1
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1 General
1.1 Introduction
Congratulations on your purchase of the Maretron Fuel Flow Monitor (FFM100). Maretron has
designed and built your monitor to the highest standards for years of reliable, dependable, and
accurate service.
Maretron’s Fuel Flow Monitor (FFM100) is used to adapt up to two positive displacement fluid
flow sensors to the NMEA 2000® network (Fluid Flow sensors sold separately). This allows you
to observe engine fuel usage on a vessel where there are NMEA 2000® compatible displays.
With the appropriate sensor, the FFM100 reports flow rate for diesel engines or gasoline
engines.
The FFM100 can be used with the positive displacement sensors to detect flow rates of many
other types of fluid as well, including water, hydraulic oil, or other fluids.
The Maretron FFM100 is designed to operate within the harsh demands of the marine
environment. However, no piece of marine electronic equipment can function properly unless
installed, calibrated, and maintained in the correct manner. Please read carefully and follow
these instructions for installation, calibration, and usage of the Maretron FFM100 in order to
ensure optimal performance.
1.2 Firmware Revision
This manual corresponds to FFM100 firmware revision 1.0.1.
1.3 Features
The Maretron FFM100 has the following features:
• NMEA 2000® interface
• Adapts up to two fluid flow sensors to the NMEA 2000 network
• Each channel independently programmable to match fluid flow sensor characteristics
• The FFM100 can be programmed to measure a differential flow rate using two fluid flow
sensors (supply and return flow for diesel engines) or two completely independent flow
rates.
1.4 FFM100 Accessories
Maretron offers the following accessories for the FFM100:
• M1RSP-2R-E8 Fuel Flow Sensor 20 to 200 HP (0.53 to 26.4 GPH, 2 to 100 LPH)
• M2RSP-2R-E8 Fuel Flow Sensor 200 to 1000 HP (4 to 132 GPH, 15 To 500 LPH)
• M4ARP-2-E8
Fuel Flow Sensor 1000 to 3000 HP (48 to 396 GPH, 180 To 1500
LPH)
1.5 Quick Install
Installing the Maretron FFM100 involves the following steps. Please refer to the individual
sections for additional details.
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1.6 Theory of Operation
The FFM100 operates by using positive displacement fluid flow sensors. These sensors are
volumetric (they measure the volume of fluid passing through them as opposed to the mass of
the fluid).
1.6.1 Operating Modes
The FFM100 can operate in one of two user-selectable operating modes:
1) Differential Flow Rate – this mode is used for diesel engines that recirculate unused fuel
back into the fuel tank. These engines will have separate supply and return fuel lines.
2) Two Independent Flow Rates – the FFM100 can measure flow rates from two
independent sources; for example, a water flow rate on one channel and a gasoline fuel
flow rate on another channel.
1.6.2 Sensor Accuracy
The M1RSP-2R-E8, M2RSP-2R-E8, and M4ARP-2-E8 fuel flow sensors use positive
displacement technology. These sensors are extremely accuracy over a wide flow range.
flow rate for the M1RSP-2R-E8 and M2RSP-2R-E8 fuel flow sensors.
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Figure 2 - M4ARP-2-E8 Typical Accuracy and Pressure Loss
1.6.3 Diesel Fuel Flow Measurement
Most diesel engines do not use all of the fuel that is supplied to them by the fuel pump via the
supply line. A portion of the fuel is consumed by the engine, but the majority of the fuel is used
for cooling the injection system and returned to the fuel tank via the return line.
For diesel engines, the FFM100 will operate in its differential mode, and will measure the net
fuel consumption of these engines by separately measuring the fuel sent to the engine via the
supply line and the fuel returned to the fuel tank from the engine via the return line. The
difference between these two readings is the fuel consumption of the engine. Please refer to
Figure 3 below for a system diagram demonstrating the location of the supply and return fuel
flow sensors in a diesel fuel system.
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Display/MFD
Supply Fuel
Flow Sensor
Fuel Filter
Return Fuel
Flow Sensor
Fuel Tank
Figure 3 - Diesel Fuel Rate Measurement Fluid Flow Sensor Locations
1.6.4 Temperature Compensation
The task of computing fuel consumption for a diesel engine is further complicated by the
following two factors:
1) Diesel fuel expands when heated
2) Diesel fuel is heated as it passes through the engine
When using volumetric sensors such as positive displacement sensors or turbine flow sensors,
simply subtracting the return flow rate from the supply flow rate without taking these factors
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into account will result in the fuel consumption being underestimated. In fact, without
compensating for temperature, if the engine were consuming no fuel, the return fuel flow rate is
greater than the supply fuel rate, since the fuel is expanded by the engine’s heat as it passes
through the injection system.
The M1RSP-2R-E8, M2RSP-2R-E8, and M4ARP-2-E8 fuel flow sensors feature embedded
temperature sensors, so that the temperature of both the supply and return fuel is sensed and
used in real time by the FFM100 to compensate for the expansion of the fuel due to the
increase in temperature, for the most accurate possible fuel flow measurement.
1.6.5 Fuel Flow Sensor Selection
The fluid flow sensors must likewise be sized to accommodate the flow rate of fluid flowing
through the supply and return lines, as opposed to the net fuel consumption used by the
engine. If too small a fuel flow sensor is used, excessive back pressure will occur through the
sensors and the sensor may wear prematurely.
For example, consider the M1RSP-2R-E8 fluid flow sensor, which is rated at a maximum flow
rate of 26.4 GPH (100 LPH). A typical diesel engine will consume 20% of the fuel sent to the
engine, so under this assumption, this fuel sensor will be able to support a diesel engine which
consumes 5.28 GPH (20 LPH).
The fluid flow sensor you select must have sufficient range to measure the supply flow rate of
maximum fuel supply flow rates that can be sensed by each fuel flow sensor, and approximate
engine power ranges for each fuel flow sensor type. Please consult your engine’s
documentation or contact your engine manufacturer for the maximum supply fuel flow rate
(sometimes called fuel feed rate) for the specific engine whose fuel consumption you wish to
monitor.
Approximate
Fluid Flow Sensor
M1RSP-2R-E8
M2ESP-2R-E8
M4ARP-2-E8
Flow Rate Range
Engine Power
Range
0.53 to 26.4 GPH
2 to 100 LPH
4 to 132 GPH
15 to 500 LPH
48 to 396 GPH
180 to 1500 LPH
20 to 200 HP
14.9 to 149 kW
200 to 1000 HP
149 to 746 kW
1000 to 3000 HP
746 to 2237 kW
Figure 4 – Fluid Flow Sensor Selection Chart for Diesel Engine Applications
If you are unable to obtain maximum supply fuel flow rates from the engine manufacturer,
another way to get a good estimate of the engine’s fuel feed rate is to disconnect the fuel
return line from the tank and direct it into a five gallon bucket. Run the engine at maximum
RPM until the bucket is filled, and calculate the return fuel flow rate by dividing the amount of
fuel in the bucket by the amount of time it took to fill the bucket. For instance, if it took 15
minutes (0.25 hour) to fill the five gallon bucket, the return flow rate is:
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Max. return flow rate = 5 gallons / 0.25 hours = 20 gallons per hour
Now, add in the engine’s consumption fuel rate at this RPM, which should be readily available
from the manufacturer’s documentation for the engine, and calculate the maximum supply flow
rate as follows:
Max. supply flow rate = Max. return flow rate + Max. consumption flow rate
For this example, let’s assume that the engine manufacturer’s documentation shows that the
fuel consumption of the engine at the maximum RPM is 5 gallons per hour. We can calculate
the maximum supply flow rate as follows:
Max. supply flow rate = 20 gallons per hour + 5 gallons per hour = 25 gallons per hour.
The 25 gallons per hour maximum supply flow rate is within the specifications of the M1RSP-
2R-E8 fuel flow sensor, so the M1RSP-2R-E8 is appropriate for this fuel flow application. If the
maximum supply flow rate had exceeded the M1RSP-2R-E8 specifications, you would have
needed to select the next larger fuel flow sensor, the M2RSP-2R-E8.
1.6.6 Accuracy of Diesel Fuel Flow Measurement
Even though the fluid flow sensors used with the FFM100 are rated at ±0.25% accuracy, since
the fuel consumption measurement is calculated as the difference of the supply and return fuel
flow rates, the accuracy of the fuel consumption measurement when operating in differential
mode for a diesel engine depends on the ratio of the flow rate of fuel consumed by the engine
to the flow rate of fuel supplied to the engine.
Following is a worst-case analysis of diesel engine fuel consumption measurement accuracy
with a 4:1 supply rate to consumption rate ratio (this ratio is typical of many diesel engines).
This assumes that both the supply and return fuel flow sensors are at the limit of their
specifications in the way that will cause the most inaccuracy in the fuel consumption
calculation.
Actual Supply Flow Rate:
80.0 LPH
Actual Engine Fuel Consumption:
Actual Return Flow Rate:
20.0 LPH
60.0 LPH
Measured Supply Flow Rate:
80.2 LPH (This assumes that the supply sensor
reads 0.25% high)
Measured Return Flow Rate:
59.85 LPH (This assumes that the return sensor
reads 0.25% low)
20.35 LPH
1.75 %
Calculated Fuel Consumption:
Error:
The resulting 1.75% error value is what appears in the FFM100 specifications for differential
flow rate accuracy.
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1.6.7 Choosing a Fluid Flow Sensor Mounting Location
Choosing a proper mounting location for fluid flow sensors is critical to obtaining accurate tank
level measurements. Because of the positive displacement design of the FFM100 sensors, no
pulse dampening or flow straightening is necessary. The installation instructions packaged with
each fuel flow sensor contain details on choosing a mounting location and installation. The
ideal location for the supply fuel flow sensor is immediately after the fuel filter.
NOTE: Maretron fuel flow sensors have anti-tamper blue silicone on one or more of the
screws that hold the body of the sensor together. Do not remove these screws.
Removing these screws will void the warranty on the sensor.
2 Installation
2.1 Unpacking the Box
When unpacking the box containing the Maretron FFM100, you should find the following items:
• 1 – FFM100 Fuel Flow Monitor
• 1 – Parts Bag containing 4 Stainless Steel Mounting Screws
• 1 – FFM100 User’s Manual
• 1 – Warranty Registration Card
If any of these items are missing or damaged, please contact Maretron.
2.2 Choosing a Mounting Location
Please consider the following when choosing a mounting location.
1. The FFM100 is waterproof, so it can be mounted in a damp or dry location.
2. The orientation is not important, so the FFM100 can be mounted on a horizontal deck,
vertical bulkhead, or upside down if desired.
3. The FFM100 is temperature-rated to 55°C (130°F), so it should be mounted away from
engines or engine rooms where the operating temperature exceeds the specified limit.
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2.3 Mounting the FFM100
Attach the FFM100 securely to the vessel using the included stainless steel mounting screws
containing methacrylate ester, such as Loctite Red (271), as they will cause stress cracking of
the plastic enclosure.
Figure 5 – Mounting the FFM100
2.4 Mounting the Fluid Flow Sensor
Since the FFM100 supports different fluid flow sensors depending on the application, please
consult the installation instructions that are packaged with each sensor for detailed installation
instructions.
2.5 Connecting the FFM100
The FFM100 requires two types of electrical connections:
2.5.1 Fluid flow sensor Connections
The FFM100 fluid flow sensor connections are made by connecting to the 12-pin terminal strip
on the top of the unit. First, remove the four screws at the corners of the unit detaching the
splash guard from the unit. On the bottom of the splash guard, you will find a label detailing
the wire connection to pin number assignments, which are repeated in the table below.
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Pin #
1
Signal Name
Connection
Fluid flow sensor 0 power connection
Fluid flow sensor 0 ground connection
Fluid flow sensor 0 phase A connection
Fluid flow sensor 0 phase B connection
Fluid flow sensor 0 phase C connection
Fluid flow sensor 0 temperature sensor connection
Fluid flow sensor 1 power connection
Fluid flow sensor 1 ground connection
Fluid flow sensor 1 phase A connection
Fluid flow sensor 1 phase B connection
Fluid flow sensor 1 phase C connection
Fluid flow sensor 1 temperature sensor connection
P0
G0
A0
B0
C0
T0
P1
G1
A1
B1
C1
T1
2
3
4
5
6
7
8
9
10
11
12
Table 1 - Fluid Flow Sensor Connections
M4ARP-2-E8 fluid flow sensor. This figure shows the connection of the fluid flow sensor to
channel 0. Connections to other channels are similar.
Fluid flow sensor
FFM100 Screw Terminals
1
2
3
4
5
6
7
8
9 10 11 12
Figure 6 – Fluid flow sensor Connection Diagram
2.5.2 NMEA 2000® Connection
The NMEA 2000® connector can be found on the side of the enclosure. The NMEA 2000®
NMEA 2000® network using a Maretron NMEA 2000® cable (or an NMEA 2000® compatible
cable) by connecting the female end of the cable to the FFM100 (note the key on the male
connector and keyway on the female connector). Be sure the cable is connected securely and
that the collar on the cable connector is tightened firmly. Connect the other end of the cable
(male) to the NMEA 2000® network in the same manner. The FFM100 is designed such that
you can plug or unplug it from an NMEA 2000® network while the power to the network is
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connected or disconnected. Please follow recommended practices for installing NMEA 2000®
network products.
Figure 7 – NMEA 2000® Connector Face Views
3 Configuring the FFM100
The FFM100 has several configurable parameters, which are shown below including the
default values. If you are not using the default values, then you will need to refer to the
corresponding section for configuring the FFM100 appropriately.
a. Device Instance
b. Channel-0 Installation
c. Channel-1 Installation
d. Channel-0 Allow negative flow
e. Channel-1 Allow negative flow
f. Differential Mode Allow negative flow
g. Installation Description
h. NMEA 2000 PGN Enable/Disable
i. Restore Factory Defaults
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3.1 Advanced Configuration
3.1.1 Configuring Device Instance
NMEA 2000® provides a unique device instance for each flow measuring device on a vessel.
This value should be programmed in each FFM100 so that each FFM100 is associated with a
unique device instance number. The default instance number is 0, which is used to indicate the
first FFM100 that is hooked to the network. Subsequent FFM100s connected to the network
would be numbered 1, 2, and so on.
3.1.2 Configuring Channel #0 Installation Orientation
If you install the Channel #0 fluid flow sensor with the “FLOW” arrow on the sensors pointing in
the same direction as the fuel flow, you will not need to change this parameter from the factory
default setting. If you inadvertently install the sensor in the reverse direction, rather than
reinstalling the sensor, you may change this parameter from “Normal” to “Reverse”, and the
FFM100 will compensate for the reversed installation of the flow sensor.
3.1.3 Configuring Channel #1 Installation Orientation
If you install the Channel #1 fluid flow sensor with the “FLOW” arrow on the sensors pointing in
the same direction as the fuel flow, you will not need to change this parameter from the factory
default setting. If you inadvertently install the sensor in the reverse direction, rather than
reinstalling the sensor, you may change this parameter from “Normal” to “Reverse”, and the
FFM100 will compensate for the reversed installation of the flow sensor.
3.1.4 Configuring Channel #0 Allow Negative Flow
The M1RSP-2R-E8, M2RSP-2R-E8, and M4ARP-2-E8 fuel flow sensors are capable of
sensing flow in both directions. When this parameter is in the default state of “Yes”, the
FFM100 will report reverse flow on Channel #0 as a negative flow rate. If you do not wish to
see negative flow rates from the Channel #0 sensor, you may change this parameter to “No”.
When this parameter is set to “No”, the FFM100 will report a zero flow rate for Channel #0
when reverse flow occurs.
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3.1.5 Configuring Channel #1 Allow Negative Flow
The M1RSP-2R-E8, M2RSP-2R-E8, and M4ARP-2-E8 fuel flow sensors are capable of
sensing flow in both directions. When this parameter is in the default state of “Yes”, the
FFM100 will report reverse flow on Channel #1 as a negative flow rate. If you do not wish to
see negative flow rates from the Channel #1 sensor, you may change this parameter to “No”.
When this parameter is set to “No”, the FFM100 will report a zero flow rate for Channel #1
when reverse flow occurs.
3.1.6 Configuring Differential Mode Allow Negative Flow
In differential mode, if no fuel consumption occurring but fuel is flowing through both the supply
and return fuel flow sensors, the resulting calculated net fuel consumption can result in a small
negative value. When this parameter is set to the default state of “No”, the FFM100 will report
this as a zero flow rate value. If you wish to see these small negative values transmitted by the
FFM100, change the value of this parameter to “Yes”.
3.1.7 Configuring Installation Description
You can configure the two installation description parameters with any text you wish. Examples
include date of installation, location, etc. NMEA 2000 diagnostic tools such as Maretron
N2KAnalyzer® can display this information.
3.1.8 Configuring NMEA 2000 PGN Enable/Disable
The FFM100 is capable of transmitting NMEA 2000® messages (or PGNs) associated with
monitored fluid senders. You may individually enable or disable each of these messages. You
may also change the rate of transmission of each of these messages if desired.
3.1.9 Restoring Factory Default Settings
Selecting this configuration option causes all stored parameters in the FFM100 to be reset to
the values they contained when the unit was manufactured.
3.2 Configuring the Device Label
Program this parameter with a text string which identifies this device. Maretron display
products will display this label text when you are selecting data to display.
3.3 Configuring the Operating Mode
The FFM100 can be operated in one of two selectable operating modes:
1. Differential Flow Rate (default) – in this mode, the FFM100 measures fuel
consumption of a diesel engine by measuring the flow rate of the fuel sent
from the fuel tank to the engine and the flow rate of the fuel returned from
the engine to the fuel tank, and computing the difference between these
two flow rates, with temperature compensation. This difference is the flow
rate of the fuel actually consumed by the engine, and is transmitted as a
single parameter over the NMEA 2000 network.
2. Two Individual Flow Rates – in this mode, the FFM100 can measure two
independent flow rates of any fluids – diesel, oil, water, etc., and transmit
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the two flow rate measurements as separate parameters over the NMEA
2000 network.
3.4 Configuring Channel #0
3.4.1 Enabling/Disabling Channel #0
By default, the channel is enabled and will measure the flow rate and transmit it over the
NMEA 2000 network. If this parameter is programmed to “Disable”, the channel will be
completely disabled and will not measure flow rate nor transmit it over the NMEA 2000
network.
3.4.2 Configuring Channel #0 Engine Instance
Program this parameter to match the desired engine instance number of the flow rate and total
fuel used for this channel. You can program this parameter to any value between 0 and 252.
3.4.3 Configuring Channel #0 Engine Label
Program this parameter with a text string which identifies the particular parameter being
monitored by this channel. Maretron display products will display this label text when you are
selecting data to display.
3.4.4 Configuring Channel #0 K-factor
Program this parameter to match the K-factor that appears on the flow sensor connected to
this channel.
3.4.5 Configuring Channel #0 Data Damping Period
You can configure a damping parameter to smooth the flow rate readings or make them more
responsive. The data damping is configurable between 0.2-25.0 seconds. The default data
damping period is 3.0 seconds.
3.4.6 Resetting the Total Volume Recorded for Channel #0
The FFM100 maintains the total volume recorded in EEPROM, so that it is maintained across
power cycles. Select this menu entry to reset the total volume recorded to zero.
3.4.7 Configuring Channel #0 Temperature Instance
Program this parameter to match the desired instance number of the temperature reading for
this channel. You can program this parameter to any value between 0 and 252. The default
value for this parameter is 0.
3.4.8 Configuring Channel #0 Temperature Source
Program this parameter to match the desired instance number of the temperature reading for
this channel. You can program this parameter to any value between 0 and 252. The default
value for this parameter is 129 (User Defined).
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3.4.9 Configuring Channel #0 Temperature Label
Program this parameter with a text string which identifies the particular temperature parameter
being monitored by this channel. Maretron display products will display this label text when
you are selecting data to display.
3.5 Configuring Channel #1
3.5.1 Enabling/Disabling Channel #1
NOTE: This parameter is available only when the Operating Mode of the FFM100 is set to
“Two Independent Flow Rates”.
By default, the channel is enabled and will measure the flow rate and transmit it over the
NMEA 2000 network. If this parameter is programmed to “Disable”, the channel will be
completely disabled and will not measure flow rate nor transmit it over the NMEA 2000
network.
3.5.2 Configuring Channel #1 Engine Instance
NOTE: This parameter is available only when the Operating Mode of the FFM100 is set to
“Two Independent Flow Rates”.
Program this parameter to match the desired engine instance number of the flow rate and total
fuel used for this channel. You can program this parameter to any value between 0 and 252.
3.5.3 Configuring Channel #1 Engine Label
NOTE: This parameter is available only when the Operating Mode of the FFM100 is set to
“Two Independent Flow Rates”.
Program this parameter with a text string which identifies the particular parameter being
monitored by this channel. Maretron display products will display this label text when you are
selecting data to display.
3.5.4 Configuring Channel #1 K-factor
Program this parameter to match the K-factor that appears on the flow sensor connected to
this channel.
3.5.5 Configuring Channel #1 Temperature Coefficient
NOTE: This parameter is available only when the Operating Mode of the FFM100 is set to
“Differential Mode”.
In a diesel engine, the diesel fuel is used to help cool the fuel injection system. Therefore, the
fuel returned from the engine to the tank has a higher temperature than the fuel sent to the
engine from the tank. Diesel fuel expands when heated. To calculate the most accurate fuel
usage measurement, the FFM100 accounts for this expansion by sensing the temperature at
the supply flow sensor and the receive flow sensor, and calculating the effect of the
temperature difference on the fuel expansion. In order to do this compensation, this parameter
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is programmed with the appropriate value for thermal expansion coefficient of the fluid being
measured. The default value of this field is (0.083%/°C), which is appropriate for diesel fuel.
The configuration tools have predefined values for common fluids: diesel, engine oil, gasoline,
and water. You may select one of these values or choose your own.
3.5.6 Configuring Channel #1 Data Damping Period
NOTE: This parameter is available only when the Operating Mode of the FFM100 is set to
“Two Independent Flow Rates”.
You can configure a damping parameter to smooth the flow rate readings or make them more
responsive. The data damping is configurable between 0.2-25.0 seconds. The default data
damping period is 3.0 seconds.
3.5.7 Resetting the Total Volume Recorded for Channel #1
NOTE: This parameter is available only when the Operating Mode of the FFM100 is set to
“Two Independent Flow Rates”.
The FFM100 maintains the total volume recorded in EEPROM, so that it is maintained across
power cycles. Select this menu entry to reset the total volume recorded to zero.
3.5.8 Configuring Channel #1 Temperature Instance
Program this parameter to match the desired instance number of the temperature reading for
this channel. You can program this parameter to any value between 0 and 252. The default
value for this parameter is 0.
3.5.9 Configuring Channel #1 Temperature Source
Program this parameter to match the desired instance number of the temperature reading for
this channel. You can program this parameter to any value between 0 and 252. The default
value for this parameter is 129 (User Defined).
3.5.10 Configuring Channel #1 Temperature Label
Program this parameter with a text string which identifies the particular temperature parameter
being monitored by this channel. Maretron display products will display this label text when
you are selecting data to display.
4 Maintenance
Regular maintenance is not required; however, an occasional inspection will ensure continued
proper operation of the Maretron FFM100. Perform the following tasks periodically:
• Clean the unit with a soft cloth. Do not use chemical cleaners as they may remove
paint or markings or may corrode the FFM100 enclosure or seals. Do not use any
cleaners containing acetone, as they will deteriorate the plastic enclosure.
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• Ensure that the unit is mounted securely and cannot be moved relative to the mounting
surface. If the unit is loose, tighten the screws holding the cable ties.
• Check the security of the cable connected to the NMEA 2000® interface and tighten if
necessary.
• Check the security of all of the fluid flow sensor connections on the top of the unit and
tighten if necessary.
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FFM100 User’s Manual
5 Troubleshooting
If you notice unexpected operation of the Maretron FFM100, follow the troubleshooting
procedures in this section to remedy simple problems.
Symptom
No Fuel Flow
data visible on
NMEA 2000®
network.
Troubleshooting Procedure
1. Ensure that the FFM100 is properly connected to the NMEA 2000®
network.
2. Ensure that fluid flow sensors are properly connected to the FFM100.
3. Ensure that each channel that you wish to monitor is configured
correctly and that instance numbers are configured correctly.
4. Ensure that the FFM100 has the appropriate NMEA 2000 PGNs
enabled.
No Fluid
1. If operating in the NMEA 2000® Mode, check the connection to the
2. Ensure that power is supplied to the NMEA 2000® network. Proper
network power can be checked by measuring the voltage at an open
tee between NET-S and NET-C. The voltage should be between 9 and
16 volts.
Temperature
data visible on
NMEA 2000®
network.
3. Ensure that both trunk line terminators are in place. Proper network
termination can be checked by removing network power and
measuring the resistance at an open tee between NET-L and NET-H
signals. The resistance should read approximately 60 ohms (two 120
ohm terminators in parallel equals 60 ohms).
Fluid will not
flow through the
fluid flow
1. Check the meter for foreign matter blocking the rotors. Dismantle the
sensor and clean the rotors, then reassemble the sensor.
2. If a line strainer is installed, check to see whether it is blocked, and
clean if necessary.
sensors
3. Check the rotors to see if they are damaged, and replace if necessary.
4. Check the sensor connections to see if they are over-tightened, and
re-adjust if necessary.
Reduced flow
through the fluid
flow sensors
1. If a line strainer is installed, check to see if it is partially blocked, and
clean if necessary.
2. Ensure that the fluid being measured is less than 1000 centipoise
viscosity.
Inaccurate fluid 1. Ensure that the fluid flow rate is within the minimum and maximum
flow reading
specifications for the sensor.
2. Check for air in the system, and bleed if present.
3. Check the fluid flow sensor body and rotors for excess wear caused
by incorrect installation.
Figure 8 – Troubleshooting Guide
If these steps do not solve your problem, please contact Maretron Technical Support (refer to
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6 Technical Specifications
Specifications
Parameter
Value
Comment
Accuracy (Differential Mode)
±1.75% of Using M1RSP-2R-E8 sensors
reading
K factors programmed into FFM100
4:1 fuel supply/fuel consumption ratio
Accuracy (Two Independent
Sensors)
±0.25% of Using M1RSP-2R-E8 sensor
reading
K factors programmed into FFM100
Resolution
0.1 LPH
(0.026 GPH)
Certifications
Parameter
Comment
NMEA 2000®
Level A
Maritime Navigation and Radiocommunication Equipment & Systems
Maritime Navigation and Radiocommunication Equipment & Systems
FCC and CE Mark
IEC 61162-3
Tested to IEC 60945
Electromagnetic Compatibility
NMEA 2000® Parameter Group Numbers (PGNs) - See Appendix A for Details
Description
PGN #
PGN Name
Default Rate
Periodic Data PGNs
127489 Engine Parameters, Dynamic
127497 Trip Parameters, Engine
130312 Temperature
2 Times/Second
1 Time/Second
0.5 Times/Second
Response to Requested PGNs
Protocol PGNs
126464 PGN List (Transmit and Receive)
126996 Product Information
126998 Configuration Information
059392 ISO Acknowledge
059904 ISO Request
060928 ISO Address Claim
065240 ISO Address Command
126208 NMEA
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
Maretron Proprietary PGNs
128720 Configuration
Electrical
Parameter
Value
Comment
Operating Voltage
9 to 32 Volts
DC Voltage
Power Consumption
Load Equivalence Number (LEN)
Reverse Battery Protection
Load Dump Protection
150mA
3
Yes
Yes
Maximum Current Drain
NMEA 2000® Spec. (1LEN = 50mA)
Indefinitely
Energy Rated per SAE J1113
Mechanical
Parameter
Size
Value
Comment
Including Flanges for Mounting
3.50” x 4.20” x 2.03”
(88.9mm x 106.7mm x 51.6mm)
13 oz. (368.5 g)
Weight
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FFM100 User’s Manual
Environmental
Parameter
Value
IEC 60945 Classification
Degree of Protection
Operating Temperature
Storage Temperature
Relative Humidity
Vibration
Exposed
IP64
-25°C to 55°C
-40°C to 70°C
93%RH @40° per IEC60945-8.2
2-13.2Hz @ ±1mm, 13.2-100Hz @ 7m/s2 per IEC 60945-8.7
Ultraviolet B, A, Visible, and Infrared per IEC 60945-8.10
Solar Radiation
Corrosion (Salt Mist)
4 times 7days @ 40°C, 95%RH after 2 hour Salt Spray Per IEC 60945-8.12
Conducted and Radiated Emission per IEC 60945-9
Conducted, Radiated, Supply, and ESD per IEC 60945-10
Dangerous Voltage, Electromagnetic Radio Frequency per IEC 60945-12
Electromagnetic Emission
Electromagnetic Immunity
Safety Precautions
7 Technical Support
If you require technical support for Maretron products, you can reach us in any of the following
ways:
Telephone: 1-866-550-9100
Fax: 1-602-861-1777
E-mail: [email protected]
Mail: Maretron, LLP
Attn: Technical Support
9014 N. 23rd Ave Suite 10
Phoenix, AZ 85021 USA
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8 Installation Template
Please check the dimensions before using the following diagram as a template for drilling the
mounting holes because the printing process may have distorted the dimensions.
Figure 9 – Mounting Surface Template
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FFM100 User’s Manual
9 Maretron (2 Year) Limited Warranty
Maretron warrants the FFM100 to be free from defects in materials and workmanship for two (2) years from the
date of original purchase. If within the applicable period any such products shall be proved to Maretron’s
satisfaction to fail to meet the above limited warranty, such products shall be repaired or replaced at Maretron’s
option. Purchaser's exclusive remedy and Maretron’s sole obligation hereunder, provided product is returned
pursuant to the return requirements below, shall be limited to the repair or replacement, at Maretron’s option, of
any product not meeting the above limited warranty and which is returned to Maretron; or if Maretron is unable to
deliver a replacement that is free from defects in materials or workmanship, Purchaser’s payment for such
product will be refunded. Maretron assumes no liability whatsoever for expenses of removing any defective
product or part or for installing the repaired product or part or a replacement therefore or for any loss or damage
to equipment in connection with which Maretron’s products or parts shall be used. With respect to products not
manufactured by Maretron, Maretron’s warranty obligation shall in all respects conform to and be limited to the
warranty actually extended to Maretron by its supplier. The foregoing warranties shall not apply with respect to
products subjected to negligence, misuse, misapplication, accident, damages by circumstances beyond
Maretron’s control, to improper installation, operation, maintenance, or storage, or to other than normal use or
service.
THE FOREGOING WARRANTIES ARE EXPRESSLY IN LIEU OF AND EXCLUDES ALL OTHER EXPRESS OR
IMPLIED WARRANTIES, INCLUDING BUT NOT LIMITED TO THE IMPLIED WARRANTIES OF
MERCHANTABILITY AND OF FITNESS FOR A PARTICULAR PURPOSE.
Statements made by any person, including representatives of Maretron, which are inconsistent or in conflict with
the terms of this Limited Warranty, shall not be binding upon Maretron unless reduced to writing and approved by
an officer of Maretron.
IN NO CASE WILL MARETRON BE LIABLE FOR INCIDENTAL OR CONSEQUENTIAL DAMAGES, DAMAGES
FOR LOSS OF USE, LOSS OF ANTICIPATED PROFITS OR SAVINGS, OR ANY OTHER LOSS INCURRED
BECAUSE OF INTERRUPTION OF SERVICE. IN NO EVENT SHALL MARETRON’S AGGREGATE LIABILITY
EXCEED THE PURCHASE PRICE OF THE PRODUCT(S) INVOLVED. MARETRON SHALL NOT BE SUBJECT
TO ANY OTHER OBLIGATIONS OR LIABILITIES, WHETHER ARISING OUT OF BREACH OF CONTRACT OR
WARRANTY, TORT (INCLUDING NEGLIGENCE), OR OTHER THEORIES OF LAW WITH RESPECT TO
PRODUCTS SOLD OR SERVICES RENDERED BY MARETRON, OR ANY UNDERTAKINGS, ACTS OR
OMISSIONS RELATING THERETO.
Maretron does not warrant that the functions contained in any software programs or products will meet
purchaser’s requirements or that the operation of the software programs or products will be uninterrupted or error
free. Purchaser assumes responsibility for the selection of the software programs or products to achieve the
intended results, and for the installation, use and results obtained from said programs or products. No
specifications, samples, descriptions, or illustrations provided Maretron to Purchaser, whether directly, in trade
literature, brochures or other documentation shall be construed as warranties of any kind, and any failure to conform
with such specifications, samples, descriptions, or illustrations shall not constitute any breach of Maretron’s limited
warranty.
Warranty Return Procedure:
To apply for warranty claims, contact Maretron or one of its dealers to describe the problem and determine the
appropriate course of action. If a return is necessary, place the product in its original packaging together with
proof of purchase and send to an Authorized Maretron Service Location. You are responsible for all shipping and
insurance charges. Maretron will return the replaced or repaired product with all shipping and handling prepaid
except for requests requiring expedited shipping (i.e. overnight shipments). Failure to follow this warranty return
procedure could result in the product’s warranty becoming null and void.
Maretron reserves the right to modify or replace, at its sole discretion, without prior notification, the warranty listed
above. To obtain a copy of the then current warranty policy, please go to the following web page:
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Appendix A – NMEA 2000® Interfacing
FFM100 NMEA 2000® Periodic Data Transmitted PGNs
PGN 130312 –Temperature
The FFM100 uses this PGN to provide a regular transmission of fluid temperatures. The
factory default for periodic transmission rate is once every two seconds. The transmission of
this PGN can be disabled (see PGN 126208 – NMEA Request Group Function – Transmission
Periodic Rate).
Field 1: SID – The sequence identifier field is used to tie related PGNs together.
2: Temperature Instance – The FFM100 sets this field to identify a particular
temperature measurement from the source specified in Field 3. Every temperature
measurement from a given source type on the network should have a distinct
instance value, so that monitoring devices and displays can identify which
measurement is which.
3: Temperature Source – This field is used to indicate the type of temperature
measurement being taken. Possible values for this field include Sea Temperature,
Outside Temperature, Inside Temperature, Engine Room Temperature, Main Cabin
Temperature, Live Well Temperature, Bait Well Temperature, Refrigeration
Temperature, Heating System Temperature, and Freezer Temperature.
4: Actual Temperature – This field is used to indicate the temperature, whose source is
specified in field 2, in units of 0.01°C.
5: Set Temperature – The FFM100 sets this field to a reserved NMEA 2000 value
indicating “Data Not Available”.
6: Reserved bits – The FFM100 sets all bits in this field to a value of “1”.
PGN 127489 – Engine Parameters, Dynamic
The FFM100 uses this PGN to transmit fluid flow rate information. The factory default for
periodic transmission rate is twice per second. The transmission of this PGN can be disabled
(see PGN 126208 – NMEA Request Group Function – Transmission Periodic Rate).
Field 1: Engine Instance – (8-bit unsigned integer) This field indicates the particular engine
for which this data applies. A single engine will have an instance of 0. Engines in
multi-engine boats will be numbered starting at 0 at the bow of the boat incrementing
to n going in towards the stern of the boat. For engines at the same distance from the
bow are stern, the engines are numbered starting from the port side and proceeding
towards the starboard side.
2: Engine Oil Pressure – (16-bit unsigned integer) The FFM100 sets this field to a
reserved NMEA 2000 value indicating “Data Not Available”.
3: Engine Oil Temperature – (16-bit unsigned integer) The FFM100 sets this field to a
reserved NMEA 2000 value indicating “Data Not Available”.
4: Engine Temperature – (16-bit unsigned integer) The FFM100 sets this field to a
reserved NMEA 2000 value indicating “Data Not Available”.
5: Alternator Potential – (16-bit signed integer) The FFM100 sets this field to a reserved
NMEA 2000 value indicating “Data Not Available”.
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6: Fuel Rate – (16-bit signed integer) This field indicates the fuel consumption rate of
the engine in units of 0.0001 cubic meters / hour.
7: Total Engine Hours – (32-bit unsigned integer) The FFM100 sets this field to a
reserved NMEA 2000 value indicating “Data Not Available”.
8: Engine Coolant Pressure – (16-bit unsigned integer) The FFM100 sets this field to a
reserved NMEA 2000 value indicating “Data Not Available”.
9: Fuel Pressure – (16-bit unsigned integer) The FFM100 sets this field to a reserved
NMEA 2000 value indicating “Data Not Available”.
10: Reserved – (8 bits) The FFM100 sets all bits in this field to a value of “1”.
11: Engine Discrete Status 1 – (16 bits) The FFM100 sets all bits in this field to a value of
“0”.
12: Engine Discrete Status 2 – (16 bits) The FFM100 sets all bits in this field to a value of
“0”.
13: Percent Engine Load – (8-bit signed integer) The FFM100 sets this field to a reserved
NMEA 2000 value indicating “Data Not Available”.
14: Percent Engine Torque – (8-bit signed integer) The FFM100 sets this field to a
reserved NMEA 2000 value indicating “Data Not Available”.
PGN 127497 – Trip Parameters, Engine
The FFM100 uses this PGN to transmit more slowly changing engine data. The factory default
for periodic transmission rate is once per second. The transmission of this PGN can be
disabled (see PGN 126208 – NMEA Request Group Function – Transmission Periodic Rate).
Field 1: Engine Instance – (8-bit unsigned integer) This field indicates the particular engine
for which this data applies. A single engine will have an instance of 0. Engines in
multi-engine boats will be numbered starting at 0 at the bow of the boat incrementing
to n going in towards the stern of the boat. For engines at the same distance from the
bow are stern, the engines are numbered starting from the port side and proceeding
towards the starboard side.
Field 2: Trip Fuel Used – (16-bit unsigned integer) This field indicates the total fuel used since
the counter was last reset with a resolution of 0.001 cubic meters.
Field 3: Fuel Rate, Average – (16-bit signed integer) The FFM100 sets this field to a reserved
NMEA 2000 value indicating “Data Not Available”.
Field 4: Fuel Rate, Economy – (16-bit signed integer) This field indicates the current fuel
consumption rate with a resolution of 0.0001 cubic meters / hour.
Field 5: Instantaneous Fuel Economy – (16 bit signed integer) This field indicates the current
fuel consumption rate with a resolution of 0.0001 cubic meters / hour.
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Appendix A – NMEA 2000® Interfacing
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