JPI EDM 900, EDM 930 Engine data management system Installation Manual
Below you will find brief information for Engine data management system EDM 900, Engine data management system EDM 930. These systems provide a comprehensive suite of engine and aircraft system parameters, including RPM, manifold pressure (MAP), cylinder head temperature (CHT), and more. The EDM 900/930 display can be customized to show primary data for your specific aircraft and can be integrated with a GPS system for navigation and fuel management capabilities.
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FAA Approved Installation Manual for the
Report No 908
EDM-900 and EDM-930 Page 1 of 50 Rev J
Primary Engine Data Management System Date 5-24-14
TABLE OF CONTENTS
Section Page
1.
Revisions ______________________________________________________________________________________ 2
2.
Read This First _________________________________________________________________________________ 2
3.
Instrument Labeling______________________________________________________________________________ 3
4.
Primary TSO Label ______________________________________________________________________________ 3
5.
Operation and Abbreviations ______________________________________________________________________ 4
6.
Remote Alarm Light EDM 900 _____________________________________________________________________ 5
7.
Locating and Installing the Indicator and Remote Alarm Display (RAD and Alert Light) ________________________ 8
8.
EDM-900/930 Key information installation __________________________________________________________ 10
9.
Routing the Wiring Harnesses _____________________________________________________________________ 11
10.
Pressurized Aircraft wire Routing __________________________________________________________________ 11
11.
Power Connection ______________________________________________________________________________ 12
12.
Probe Wiring __________________________________________________________________________________ 12
13.
Exhaust Gas Temperature Probe (EGT) Installation ___________________________________________________ 13
14.
Cylinder Head Temperature (CHT) Probe Installation__________________________________________________ 14
15.
Radial Engine CHT (spark plug gasket) _____________________________________________________________ 14
16.
Outside Air Temperature (OAT) Probe Installation ____________________________________________________ 14
17.
Oil Temperature Probe Installation ________________________________________________________________ 15
18.
Oil Pressure Sensor Installation ___________________________________________________________________ 15
19.
Fuel Pressure Sensor Installation using combination sensor _____________________________________________ 16
20.
Ammeter Shunt Installation _______________________________________________________________________ 17
21.
General Fuel Flow Transducer Installation __________________________________________________________ 18
22.
Fuel Level Sender Wiring Types ___________________________________________________________________ 20
23.
Fuel Flow Totalizer, Refuel Question _______________________________________________________________ 26
24.
GPS Interface _________________________________________________________________________________ 27
25.
Manifold Pressure (MAP) Sensor __________________________________________________________________ 27
26.
RPM Sensor installation _________________________________________________________________________ 28
27.
EDM-900/930 Specifications and Limitations_________________________________________________________ 30
28.
EMI Radio Test and functional check: ______________________________________________________________ 31
29.
Component Parts _______________________________________________________________________________ 32
30.
Weight and Balance Data ________________________________________________________________________ 34
31.
Pilot Programming _____________________________________________________________________________ 34
32.
Programming the HP Constant ____________________________________________________________________ 35
33.
Programming the MAP __________________________________________________________________________ 35
34.
Selecting Fuel Pressure Type (EDM-900 only) ________________________________________________________ 35
35.
Customizing Non-Primary Data (EDM900 only) ______________________________________________________ 36
36.
K Factor______________________________________________________________________________________ 36
37.
Fine tuning the K Factor _________________________________________________________________________ 37
38.
Adjusting the K Factor___________________________________________________________________________ 38
39.
Programming Accumulate Trip Total _______________________________________________________________ 38
40.
Trouble Shooting _______________________________________________________________________________ 39
41.
GPS Interface Diagnostics _______________________________________________________________________ 40
42.
Connector Pin Assignments on EDM, J1 through J5 _______________________________________________ 41
43.
Connector Pin Assignments on EDM, J1 through J5 ___________________________________________________ 42
44.
J3 RPM, MP, Oil-P_____________________________________________________________________________ 45
45.
Appendix A Connector Pin Assignments on EDM, J1-J2 Only with ARINC 42 ______________________________ 49
46.
Appendix B ICA _______________________________________________________________________________ 50
The Owner of the EDM-900/930 must keep this manual
J.P. INSTRUMENTS
PO BOX 7033
HUNTINGTON BEACH CA
Last printed 6/2/2014 10:18:00 AM
FAA Approved Installation Manual for the
EDM-900 and EDM-930
Report No 908
Page 2 of 50 Rev J
Primary Engine Data Management System Date 5-24-14
1. Revisions
REV Description
G
H
Added new pictures of 900 and 930, page 6. Abbreviations page 4. Revised how the
JPI data base functions, page 3. Added revision box. Page 2. Added fuel level calibration, page 22. Renumbered all pages.
Revised to include new trouble shooting section for ICA and renumber pages. Updated pressure sensors to i2s
Revised TSO Label to show lighting change and added ARINC 429 wire chart
I
J
Updated Part Numbers and Added new ICA and Pressure bulkhead paragraph
Date Approval
9-28-2011 JFP
12-02-2011 JFP
1-18-2013 JFP
5-24-2014 JFP
2. Read This First
The following notes apply to a new installation. Read this section before proceeding.
The JPI warranty found in the back of the pilots guide clearly states that JPI will replace defective parts under warranty, but does NOT cover labor to remove or install any parts.
The most common cause of probe problems is poor terminal crimps. Crimp ring terminals with AMP tool or equivalent. Fold back the wire double before crimping terminals.
Do not use aluminum fittings or Teflon tape or pipe sealant with the FXT-201 or FXT-231 fuel flow transducer.
Write down the K-factor engraved on the side of the fuel flow transducer here _______. Once the transducer is installed and covered with the fire sleeve, you will not be able to access this K factor.
Determine the locations of all holes before drilling to ensure that nothing interferes with the probe, clamp, clamp screw or wire.
Provide service loops at the instrument so that it can be moved for maintenance or troubleshooting.
Thermocouple wire length is not critical. Trim to required length, allowing for service loops at the engine so that probes can be swapped with probes on adjacent cylinders for troubleshooting purposes.
Dress all wires away from high temperature components such as exhaust stacks.
Never splice thermocouple wire using copper wire. Use only K-type thermocouple wire. Solder using zinc chloride flux such as Nokorode brand – rosin flux alone will not work.
Observe correct polarity on all probe wires. Connect like colors together (red to red, yellow to yellow).
The instrument must be grounded at the engine, not at the avionics ground.
Record the installation of the EDM-900 or EDM-930 on a FAA form 337. Make an entry in the aircraft logbook.
Note: Removal of probes, sensors and the instrument is the reverse of the installation procedure.
FAA Approved Installation Manual for the
EDM-900 and EDM-930
Report No 908
Page 3 of 50 Rev J
Primary Engine Data Management System Date 5-24-14
3. Instrument Labeling
The TSO label on the instrument is marked as to the instrument configuration.
The part number of the instrument is as follows:
Model designation system by part number for EDM-900/930
Model Number / Part Number Description
EDM-900 PN 790000-A- [XXX] TFT (liquid crystal) Type Display
EDM-930 PN 790000-C- [XXX] TFT (liquid crystal) Type Display
INSTRUMENTS THAT CAN BE PRIMARY IF IN POH NON-PRIMARY INSTRUMENTS
CHT
4-9
OIL
TEMP
OIL
PRESS
FUEL
FLOW
FUEL
PRESS
RAD
Alert Light
RPM CDT
4-9
CARB
Amps
IAT empty to WP
WP
MPG
Fuel Remaining
Fule USED
Shock Cooling
Differential EGT
Normalize
Percent of HP
Quantity
Example PN 790000-(X)-(XXX) (X) denotes EDM-900 or EDM-930, (XXX) denotes Part Number for a specific aircraft with or without and engine STC. Each PN is specific to a Make and Model Aircraft with or without
STC. In which the information is gathered from the Aircraft POH or STC Data sheet. w/engine STC No. if applicable
Cessna 182-P, STC12345NW
JPI assigned Data Base Part No. per
Limits found in the POH or engine STC for a specific aircraft
534
875
Part No. Displayed on 930
RAD at Start-up or 900 message area
790000-X-534
790000-X-875
4. Primary TSO Label
FAA Approved Installation Manual for the
EDM-900 and EDM-930
Report No 908
Page 4 of 50 Rev J
Primary Engine Data Management System Date 5-24-14
5. Operation and Abbreviations
The EDM-900/930 is a combined electronic indicating system which simultaneously displays to the pilot powerplant and aircraft systems operating parameters. It includes the following indicating systems; replacing all previous primary digital and/or analog instruments: Message Area Abbreviation in parenthesis. (X)* denotes cylinder No.
Gauge Function
Message Area
Alarm Abbreviation
Primary Primary
Engine rotational speed RPM xxxx
Engine Manifold Pressure
Engine Cylinder Head Temp
MAP xx.x in hg
CHT2 xxx o
F
Engine Oil Temperature O-T xxx o
F
Engine Oil Pressure O-P xxx o
F
Fuel Pressure F-P xx PSI
Fuel Flow to engine
Comp. Discharge Temp.
Turbine inlet Temp. Left side
Turbine Inlet Temp. Right side
Single Turbine Inlet Temp.
Non-Primary Non-Primary
Exhaust Gas Temp. EGT2 xxxx o
F
Shock Cooling of CHT
Differential Temp. of EGT
CLD xx o
/MIN
DIF xx o
F
Bus Voltage
Amperage Load
Outside Air Temp.
Estimated Time to Empty
F-F xx.x GPH
CDT xxx o
F
TIT-L xxxx o
F
TIT-R xxxx o
F
TIT xxxx o
F
Volts xx.x
AMPS xx
OAT xx o
F
Est. T to E xx:xx H:M
Fuel used to date
Estimated Remaining fuel
USED xx.x GAL
Est. REM xx GAL
Estimated Fuel required to Waypoint Est. WP REQ xx GAL
Estimated Fuel Remaining at Waypoint
Nautical Miles per Gallon
Brightness, Dim control
Est. WP RES xx GAL
ECON xx.x MPG
DIM/BRT
FAA Approved Installation Manual for the
EDM-900 and EDM-930
Report No 908
Page 5 of 50 Rev J
Primary Engine Data Management System Date 5-24-14
6. Remote Alarm Light EDM 900
The remote alarm light is a Red or Yellow light depending on the alarm condition. The EDM-900 incorporates a single light that alerts the pilot that a problem existing within the engine. This light is place in with the primary flight instruments and required only if the display is more than 8 inches from the center of the instrument “T” to a max of
21 inches. It is a single light that changes color with condition and the label associated with the light must be lit by a post light or such that you can see the word “ENGINE”.
6.1
Remote Alarm Display (RAD) Operation EDM-930
The RAD is a 0.2” high, 8 character independent display found on the EDM-930 only. The RAD will still function if the main display is inoperable. An alarm—such as the CHT is 480° on cylinder number 2—is displayed as
480CHT2. The label CHT2 will flash whenever an over-temperature exists and will extinguish when the temperature falls below the limit temperature. Other alarms would be displayed as, for example: 2780 RPM.
The RAD is located directly in front of the pilot and displays digital caution and limit excedances when any of the parameters have reached its preset trigger point. Whenever limit alarms are not triggered, the RAD continuously displays MAP and RPM.
On initial startup or whenever power is turned on, the words EDM-930 PRIMARY” are displayed, followed by the make and model of the aircraft with STC information for which the primary limits were set
Alarm hierarchy for the EDM-900/930
When a measurement limit is reached, the pilot should momentarily depress the STEP button on the EDM-900/930 instrument to extinguish the particular flashing alarm acronyms. If another function has also reached its limit, that label will then begin to flash. The pilot should continue to monitor the affected parameters as he would if a conventional analog display had reached a limit. The bar graph functions of CHT, EGT, and TIT remain displayed for easy reference should one of these limits be reached. Alarm hierarchy is shown in the table below.
1. OILP_LO.
2. FP_LO.
3. OILT_HI.
4. CHT.
5. TIT.
6. FLVL.
7. REM.
8. FP_HI.
9. MAP.
10. DIF.
11. CLD.
12. RPM.
13. OILT_LO.
14. VOLTS.
15. OILP_HI.
16. AMPS.
17. CDT.
18. RES.
19. EGT.
20. Fuel Flow.
6.2
Dimming
Automatic dimming is provided to dim both the panel display and the remote alarm display. Dimming can also be accomplished manually to change the Automatic setting. Button #3 initiates the manual Dim function and shows which button to press for Dim or Bright changes.
. The display starts up in the max brightness mode.
FAA Approved Installation Manual for the
EDM-900 and EDM-930
Report No 908
Page 6 of 50 Rev J
Primary Engine Data Management System Date 5-24-14
RAD
EDM-930 Display
FAA Approved Installation Manual for the
EDM-900 and EDM-930
Report No 908
Page 7 of 50 Rev J
Primary Engine Data Management System Date 5-24-14
EDM-900 TFT Flat panel display
Portrait Mode
Remote Alert Light
With the placard
“Engine”
EDM-900 TFT Flat panel display
Landscape Mode
EDM-900 system mounts in a 3.125 inch diameter instrument panel hole in either a portrait or landscape position depending on panel hole location. By holding the Step button ( first on left) for approx. 10 seconds and arrow will appear on the display showing which way the rotation will use as up. Use the LF (Second from left) button to index the rotation arrow. When the proper position is achieved, tap the step button Tap STEP to save the new rotation.
At this point properly the rotation will be saved and the unit will reboot to the new rotation. The rotation will not occur if the engine is running.
FAA Approved Installation Manual for the
EDM-900 and EDM-930
Report No 908
Page 8 of 50 Rev J
Primary Engine Data Management System Date 5-24-14
7. Locating and Installing the Indicator and Remote Alarm Display (RAD and Alert Light)
Single Engine Aircraft EDM-900/930
A) The EDM-900/930 display should be located as close as possible to the pilot with an unobstructed view and for easy access to the buttons on the instrument. The least desirable view angle is landscape looking up. To improve the view angle call the factory. A remote display is also provided for alarm indications and should be directly in front of the pilot.
B) The RAD PN-790749 mounts in a 5/8 inch hole in the panel directly in front of the pilot for the EDM-930 and an alert light for the EDM-900 is mounted in a 3/8 dia hole.
The diagram below should be used as a guide for cutting and drilling the mounting and buttonholes in the instrument panel. The dimensions shown are for the finished cutout. Allow extra clearance for any panel finish such as powder coat. The EDM mounts from behind the panel through this cutout. Fabricate the appropriate cut-out using the fig below as a guide. If the panel has too many holes for a clean installation, it is recommended that a
0.10” aluminum overlay panel be constructed and installed over the original instrument panel and the EDM be installed into this overlay panel. The Remote Alarm Display PN-790749 mounts in a 5/8 inch hole in the panel immediately above the Attitude Gyro / D.G. / HSI +/- 0.5 inches from their centerline directly in front of the pilot.
4.1 Figure 1:
FAA Approved Installation Manual for the
EDM-900 and EDM-930
Report No 908
Page 9 of 50 Rev J
Primary Engine Data Management System Date 5-24-14
Mounting bracket for the EDM-900
EDM-900 Model:
Mounts in a standard 3.1/8” instrument hole. First, place the mounting bracket on the instrument and tighten the clamp hex screw until you can just remove the instrument from the bracket. The
Mounting bracket is then placed behind the instrument panel hole and screwed (6-32 x ½” screws) in place using the existing holes. Three screws should be used leaving one hole vacant on either side of the hex screw. Locate the hex screw in a location that you can easily get to from the rear of the panel. The body of the instrument is 3.0 inches in diameter and 2.0 inches deep less connectors.
FAA Approved Installation Manual for the
EDM-900 and EDM-930
Report No 908
Page 10 of 50 Rev J
Primary Engine Data Management System Date 5-24-14
5. EDM Display Installation
Choose the Proper Installation Location
The display is best located within the natural scan and easy reach of the pilot. The recommended mounting location is defined as the distance from the vertical centerline of the Primary Flight Instruments to the outer edge of the further most gauge displayed on the EDM.
HORIZONTAL ORIENTATION:
The EDM display may be mounted from the vertical centerline of the Primary Flight Instrument “T” to a maximum of
21” to the further most gauge of the EDM display and to the left of the centerline as much as needed.
VERTICAL ORIENTATION:
The EDM display is to be mounted within +/- 10” from the horizontal centerline of the Primary Flight
Instrument “T”. The installer should insure that the EDM display is not obstructed by either the glare shield or the control wheel.
The installing A&P and IA must insure that the installation location complies with the viewing angle requirements listed above.
8. EDM-900/930 Key information installation
Aircraft specific configuration information is loaded differently on both the EDM-900 and the EDM-930. The configuration data is the same for both instruments. The data for the EDM-900/930 is loaded via the mini USB port on the EDM-900 and a standard USB port for the EDM-930.
FAA Approved Installation Manual for the
EDM-900 and EDM-930
Report No 908
Page 11 of 50 Rev J
Primary Engine Data Management System Date 5-24-14
Be sure to verify that this matches your aircraft.
Note: If your EDM should ever have to be replaced with a different unit, the factory will reprogram it to match your configuration. You should always retain your fuel quantity calibration records, as these may need to be manually reentered in a different or serviced unit.
9. Routing the Wiring Harnesses
Five connectors are protruding from the rear of the instrument. Connect the five wiring harnesses to the rear of the instrument and run the cables through the firewall into the engine compartment. Allow sufficient service loop to facilitate removal of the connectors for servicing. These wiring harnesses are labeled as follows:
P1 790200
P2 700700
700702
P3 790422
P4 700708
P5 790723
RAD 790749
Power, Engine ground, MFD input, MFD output the following are optional and need to be added : Oil temperature, Induction temperature, Carburetor temperature,
Outside air temperature, Turbine inlet temperature, Turbine inlet temperature 2,
CHT, EGT 6 cylinder
CHT, EGT 4 cylinder
RPM, MAP, Oil pressure
Serial data to GPS, Serial data from GPS, Fuel flow transducer
Fuel Pressure, Fuel Level (Resistive and Capacitive ), Amps
Category 5 jack and cable for RAD (Remote Alarm Display)
Route the wires from the connectors through the firewall using rubber grommets and flame retarding silicone. Use an existing hole if possible. All wires must be routed away from high temperature areas (exhaust stacks, turbochargers, etc.). Secure probe and sensor leads to a convenient location on the engine approximately 8 to 12 inches from the probe or sensor, being sure there is sufficient slack to absorb engine torque. It is essential in routing the probe wire that this wire not be allowed to touch metal parts of the air-frame or engine since abrasion will destroy this high temperature wire. Secure wires along the route to the indicator. Secure wire using original clamps, tape or tie wrap if possible.
Note: The probe wires must not be tied in with ignition, alternator or engine cabin heater ignition wires or transceiver coax cables because of potential induced interference with readings.
The temperature probe wiring harness is made of Chromel-Alumel alloy wires that must not be substituted or
extended with copper wire. Temperature probe leads must be spliced with the same type of wire (typically
Chromel-Alumel for JPI temp probes) using copper butt splices. The other signal and power wires are made from normal copper and must meet MIL-W-32759/16 or equivalent.
CAUTION: Be sure the installation does not result in interference with any aircraft control movements.
When the installation is complete all wires should be secured using ties and carefully checked for interference, rubbing or chafing with flight controls and associated cables or any other moving parts.
10. Pressurized Aircraft wire Routing
Pressurized Aircraft have a factory installed pressure bulkhead pass thru boot or connector at the pressure vessel or firewall where all electrical wires from the engine pass through to the cockpit. If you can not find the opening follow the wires from the engine to the pressure vessel. If a boot with sealant is used, remove the sealant, pass the signal wires from the transducers mounted in the engine compartment to the display unit. Upon accomplishing this reseal the opening with factory recommended sealant.
An alternate method for a cannon connector is to use existing wires in the aircraft going thru the pressure bulkhead.
The EDM-900/930 replaces the RPM, MAP, CHT, Oil Temperature, Oil Pressure Fuel Pressure, Fuel Flow and TIT gauges which have wires going thru the pressure bulkhead. Making a new hole in the pressure bulkhead is beyond the scope of this document and will require a DER or other FAA approval.
FAA Approved Installation Manual for the
EDM-900 and EDM-930
Report No 908
Page 12 of 50 Rev J
Primary Engine Data Management System Date 5-24-14
11. Power Connection
The EDM automatically adapts to either a 14 or 28-volt electrical system. Master Bus power wire to the EDM should be 20ga copper connected directly to the master solenoid located at the battery to avoid a line drop when cranking. A 5 amp circuit breaker is required. Connect the EDM ground wire to the engine block. The instrument is designed to reset at less than 10vdc bus power, therefore the instrument may reset on engine start
(typical for 14vdc systems). For lighting, no connection to the aircraft dimmer system is required because the instrument dims automatically with reductions in ambient light. Required power for 900 or 930 is 1.0 amp at 14vdc
12. Probe Wiring
When cutting the pair of leads to the proper length to connect to the probes, leave enough slack in the wiring so that probe may be interchanged to an adjacent cylinder if necessary for trouble-shooting and servicing.
Thermocouple wire length is not critical and should be trimmed to any length as required for a clean installation.
The Temperature probe must be wired with the correct polarity. The temperature probe connects to its temperature indicator with yellow jacket Teflon Chromel Alumel wire supplied. Strip the wires as shown below—observing colorcoding.
Thermocouple wire harness
2 1/4" yellow
Fold back wire double before crimping terminals red
1/4" 1 1/2"
Terminate each wire with a crimp-on ring terminal, provided. The ring terminals may be crimped with an AMP part number 48518 crimp tool is recommended however, a “service-type” tool may also be used. Verify the quality of each crimp with a sharp tug on the wire. The terminal should be impossible to pull off when crimped correctly. ring terminal shrink tubing
Place a ¼ x 4-inch sleeve over each pair of wires in the wiring. Connect the wire ring lug to the probe ring lug using the supplied number 4 screws and nuts, placing the star washer between the ring lugs, not against the nut. to instrument
Important: place star waster between two ring terminals and tighten nut and bolt as necessary to probe
Slide the sleeve over the joint and secure with three tie-wraps.
1/4 x 4" sleeve tie-wrap 3 places
The most common installation problems are related to poor quality terminations.
12.1
Wiring Markings
The EDM-900/930 is supplied with special Teflon insulated Chromel Alumel factory assembled wiring harness configured for the correct number of cylinders. The wire harness is marked E1= EGT-1, C1= CHT-1, etc.
NOTE: Unlike most other EGT & CHT installations the probe wire length is not critical and should be trimmed to any length as required for a clean installation. Do not extend the thermocouple wire with
copper wire.
FAA Approved Installation Manual for the
EDM-900 and EDM-930
Report No 908
Page 13 of 50 Rev J
Primary Engine Data Management System Date 5-24-14
13. Exhaust Gas Temperature Probe (EGT) Installation
Use the J2 connector harness 700700 or 700702 labeled E1 through E4 or E6. Remove the existing EGT gauge and Probe. Replace with JPI probe M-111 in all exhaust stacks.
CHT probe
EGT probe
Drill no. 40 pilot hole, then no. 30 hole.
2" to 4"
The Model M-111 Probe will fit any engines where the existing holes in the exhaust stack are 1/8" to
1/4" in diameter. If no hole exists, it will require the drilling of a 1/8" diameter hole and ream to fit. It is important that each probe be mounted the same distance from its exhaust stack flange. A nominal distance of 2 to 4 inches from the exhaust flange is recommended. If the recommended distance is
impractical because of obstructions, slip joints or bends in the exhaust system then position the probes a uniform distance from the flange as space permits. Do not mount probes in slip joints. Be certain to locate all holes BEFORE drilling to ensure that nothing interferes with the probe, clamp, screw or wire. Careful matching of probe position will provide best temperature readings.
Insert the probe in the exhaust or previously drilled hole so that the tip of the probe is in the center of the exhaust
stream. Tighten the stainless steel clamp to a torque of 45 in/Lbs. Cut off the excess strap close to the screw.
Clamp
Seal Washer
Thimble note orientation of slot
Probe
Position probe in approximate center of exhaust
13.1
R
ADIAL
Engine EGT
Radial engine exhaust, require a larger EGT clamp (supplied) to fit the 2.5 inch exhaust pipe. The EGT probe is installed in the same fashion as a Lycoming or Continental engine and should be placed between the exhaust pipe flange and the accumulator at a distance of 2 to 3 inches from the engine exhaust flange. Refer to the engine manufactures recommended location. Do not route the EGT/CHT harness in with the ignition harness. Do not extend the yellow thermocouple leads with copper wire.
13.2
Turbine Inlet Temperature (TIT) Probe Installation (optional)
Use the J1 connector harness 790200 and insert the yellow wire into the connector pin 16 and the red wire into pin
17. The standard TIT probe PN M111-T with a #48 clamp is placed in the exhaust stack accumulator to a maximum depth of 1/2 inch and approximately 4 inches from the turbine inlet if possible, on the waste-gate side of the turbine.
FAA Approved Installation Manual for the
EDM-900 and EDM-930
Report No 908
Page 14 of 50 Rev J
Primary Engine Data Management System Date 5-24-14
13.3 TIT for second Turbine Inlet Temperature
Use the J1 connector harness 790200 and insert the yellow wire into the connector pin 18 and the red wire into pin
19. The standard JPI TIT probe P/N M-111-T with a special clamp is placed in the exhaust stack accumulator to a
maximum depth of 1/2 inch and approximately four inches from the Turbine inlet if possible, on the waste gate side of the turbine.
13.4
Using the Factory original TIT Probe
The factory installed TIT probe (K-calibration) is compatible with the JPI EDM-900/930 System. Connect the JPI wire marked TIT in parallel with the factory probe noting color polarity. Replacement probes should be purchased per part number from the aircraft manufacturer.
If you choose to use only the EDM-900/930 TIT display you may remove the factory installed TIT indicator and leave the TIT probe installed. Connect the JPI wire marked TIT directly to the probe noting color polarity. The TIT probe should now have only the JPI leads attached to it. No calibration of the EDM-900/930 is necessary.
14. Cylinder Head Temperature (CHT) Probe Installation
Use the J2 connector harness 700700 or 700702 labeled C1 through C4 or C6. The JPI probe is a bayonet probe
P/N 5050-T that has a captive 3/8-24 boss that is screwed into the head of each cylinder.
15. Radial Engine CHT (spark plug gasket)
Cylinder head temperatures are measured with a spark plug gasket type probe placed under the front sparkplugs.
Front spark plugs will read 15 to 20 degrees cooler than the rear plugs.
The spark plug gasket probe, P/N M-113, replaces the standard copper spark plug gasket on one spark plug. The probe is usually placed on the plug that receives the most direct cooling air. After many removals the probe may be annealed for re-use. Heat to 1100 o
F and quench in water.
16. Outside Air Temperature (OAT) Probe Installation
Use the J1 connector harness
790200 labeled OAT. All wiring must be type K thermocouple wire. Do not splice ordinary copper wire in any temperature probe circuits. aircraft sheet metal shield tube used to secure probe probe
Install the OAT probe, PN 400510 in the airframe manufacturer’s washer washer recommended location. If this information is not available, place the OAT probe in clean airflow such as in a cabin air scoop or below the underside of the wing away from engine heat or exhaust. In this case it is recommended that the installation be done similar to the antenna installation instructions of AC 43.13-2b Acceptable Methods,
Techniques and Practices.
The outside aluminum shield tube is used to both hold the probe in place and shield it from radiated heat from the sun. The OAT option is displayed as an independent digital temperature bar graph such as "75.”
16.1
Induction Air (IAT), Compressor Discharge Temperature Probe Install (optional)
Use the J1 connector harness 790200 and insert the yellow wire into the connector pin 3 and the red wire into pin
4. All wiring must be type K thermocouple wire. The Induction Air Temperature probe, (IAT), is installed just after the inter-cooler and the Compressor Discharge Temperature (CDT) just before the inter-cooler. The probe is the same as an EGT probe and installed similarly to an EGT probe. A large clamp is supplied to fit around the air duct leaving the inter-cooler. Alternately a 1/8 NPT fitting is available. IAT option is displayed as an independent digital
FAA Approved Installation Manual for the
EDM-900 and EDM-930
Report No 908
Page 15 of 50 Rev J
Primary Engine Data Management System Date 5-24-14
temperature like "125 IAT". On non-turbo engines the IAT in reality is the Carburetor temperature and displayed as
“34 CRB.”
16.2
Carburetor Probe Installation (optional)
Use the J1 connector harness 790200 and insert the yellow wire into the connector pin 5 and the red wire into pin
6. All wiring must be type K thermocouple wire. Do not splice ordinary copper wire in any temperature probe circuits. Locate the access hole (1/4-24 thread) in the carburetor near the butterfly valve. Remove the screw plug now in that hole and screw the CRB probe into the carburetor throat. No drilling or machining of the carburetor is necessary.
17. Oil Temperature Probe Installation
The sensor port is a standard 5/8-18 thread for both the Continental and Lycoming engines. Probe PN 400509 is a complete assembly using type K thermocouple wire (red/yellow). Connect the wire marked oil temperature observing polarity to pin 1 and 2 on 790200. Wire length has no effect on the readings. Oil temperature will be displayed as an independent temperature digital and bar-graph. Check with engine manufactures proper location for oil temperature. Check for oil leaks before first flight.
18. Oil Pressure Sensor Installation
Use the J3 connector harness 790422 labeled OIL-P for a pressure sensor three wire i2s sensor (0-5vdc)
Oil pressure sensor mount using an aluminum clamp MS21919. Mount to firewall.
Mount the pressure sensor to the pressure line using a flexible hose and fittings (not supplied) as depicted in the drawing below. Use aluminum clamp to mount the pressure sensor to firewall. Do not mount the sensor directly to the engine. Connect the other end of the hose to the engine manufacturer’s recommended location for engine oil pressure.
FAA Approved Installation Manual for the
EDM-900 and EDM-930
Report No 908
Page 16 of 50 Rev J
Primary Engine Data Management System Date 5-24-14
18.1
Alternate method of installation keeping the original sensors in the aircraft operational
The oil pressure sensor should tee off the oil pressure line feeding the original aircraft gauge or the oil pressure switch is removed and the sender is installed in that location.
19. Fuel Pressure Sensor Installation using combination sensor
Use the J5 connector harness 790723.
Mount the pressure sensor to the pressure line using a flexible hose and fittings (not supplied) as depicted in the drawing below. Use Aluminum Clamps MS21919WDG25, or WDG14 to mount the pressure sensor to engine mount structure or firewall. Do not mount the sensor’s directly to the engine. Connect the other end of the hose to the existing pressure line. Later, you will connect the pressure sensor to the three pressure sensor wires through the supplied 3-pin connector. i2s sensor PN 159935A Normally Aspirated or Turbo-Normalized or PN 159938 for turbocharged. Fuel pressure sensors are only supplied if the POH requires it. If not in the POH Fuel pressure can be supplied at additional cost
FAA Approved Installation Manual for the
EDM-900 and EDM-930
Report No 908
Page 17 of 50 Rev J
Primary Engine Data Management System Date 5-24-14
19.1 Adding a non-primary gauge to the system
Requirements: All EDM930 and EDM960 units manufactured after Sep 15, 2012 have the EDM Configuration
Editor built into a separate utility memory area of the EDM.
To start the EDM Configuration Editor, hold the left two EDM buttons (STEP & LF) while powering up the
EDM. This will start the EDM in a special AppLoader mode. Once the EDM Configuration Editor program is found, a button will be labeled CFG EDITOR. Press the button to run the EDM Configuration Editor program.
Follow prompts and continue to the “Usage Agreement” page and press ACCEPT to continue.
Tap YES or NO for “SHOW CONFIGURATION TUTORIAL”. Tap NEXT to skip “RESTORE FROM USB
DRIVE?” Continue tapping NEXT until you see “EDIT GAUGES ?” Tap YES to begin the process. Using the NEXT button will scroll through the available non-primary gauges on the display. Once the gauge you wish to modify appears, tap MODIFY.
Tap NEXT until the title block “FUEL-P” or whatever non-primary gauge you selected is highlighted.
Tap MODIFY then YES when “Change Gauge Channel” appears.
Follow prompts to select a new gauge title.
Tap SAVE to save changes to the gauge, YES to confirm.
Tap DONE to exit gauge editing mode.
Tap NEXT repeatedly until “EDIT CHANNELS” is displayed.
Tap YES to edit channels. This will take you to the “EDM Probe & Sensor Channels” page. On this page you will see values for Primary gauges in RED which are not available for alteration. The values in
WHITE can be selected or deselected to be displayed on the EDM. An “X” in the box selects the gauge to be displayed.
Tap STEP several times to select FUEL PRESS or desired gauge input channel.
Tap ENABLE key to enable the input.
Tap SAVE, then YES to save change to channels.
Tap STEP key repeatedly until prompted to exit configuration, EDM will restart with FP or desired gauge enabled.
20. Ammeter Shunt Installation
Use the J5 connector harness 790723 labeled AMP+ and AMP-. Connect the harness leads using ring terminals to the smaller terminal screws on the side of the shunt.
20.1
Charge/Discharge configuration
The shunt can be installed between the master contactor and the main bus in which case it will be in the ammeter configuration showing battery charge and discharge. Be sure that the positive side of the shunt is connected to the main bus in the ammeter configuration. The alarm will be triggered by a discharge condition.
FAA Approved Installation Manual for the
EDM-900 and EDM-930
Report No 908
Page 18 of 50 Rev J
Primary Engine Data Management System Date 5-24-14
Master switch contactor
Alternator
F G
B
- BATT +
Master switch
Bus
+ external shunt
Starter Starter solenoid
Ammeter Configuration
- BATT +
Master switch
Starter
Master switch contactor
Starter solenoid
F G
B
Alternator
+ external shunt
Bus
Load Meter Configuration
20.2
Load Meter Configuration
Alternatively the shunt can be installed between the alternator output and the main bus in which case it will be the load meter configuration showing alternator load (positive only). Be sure that the negative side of the shunt is connected to the main bus in the load meter configuration. There is no alarm.
21. General Fuel Flow Transducer Installation
Use the J4 connector harness 700708 labeled FFSIG (white), FFPWR (red), and FFGND (black). If no previous fuel flow transducer is installed, install transducer per APPENDIX-A Report 503 FUEL FLOW TRANSDUCER
INSTALLATION.
FAA Approved Installation Manual for the
EDM-900 and EDM-930
Report No 908
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Primary Engine Data Management System Date 5-24-14
The EDM-900/930 receives signal from any installed FloScan Transducer with the following FloScan P/N’s embossed on to the top of the transducer. The K-Factor is marked on the side of the Transducer and on a white ticket. Wire per drawing 700744, Route the JPI wires along the existing wiring bundle lacing every foot.
The EDM is approved to work with the following Shadin equivalent PN.
FloScan PN Shadin equivalent PN
201-A NA
201-B 680501/680600
201-C NA
231 680503
Before connecting any hoses to the transducer, thoroughly clean them and insure they are free of any loose material. Never pass air pressure through the transducer or use Teflon tape/pipe cement; damage will
occur. Use only steel fittings supplied never use aluminum fittings on transducer. Remove the transducer cap plugs only when ready to install the hoses. Note the direction of fuel flow marked on the transducer. Fuel must flow in this direction. Reverse flow installations will read ½ the required flow. Mount the transducer with the three wires pointing up. The K-factor is printed on the side of the transducer and on a tag. Write down the K-factor here for future reference __________.
Aeroquip
900591B Clamp
Cut slit in fire sleeve
up
MS 21919
Clamp as required Transducer
Fittings 1/4 NPT. Do NOT use aluminum fittings
Aeroquip
303 hose
OUT
IN to carburetor, flow divider, or fuel injector
6 inches maximum from support
Aeroquip Fire Sleeve
AE102/62-24 from fuel tank, throttle body or engine driven fuel pump.
The EDM-900/930 fuel flow transducer receives signal from any installed 201 or 231 transducer with either of these part numbers embossed on to the top of the transducer. For specific engine Installations see Appendix A
Report 503
FAA Approved Installation Manual for the
EDM-900 and EDM-930
Report No 908
Page 20 of 50 Rev J
Primary Engine Data Management System Date 5-24-14
22. Fuel Level Sender Wiring Types
The EDM has the capability to interface to the aircraft’s fuel level system. It is also used to directly read the fuel senders for fuel calibration (no other equipment is needed). To implement the EDM fuel tank gauge functionality, the EDM is connected directly to the senders or in some cases to the aircraft’s fuel sender signal conditioner (for example the Pennycap system typically found in Cessna). The EDM has the capability to process signals from three types of sender signals: Resistive output, Voltage output or Frequency output. JPI provides the appropriate interface hardware (the P5 harness and any associated signal conditioners) based on information you provided when your order was placed. Once installation is completed, you will perform a fuel level calibration. The EDM stores this calibration internally. NOTE: The fuel quantity function will not be available until this calibration
has been performed successfully.
22.1
Capacitive Sender Frequency Output Type Sender System
Although frequency output type senders are uncommon in certified aircraft, JPI supports this interface. The P5 harness has two 3 conductor cables labeled LEFT TNK and RT TANK that are connected directly to the left and right senders. See the drawing below for basic connection information (only right tank shown for illustration purposes). Final route the LEFT TNK and RT TANK cables as necessary, then crimp the female contacts onto each cables GRN, BLK, RED wires, then insert them into the connector housing. Connect this to the sender’s cable connector. Connect the white wire of the pod cable to the center insulated terminal on the sender, and the black wire to the terminal mounted on the metal body on the sender. See illustration on following page.
22.2
Resistive Output Type Sender System (Float type, most common)
Locate the wires that run between the existing ships fuel gauges and the senders and disconnect them. For tanks that have more than one sender, the wiring between the senders must be retained. Make sure the senders do not have voltage on them before connecting to the EDM. Connect the EDM to the senders using the wire pairs coming from the signal conditioner as shown below. Note that one pair is for MAIN and the other is for AUX. Connect the
‘SIG’ wire to the senders signal terminal (typically the center stud) and the ‘GND’ wire to the closest ground terminal near or on that sender. See illustration on following page.
FAA Approved Installation Manual for the
EDM-900 and EDM-930
Report No 908
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Primary Engine Data Management System Date 5-24-14
Example harness arrangement for an aircraft with resistive output senders
Resistive Harness PN 790719-3
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EDM-900 and EDM-930
Report No 908
Page 22 of 50 Rev J
Primary Engine Data Management System Date 5-24-14
22.3
Voltage Output Type Sender System
Voltage output type systems usually have a convertor box. This is typical with the ‘Pennycap’ brand capacitive sender system. The Pennycap convertor box measures sender capacitance and converts it to a DC voltage output signal for the aircrafts fuel level gauge. In some cases the Pennycap convertor box alternately monitors two tanks per wing controlled by cockpit selector switch positions. This is typical for Cessna’s having 4 selectable tanks. The
EDM can interface to this system with the addition of the dashed interface hardware (PN 791802) shown below.
NOTE: This drawing is accurate for most models of the Pennycap system; however it is the installer’s responsibility to verify proper connections to the Pennycap output signal.
22.4
Fuel Tank Calibration Setting Fuel Calibration Points
The EDM interfaces to various fuel level sensor types to facilitate direct reading of the fuel level in the aircraft fuel tanks. The EDM has a multi-point fuel calibration table that you must enter. This table contains calibration values
(stored in non-volatile memory) used to translate sensor readings into the displayed fuel quantity values. The calibration information is collected and recorded on paper for later entry into the EDM. NOTE: Fuel quantity gauges will not be functional until the fuel calibration information has been entered into the EDM. You will use the EDM instrument itself as the measuring device to collect calibration data.
The following describes the basic procedures necessary for collection and entry of data into the fuel level calibration table. Note: Any changes to fuel table data will be temporary until you execute the ’SAVE’ function
(available after last cell of the last tank table is entered).
Before beginning the fuel table entry/edit process, you must have properly installed and tested for correct functionality of the fuel sensors.
WARNING:
Never add or remove fuel from the aircraft when the
master switch is turned on.
Fuel quantity gauge performance is affected by many
factors, such as the integrity of the sensor performance, the accuracy of the calibration data you collected and entered and most importantly your validation that the
EDM fuel quantity gauge is accurate and repeatable after installation and calibration. You should not use the fuel quantity gauge system for any flight related operations
until this validation criteria has been met.
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EDM-900 and EDM-930
Report No 908
Page 23 of 50 Rev J
Primary Engine Data Management System Date 5-24-14
Getting Started…Collecting Fuel Level Calibration Data using the
EDM as a meter
.
1. With power off, hold in Button 4 (Button 1 being far left) and then turn on power. For each EDM monitored tank, create a paper table with the desired number of calibration points (2 to 5) and at what volume each will be. Number of calibration points to be entered into the system later. The zero gallon point reading is always taken with unusable fuel in the tank. Example of a completed 3 point table for LEFT tank:
LEFT
F 39.0 1907
2 19.5 1154
E 0.0 GAL 685
Readings
2. This screen shown below provides real-time readings of all active fuel level sensors. Verify readings look normal. Reading are arbitrary whole numbers
3. Now add fuel as needed to match the required volume for a particular point. Cycle power between readings
(hold in button 4), then take a reading and record it on paper adjacent to that point.
4. Repeat this process until all points, 2 to 5, have been recorded for each tank.
With AUX it would say LMAIN and
LAUX
Actual Screen Shot
FAA Approved Installation Manual for the
EDM-900 and EDM-930
Report No 908
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Primary Engine Data Management System Date 5-24-14
22.4.1 After you have collected your data
After you have collected your data…Entering / Editing Fuel Level Calibration Data
The Fuel Table Editor is a spreadsheet type format allowing you to easily see the volume and related calibration values side by side. You can easily navigate through the cells to enter values.
1. With power off, hold in Button 3 (Button 1 being far left) and then turn on power. Wait until you see ‘Do
you agree with the disclaimer?’. Tap YES if you agree and wish to continue.
2. Tap YES when you see ‘Do you have table data?’.
FAA Approved Installation Manual for the
EDM-900 and EDM-930
Report No 908
Page 25 of 50 Rev J
Primary Engine Data Management System Date 5-24-14
3. Tap USER when you see ‘Do you want to restore user table?’
(Note: tapping FACTORY causes the fuel table stored on the Key Card to over-write any previous user entries in the fuel table. Use
FACTORY if you want to start from the original factory default).
5. You see ‘Points in LEFT’, the current calibration points for the LEFT tank.
6. Tap/hold
VALUE to change to the desired number of calibration points for this tank (2 to 5). Each
Tank can have a different set of calibration points. So 5 points for Main and 2 points for Aux.
FAA Approved Installation Manual for the
EDM-900 and EDM-930
Report No 908
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Primary Engine Data Management System Date 5-24-14
been set.
8.
Tap TABLE. You see ‘Fuel Table Data’ ( White at top of screen) with a table. You may change any of the fuel levels in the left column except for empty. You will enter the readings taken previously on paper into the right column. change digit. Tap digit to change another part of the number.
10. Tap SAVE to record it. Follow the on-screen menus to edit the value. Repeat previous step until all tanks data have been entered.
11. You see ‘Save fuel tank data?’. Answer SAVE to store all final data values or CANCEL to return to table editing. To complete the process, tap SAVE a second time.
23. Fuel Flow Totalizer, Refuel Question
The fuel flow totalizer can be set to a different value than the fuel level tank size. To reprogram the “Refuel setting for Main (total) and Auxiliary (total), enter the “Factory Program Mode” by holding buttons 1 and 2 in for a few seconds until the display reads “Program”. Keep tapping next until you see “END”. At this point hold in button
FAA Approved Installation Manual for the
EDM-900 and EDM-930
Report No 908
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Primary Engine Data Management System Date 5-24-14
1 and 2 again until the display (5 sec.) changes and you see FACTORY . At this point you will see MAIN = XX., adjust with the “Plus and Minus buttons. Tap next for AUX=XX and adjust. Tap button twice to finish and save.
24. GPS Interface
Use the J4 connector harness 700708 labeled RS232 OUT TO GPS (white) and RS232 IN FROM GPS (gray).
Refer to the Manufactures GPS manual for the required pin connections on the GPS.
25. Manifold Pressure (MAP) Sensor
Screw a AN816-4D (flared to pipe thread) into the Aeroquip 303 hose to and from the bulkhead fitting an 832-4 as shown below if not already installed from the aircraft factory MAP gauge.
P-2 GRN FP-Sig +
P-3 RED-FP PWR+5
P-1 BLK FP GND
PN 159934A
0-30 PSIA
Manifold Air-pressure
7/16 UNJF
#4 fitting MS-24587 FITTING
AEROQUIP 303 Flex hose
DO NOT MOUNT SENSOR DIRECTLY TO ENGINE
FAA Approved Installation Manual for the
EDM-900 and EDM-930
Report No 908
Page 28 of 50 Rev J
Primary Engine Data Management System Date 5-24-14
Manifold Pressure Calibration
The manifold pressure must be calibrated to the ambient air pressure. Enter the current ambient barometric pressure. The engine must not be running. This setting is not the same as the altimeter setting that you receive from ATIS or Unicom. It will vary with field elevation. Use the chart below to calculate the MP FACTOR. Multiply this
MP FACTOR by the altimeter setting that you receive from ATIS or Unicom. For example if the field elevation is
1700 ft and the altimeter setting is 30.1, the MP FACTOR is 0.9400 from the table. Multiply 30.1 x 0.9400 to get the ambient MP of 28.29.
Field
Elev.
MP
FACTOR
-500 1.0182
-400 1.0145
-300 1.0109
-200 1.0073
-100 1.0036
0 1.0000
100 0.9964
200 0.9928
300 0.9892
400 0.9856
500 0.9821
600 0.9785
700 0.9750
800 0.9714
900 0.9679
1000 0.9644
1100 0.9609
1200 0.9574
1300 0.9539
1400 0..4
1500 0.9469
1600 0.9435
1700 0.9400
1800 0.9366
1900 0.9332
2000 0.9298
2100 0.9264
2200 0.9230
2300 0.9196
2400 0.9162
2500 0.9129
2600 0.9095
2700 0.9062
2800 0.9028
2900 0.8995
3000 0.8962
3100 0.8929
3200 0.8896
3300 0.8863
3400 0.8830
3500 0.8798
3600 0.8765
3700 0.8733
3800 0.8700
3900 0.8668
4000 0.8636
4100 0.8604
4200 0.8572
4300 0.8540
4400 0.8508
4500 0.8477
4600 0.8445
4700 0.8414
4800 0.8382
4900 0.8351
5000 0.8320
5100 0.8289
5200 0.8258
5300 0.8227
5400 0.8196
5500 0.8165
5600 0.8135
5700 0.8104
5800 0.8074
5900 0.8043
6000 0.8013
6100 0.7983
6200 0.7953
6300 0.7923
6400 0.7893
6500 0.7863
6600 0.7833
6700 0.7804
26. RPM Sensor installation
Use the J3 connector harness 790422 and connect the 3 leads using the supplied 3-pin connector and pins. There are four types of magnetos commonly in use. You must have the correct RPM sensor for the magneto installed in the aircraft. The following part numbers apply: Slick – pressurized 4000, -6000 series use JPI P/N 420809. For the Bendix pressurized -1200 series use P/N 420807. Dual magnetos use JPI PN 420808. For the Bendix -20 series and Slick
600 use JPI P/N 420806. Mount the sensor as shown in the appropriate diagram below. Note: this is eligible for installation on all 4 & 6 cylinder engines only.
.
FAA Approved Installation Manual for the
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EDM-900 and EDM-930
Page 29 of 50 Rev J
Primary Engine Data Management System Date 5-24-2014
Bendix Magnetos Slick Magnetos
Connector to harness
Bendix -20, -21, -200, 1200 series non-pressurized
JPI 420815-2
position limit
Mount sensor side of bracket towards magneto body, positioned over the magnet armature
P
TO position limit
Connector to harness
Alternate bracket locations
Bendix 1200 series pressurized
JPI 420807
Mount sensor side of bracket towards magneto body
Connector to harness
Slick 6000, 4000 series non-pressurized
JPI 420815-1
Mount sensor side of bracket towards magneto body
Sensor ring munted under vent plug.
Stem at right angles to magneto center line
Alternate bracket location Connector to harness
Vent plug
Spacer ring
Sensor ring bracket
Magneto body
Slick 6000, 4000 series pressurized
JPI 420809
Sensor must be over moving magnet armature
Remove this screw to mount sensor bracket
Bendix Dual Magneto
JPI PN 420808 non-pressurized
rev Dec 2010
Slick 600 series
JPI PN 420806 non-pressurized
FAA Approved Installation Manual for the
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EDM-900 and EDM-930
Page 30 of 50 Rev J
Primary Engine Data Management System Date 5-24-2014
27. EDM-900/930 Specifications and Limitations
The following parameters must be customized for the aircraft into which the EDM-900/930 is installed.
Factory set limits or default values for EDM-900/930
1. TIT 1650 F
2. CHT 450 F
3. Oil Temp Low 90 F
4. Oil Temp HI 230F
5. Oil Press low 15 psi
6. Oil Press Hi 100 psi
7. Vacuum 0- 15”hg
8. RPM 2700 Limit and range
9. RPM set to cyl 6
10. Map 32 In hg HI
11. Map setting 29.90 In Hg
12. Fuel Pressure Hi 35 psi Injected
13. Fuel Pressure Lo 15 psi Injected
14. Fuel Pressure Hi 8 psi Carb
15. Fuel Pressure Lo .5 psi Carb
16. Fuel Flow 24 GPH
17. K-factor 29.99
18. Carburetor filter smoothing 1
19. Ammeter configuration (load or charge-discharge). Load NON TSO
20. HC-120 (% of HP) NON TSO
TSO-55 21. Fuel Level Resistive/Capacitive
22. Low fuel 10 Gal
23. Low time 45 Min
24. Main tank 75 gallons
25. Aux tank 0
26. GPS set at GARMIN
27. Diff 500 degrees
28. CLD 60 degrees per minute
29. Amps limit 100 amps
30. Record time, 6 sec intervals
31. Hobbs on at 1000 RPM
TSO-C43
TSO-C43
NON TSO
NON TSO
NON TSO
TSO-C43
TSO-C43
TSO-C43
TSO-C43
TSO-47
TSO-47
TSO-47
TSO-C49
TSO-C49
TSO-C45
TSO-C45
TSO-47
TSO-47
TSO-47
TSO-47
TSO-C44
On 14 vdc systems during start-up the EDM may reset it self. This is normal due to extremely low battery voltage.
The conditions and test required for TSO approval of this article are minimum performance standards. It is the responsibility of those desiring to install this article either on or within a specific type or class of aircraft to determine that the aircraft installation conditions are within the TSO standards.
The article may be installed only if installation of the article is approved by the Administrator. The functions of Volts, Amps, and Horse Power were tested to DO-160D and DO-178B, but not TSO’d since no TSO exist for these functions. Deviation granted for TSO-C49b to include digital display and sensor. All TSO required probes, transmitters and sensors also tested to DO-160D.
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EDM-900 and EDM-930
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Primary Engine Data Management System Date 5-24-2014
28. EMI Radio Test and functional check:
Even through the EDM-900/930 has been tested to DO-160E Section 20 (EMI) the installation itself could creates radio interference on specific frequencies. The following test is to insure that this does not exist.
EMI/RFI TESTS: perform tests, in accordance to the table below, to insure wire routing and connectivity has not compromised the signal integrity of the NAV/COM receivers. Power up the aircraft bus (or buses) in accordance with normal engine prestart procedures (see Aircraft Pilot Operating Handbook). Verify that the EDM-900/930 is operating normally and there are no bad probes or alarm messages. Set the frequency and audio panel to listen to that radio.
Loud buzzing/humming is considered ‘unusual noise’ in the context of these tests also the OBS needle should not move. Should any EMI noise be found that is attributed to the EDM-900/930 system, it must be corrected by shielding and/or rerouting wiring to eliminate the noise. If unusual noise is heard, remove power from the EDM-900/930 system to check if it is the source of this noise. If the EDM-900/930 system is not the source of ‘unusual noise’ then mark the table with a ‘PASS’.
(PASS/FAIL)
108.00
112.00
115.00
117.00
120.00
121.00
122.00
123.00
124.00
125.00
126.00
127.00
128.00
129.00
130.00
132.00
NAV/COM 2
(PASS/FAIL)
Comments
FAA Approved Installation Manual for the
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EDM-900 and EDM-930
Page 32 of 50 Rev J
Primary Engine Data Management System Date 5-24-2014
29. Component Parts
Display EDM-930 P/N 790000-C-(xxx)
Display EDM-900 P/N 790000-A-(xxx)
EGT probe KIT PN 1280
TIT probe with option KIT 1200
CHT probe KIT PN 1260
OAT probe with option KIT 1300
IAT probe with option KIT 1144
Carb temp probe KIT 1250 PN 500409
Oil Temp probe with option KIT 1255 PN 400409
Oil pressure sender KIT 1460 PN 159936A
Fuel pressure sender KIT 1450 PN 159935A
Fuel pressure differential sender Kit 1480 PN 159938
Ammeter shunt PN 159920
Fuel Flow transducer PN 700900-1 or -2
Fuel Level sender option
MAP KIT 1440 PN 159934A
RPM one of P/N 420806 or 420809 Pressurized
RPM one of P/N 420815-1, -2 Non Pressurized
29.1
Component Parts List for EGT (KIT 1280), TIT (KIT 1200) Probe
1 Thermocouple type K probe PN M-111
1 Stainless Steel Clamp Thimble
1 Stainless Steel Exhaust Seal Washer
1 Stainless Steel Screw Type Clamp
2 Ring Terminals
2 Screws and nuts 6-32 X 1/4
1 Fiberglass tube 3/8” x 5”
29.2
Component Parts list for CHT KIT 1260
1 Bayonet Probe Thermocouple type K Spring loaded PN 5050-T
2 Ring Terminals
2 Screws and Nuts 6-32 X 1/4"
1 Fiberglass tube 3/8” x 5”
29.3
Component Parts list for IAT (KIT 1300) probe
1 Thermocouple type K probe PN M-111
1 Stainless Steel Clamp &Thimble
1 Stainless Steel Exhaust Seal Washer
29.4
Component Parts list for OAT (KIT 1220) probe
1 P/N 400510, OAT probe
2 Ring Terminals
2 Screws and Nuts 6-32 X1/4"
Fiberglass tube 3/8” x 5”
29.5
Component Parts list for CARB (KIT 1190) probe
1 P/N 400128, CARB probe
1
1
1
1
1
1
1
1
Single engine
-4 Cyl -6 Cyl -7 Cyl -8 Cyl -9 Cyl
1
1
4
1
4
1
1
6
1
6
1
1
7
1
7
1
1
8
1
8
1
1
9
1
9
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1 1 1 1 1
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EDM-900 and EDM-930
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Primary Engine Data Management System Date 5-24-2014
2 Ring Terminals
2 Screws and Nuts 6-32 X1/4"
1 Fiberglass tube 3/8” x 5”
29.6
Component Parts list for OIL Temperature probe (KIT 1250)
1 P/N 400509 OIL probe
1 AN900-10 crush washer
2 Ring Terminals
2 Screws and Nuts 6-32 X 1/4"
1 Fiberglass tube 3/8” x 5”
29.7
Component Parts list for Oil Pressure sensor KIT 1460
1 P/N 159936A Oil Pressure sensor
1 P/N 159961 Clamp, Loop Cushioned
1 P/N 174402 Connector Pack 3 Pin and Terminals
29.8
Component Parts list for Kit 1480 Differential Fuel Pressure (only if required by POH)
1 P/N 159938 Fuel pressure sensor
1 P/N 159961 Clamp, Loop Cushioned
1 P/N 174204 Connector MS 3116F8-4S
29.9
Component Parts list for ampere shunt Kit 1300
1 P/N 159920 100 amp shunt
2 Ring Terminals
29.10
Component Parts list for Fuel Flow Transducer
1 fuel flow transducer, 201 or 231 PN 700900-1,-2
8 inches of 1.5” dia. fire sleeve
1 3-pin connector housing
3 female pins
2 AN816-4-4 fittings (Continental) or AN816-4-6 (Lycoming)
29.11
Component Parts list for MAP sensor KIT 1440
1 P/N 159934A Manifold pressure sensor
1 P/N 159961 Clamp, Loop Cushioned
1 P/N 174402 Connector Pack 3 Pin and Terminals
29.12
Components Parts list for non pressurized RPM sensor P/N depends on Magneto make and model
Bendix magneto -20,1200………….P/N 420815-2
Slick magneto 4000 or 6000………P/N 420815-1
Bendix dual ………………………….P/N 420808
FAA Approved Installation Manual for the
Report No 908
EDM-900 and EDM-930
Page 34 of 50 Rev J
Primary Engine Data Management System Date 5-24-2014
29.13
Components Parts list for pressurized RPM sensor P/N depends on Magneto make and model
Slick 6000………………………….….P/N 420809
Bendix magneto 20, slick 600………P/N 420806
Bendix Dual ………………………….P/N 420808
Bendix 1200………………………….P/N 420807
30. Weight and Balance Data
Indicator PN 790000(-A) EDM-900
Indicator PN 790000(-C) EDM-930
EGT / TIT / CDT / IAT / OAT probe
CHT / Oil Temperature probe
4/6 Cylinder Harness 8 ft.
RPM
MAP
Fuel Pressure Sender
Oil Pressure Sender
Harness each
2.0 Lbs
3.0 Lbs
2.0 oz. each / 0.125 lbs
1.5 oz. each / 0.094 lbs
14.0 oz. each / 0.88 lbs
1.5 oz each / .094 lbs
5.0 oz / 0.42 lbs
5.0 oz / 0.42 lbs
5.0 oz / 0.42 lbs
1.0 Lbs
31. Pilot Programming
To start the Pilot Program procedure, simultaneously hold the STEP and LF buttons for five seconds. You will see the word PROGRAM for two seconds and then the sequence shown in the chart below.
Tap the STEP button to advance to the next item in the list. Hold the STEP button to step back to the previous item.
Tap the LF button to select alternate values of that item. Simultaneously hold both STEP and LF to exit.
STEP
advances next item
LF sequences
through these values Comments
PROGRAM
Stays on for two seconds.
FUEL N FILL ? N Tap LF to change fuel status. Exits program mode when done.
RATE 4
OAT F
0 … 9
OAT F
OAT
C
Index rate (pause time in seconds) in the Automatic Mode. 0 disables the Automatic Mode.
To calibrate the OAT
10°, hold both the STEP and LF buttons simultaneously for five seconds, which will proceed to the next step. Otherwise the next step will be skipped.
OAT
0
OAT-I0 …
OAT
I0
This step will be normally be skipped.
Adjust the indicated temperature up or down by up to 10°. For example, OAT
3 adjust the OAT 3° higher.
EGT I?N EGT I?N
EGT I?Y
HPC I25 70 HP
HPC= I25
Y—Yes—sets the digital display to one-degree resolution; N—No—sets 10°. (10° resolution is easier to interpret the EGT’s.)
%HP display will change when HP constant is adjusted. Hold STEP and LF for 5 seconds until you see ADJUST to set the HP calibration. Tap STEP to continue to the next step.
To adjust the MAP, hold both the STEP and LF buttons simultaneously for five seconds, which will proceed to the next step. Otherwise the next step will be skipped.
MAP
29.9
MAP 20
32
KF 29.90
Adjust the MAP.
Adjust the instrument’s K-factor to match the fuel flow transducer K-factor.
TR IP? N
DATE AND
TIME
TR IP? N
TR IP? Y
N—No—Upon informing the EDM that you refueled the aircraft, reset total fuel used to 0.
Y—Yes—accumulate total fuel used rather than reset to 0 at each refueling. See page
Displays the Date and time
FAA Approved Installation Manual for the
Report No 908
EDM-900 and EDM-930
Page 35 of 50 Rev J
Primary Engine Data Management System Date 5-24-2014
END? Y END? Y STEP exits the pilot programming mode.
LF reenters pilot programming mode.
32. Programming the HP Constant
You must adjust the HP Constant once for your aircraft. You must perform this adjustment in the air while the aircraft is in flight between 5,000 and 8,000 feet MSL.
1. Enter the pilot program mode by simultaneously holding the STEP and LF buttons for five seconds.
2. Tap STEP repeatedly until you see—for example— HPC = I25. Then hold both the STEP and LF buttons display until you see ADJUST, followed by HPC= I25. The adjustment range for the HP Constant is 45 to 180.
3. Set the MP and RPM per your POH to 70 percent power. Let conditions stabilize.
4. Change the HP reading on the EDM-900 to 70 percent by adjusting the HP constant in the lower display by holding or tapping the LF button. Percent HP should be close to 100 percent during takeoff at sea level.
5.
Tap the STEP button to proceed to the next step.
33. Programming the MAP
Sets the manifold pressure calibration .
You may need to correct the MAP based on the altimeter setting at a sea level airport.
1. Enter the pilot program mode by simultaneously holding the Step and LF buttons for five seconds.
2. Tap Step/OK repeatedly until you see—for example – MAP adjustment 0.0 . .
3. Then hold both the first two buttons until you see ADJUST, followed by MAP+0. The adjustment range for the
MAP is ±2.0 in Hg. As you adjust the MAP up or down you will see a change in the MAP gage under RPM. When you see the correct setting stop.
4. Tap the Step/OK button to proceed to the next step or hold both buttons again to exit setup.
Do this one time and only if the MAP on your manifold pressure gauge doesn't match the MAP shown on the EDM-960
You must do this on the ground with the engine turned off.
.
34. Selecting Fuel Pressure Type (EDM-900 only)
To properly display Fuel Pressure values, the EDM must be told what type of Fuel Pressure sensor is connected to the
EDM. This is normally set at the factory for new installations. To set or modify the type of Fuel Pressure sensor connected to the EDM, follow these steps:
1. Enter Pilot Program Mode by holding the STEP and LF buttons for 5 seconds
2. When the EDM enters Program Mode, tap the button labeled “NEXT” until END? Is displayed in the scanner message area.
3. Again hold the STEP and LF buttons until the EDM enters Factory Program Mode. displayed in the scanner message area.
7. To save the selected value, hold the STEP and LF buttons until the word SET appears in the message area.
9.
Tap the button labeled YES to save changes and restart the EDM.
FAA Approved Installation Manual for the
Report No 908
EDM-900 and EDM-930
Page 36 of 50 Rev J
Primary Engine Data Management System Date 5-24-2014
35. Customizing Non-Primary Data (EDM900 only)
You can customize – change or re-order non-primary data channels in the non-primary portion of the EDM display
(non-primary values are displayed as text gauges without redline values – See Pilot’s Guide for more information).
Non-primary data channels are numbered from 1 up to 6, depending on your particular aircraft configuration and EDM installation. To customize the LCD layout of non-primary data, follow these steps:
1. Enter Pilot Program Mode by holding the STEP and LF buttons for 5 seconds
2. When the EDM enters Program Mode, tap the button labeled “NEXT” until END? Is displayed in the scanner message area.
3. Again hold the STEP and LF buttons until the EDM enters Factory Program Mode. is displayed in the scanner message area.
6. You will see a prompt like “1=VOLTS” (or similar). This describes the data channel to be displayed in the first non-primary data location.
7. Tap the “CHANGE” button to change to the next non-primary data channel. The new data channel selected will be displayed in the
8. Tap the “NEXT” button to select the next non-primary location (such as 2=AMPS).
10. When all changes have been made, hold the STEP and LF buttons until the word SET appears in the message area.
11. Tap the STEP button repeatedly until the message END? is displayed in the message area
12. Tap the button labeled YES to save changes and restart the EDM.
36. K Factor
The K factor is shown on the fuel flow transducer as a four-digit number, which is the number of pulses generated per gallon of fuel flow. Before installing the transducer, write down the K factor here _________. To enter the number, move the decimal point three places to the left. For example if the K factor on the fuel flow transducer is 29,123, enter
29.12 in the K factor parameter.
If the K factor is increased, the indicated fuel flow will decrease, and vice-versa. When the K factor is changed during a trip, calculations of fuel used, fuel remaining and time to empty are not retroactively recalculated.
FAA Approved Installation Manual for the
Report No 908
EDM-900 and EDM-930
Page 37 of 50 Rev J
Primary Engine Data Management System Date 5-24-2014
37. Fine tuning the K Factor
The K factor shown on the fuel flow transducer does not take into account your aircraft’s particular installation. Fuel hose diameters and lengths, elbows, fittings and routing can cause the true K factor to be different from that shown on the fuel flow transducer.
You must use the following procedure to fine tune the K factor.
1. Make at least three flights of about two to three hours each. Note the actual fuel used (as determined by topping the tanks) and the EDM-900 calculation of the fuel used for each flight USD.
Flight
Fuel USED shown by EDM
(total tank - REM)
1
2
3
Total
Actual fuel used by topping tanks
2. Total
the EDM-900 calculated fuel used and the actual fuel used.
3. Record the current K factor here
____________________ and in the table below.
4. Calculate the New K factor as follows:
New K factor = (EDM fuel used) x (Current K factor)
(actual fuel used)
New K factor = (
(
) x (
)
)
Every time you fine tune the K factor, change it by only half of the amount calculated above, and record the measurements here:
Date
EDM
fuel used
actual
fuel used
Current
K factor
New K factor
=
x/
Pilot’s initials
FAA Approved Installation Manual for the
Report No 908
EDM-900 and EDM-930
Page 38 of 50 Rev J
Primary Engine Data Management System Date 5-24-2014
38. Adjusting the K Factor
This procedure is different than for setting other parameters.
1. If you haven’t already done so, start the Pilot Program Mode by clearing all alarms by tapping step repeatedly, then simultaneously hold the STEP and LF buttons (for about five seconds), until you see the word PROGRAM, followed by ‘FUEL ? N’.
2. Tap STEP repeatedly until you see K-FACTOR=29.90 (this value may be different on your unit).
3. Hold both the STEP and LF buttons simultaneously until a digit begins flashing. This indicates editing has been enabled.
4. Tap or hold the LF button to change the flashing digit to the desired value.
5. Tap or hold the STEP button to select the next digit to edit.
6. Repeat steps 4 and 5 until the displayed value is set to your desired value.
7. To save new value, hold STEP and LF buttons simultaneously (for about five seconds) until the K factor parameter exits.
8.
Tap STEP repeatedly until you see END ? Y, then Tap STEP once more to exit the Pilot Program Mode.
39. Programming Accumulate Trip Total
Accumulate—default is OFF: resets the fuel used to 0 every time you inform the EDM-900 that the aircraft was refueled. With accumulate ON fuel used will not be reset to 0 when you inform the EDM-900 that the aircraft was refueled.
Select “No” if you wish to display total fuel used since the last time you informed the EDM-900 that the aircraft was refueled. Select “Yes” to display total fuel used for an extended trip with multiple fuel stops. This selection affects only the
USD
measurement.
During normal operation, to reset the accumulated fuel used display at any time, tap STEP until you see USD. Hold both STEP and LF until the display shows .0 USD.
FAA Approved Installation Manual for the
Report No 908
EDM-900 and EDM-930
Page 39 of 50 Rev J
Primary Engine Data Management System Date 5-24-2014
40. Trouble Shooting
Diagnostic Testing on Startup and During Flight
When your EDM is first turned on it tests internal components, calibration and integrity of the probes.
During flight, probes are constantly checked for inconsistent or intermittent signals.
Problem
A MISSING COLUMN IN THE
DISPLAY UPON START UP
A MISSING COLUMN IN THE
DISPLAY DURING FLIGHT
DISPLAY FREEZES OR MAY
BE INCORRECT
LEANFIND FINDS A “PEAK”
TOO SOON
Situation Correction
diagnostic routine has found an open line or probe with no connection.
Replace the EGT or CHT probe shown in the error message a reading that is jumping around or incorrect
The probe is removed from the line up
A power transient could cause the processors to malfunction
Replace the EGT or CHT probe shown in the error message on the next flight.
Recycle the power to the EDM
Continue to lean without stopping
Lean more rapidly
PEAK NOT FOUND DURING
LEANFIND
OFF-SCALE EGT COLUMNS,
TOO HIGH OR LOW
FIRST CYLINDER TO PEAK
IS NOT THE HOTTEST
EGTS RISE DURING SINGLE
MAGNETO CHECK
EGTS NOT UNIFORM
DURING LOW POWER
OPERATION
0.0 GPH
--- GPH
--- H.M
OPEN PRB
BAD-PRB
RED ‘X’ DRAWN THROUGH
A SINGLE GAUGE
RED ‘X’ DRAWN THROUGH
ALL GAUGES FOR AN
ENGINE
CAL ERR
DSP XXX
COMM ERR
NO I 5 MV
Failure to pre-lean before performing
LeanFind or stopping while leaning.
Leaning too slowly
Lean Find not activated or stopping while leaning
Off-scale EGT column readings. EDM in the Normalize view (blue EGT scales).
The first to cylinder peak is not necessarily the hottest
Incomplete combustion persisting longer
Fuel and air distribution is not optimal at low power settings
Zero’s indicate Fuel flow is too low to register
Dashes indicate No fuel flow transducer signals
Dashes indicate No fuel flow transducer signals
Open probe.
This is normal.
Have the mechanic verify if it is the sensor or wiring.
No GPS signal, check the wiring
Bad probe.
Wiring to probe is open circuit. Check wiring and crimps. Swap probes to troubleshoot.
Erratic reading. May be poor electrical connection. Swap probes to troubleshoot.
Measurement out of range. Have the mechanic verify if it is the engine or the sensor. Replace as necessary.
DAU failure or DAU communications error. Check power to DAU and wiring harness connections.
Calibration error.
Internal communication error.
Internal communication error.
Calibration error.
Lean at the speed of approximately
10°F per second
Return to Standard mode by holding the LF button.
This is normal.
This is normal.
This is normal.
Return unit to factory.
Return unit to factory.
Return unit to factory.
Return unit to factory.
FAA Approved Installation Manual for the
Report No 908
EDM-900 and EDM-930
Page 40 of 50 Rev J
Primary Engine Data Management System Date 5-24-2014
NO 50MV Calibration error. Return unit to factory.
NO 2.5V Calibration error. Return unit to factory.
WARNCAL, WARNCFG
HOBSERR
HOBSBAD
HANGCFG, HANGCAL
Transient warning messages.
The time of the most recent flight may not be reflected in the HOBBS meter.
The HOBBS data has been corrupted.
Internal system errors.
Return unit to factory.
Return unit to factory.
Return unit to factory.
Return unit to factory.
41. GPS Interface Diagnostics
Problem
Measurements ‘xxx REQ’,
‘XXX RES’ AND ‘XXX
MPG’ are all missing from the scan.
NO - COM message and
‘xxx REQ’, ‘XXX RES’ AND
‘XXX MPG’ are all missing from the scan.
NO - SIG message and
‘xxx REQ’, ‘XXX RES’ AND
‘XXX MPG’ are all missing from the scan.
NO - WPT message and
‘xxx REQ’, ‘XXX RES’ are all missing from the scan.
No communications from GPS receiver to
EDM.
Situation Correction
No connection or aircraft GPS is off.
Communications are received by EDM and the Auto-Protocol setup is in process.
GPS receiver has insufficient signal for valid data.
No waypoints are programmed into the aircraft GPS receiver.
Verify correct output format setup in
GPS receiver; check GPS connections.
Check GPS signal
Program way points
FAA Approved Installation Manual for the
Report No 908
EDM-900 and EDM-930
Page 41 of 50 Rev J
Primary Engine Data Management System Date 5-24-2014
42.
Connector Pin Assignments on EDM, J1 through J5
Rear view of EDM 930 Showing Connector Locations
FAA Approved Installation Manual for the
Report No 908
EDM-900 and EDM-930
Page 42 of 50 Rev J
Primary Engine Data Management System Date 5-24-2014
43.
Connector Pin Assignments on EDM, J1 through J5
Rear view of EDM 900 Showing Connector Locations
FAA Approved Installation Manual for the
Report No 908
EDM-900 and EDM-930
Page 43 of 50 Rev J
Primary Engine Data Management System Date 5-24-2014
J1 For 4 and 6 cylinder installations
OIL temperature sensor yel 1 red 2 yel 3 red 4 yel 5 red 6 yel 14 red 15 yel 16 red 17 yel 18 red 19 gray 12 red 13
IND temperature sensor
Carb temperature sensor
OAT
TIT 1 sensor
TIT 2 sensor
Remote temperature/voltage alarm light
(option)
+12 or +24 vdc power lead black 25 Aircraft engine ground lead yel 1 red 2 yel 3 red 4 yel 5 red 6 yel 7 red 8 yel 9 red 10 yel 14 red 15 yel 18 red 19 yel 20 red 21 yel 22 red 23 gray 12 yel 16 red 17
J1
FOR
7, 8,
and
9
cylinder installations
OIL temperature sensor
Carb temperature sensor
+
+
+
CHT-7
CHT-8
CHT-9
OAT
EGT-7
EGT-8
EGT-9
Remote temperature/voltage alarm light
(option)
TIT 1 sensor red 13 black 25 wht 11 DATA IN
+12 or +24 vdc power lead
Aircraft engine ground lead wht 24 DATA OUT
FAA Approved Installation Manual for the
Report No 908
EDM-900 and EDM-930
Page 44 of 50 Rev J
Primary Engine Data Management System Date 5-24-2014
FAA Approved Installation Manual for the
Report No 908
EDM-900 and EDM-930
Page 45 of 50 Rev J
Primary Engine Data Management System Date 5-24-2014
44.
J3 RPM, MP, Oil-P
J-3 Harness with i2s Oil and manifold pressure sender
FAA Approved Installation Manual for the
Report No 908
EDM-900 and EDM-930
Page 46 of 50 Rev J
Primary Engine Data Management System Date 5-24-2014
J4 (FF, GPS, AMP 2 )
White 1
Gray 2
Data out to GPS
Data in from GPS white 4 red 5 black 6
IN
Serial communications
OUT
Main FF 700900-1, (201) -2 (231)
White 12
NC 9
10
11
5 6
Right low fuel switch
13
White 14
Gray 15
Left low fuel switch
IN
OUT
Return FF 700900-1, (201) -2 (231)
Optional
optional
Remote fuel flow alarm light (option)
FF2
Power and ground connect to pins 5 and 6 respectively
+
AMPS 2
159920
Optional
FAA Approved Installation Manual for the
Report No 908
EDM-900 and EDM-930
Page 47 of 50 Rev J
Primary Engine Data Management System Date 5-24-2014
44.1
J5 PN 790723 (fuel tanks, fuel press, amps)
FAA Approved Installation Manual for the
Report No 908
EDM-900 and EDM-930
Page 48 of 50 Rev J
Primary Engine Data Management System Date 5-24-2014
J-5 Harness with i2s fuel pressure sender.
FAA Approved Installation Manual for the
Report No 908
EDM-900 and EDM-930
Page 49 of 50 Rev J
Primary Engine Data Management System Date 5-24-2014
45. Appendix A
Connector Pin Assignments on EDM, J1-J2 Only with ARINC 42
J1 - DB25M
Production
Version
Oil Temp Y
8
9
10
4
5
6
7
1
2
3
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
Oil Temp R
Spare RS232 Data In
FDR RS232 Data Out
Ground Oil Pr/Hydr Pr
Oil Pr +input 0-5V
Oil/Hydr Pr +5V power
Torque +5V power
Torque +input 0-5V
Torque Ground
AMPS #1+
AMPS #2+
14-28V Pwr (BAT1)
OAT Y
OAT R
ITT Y
ITT R
Emerg Hyd Pr +in 0-5V
Main Hyd Pr +in 0-5V
Fuel Pr +5V power
Fuel Pr +input 0-5V
Fuel Pr Gnd
AMPS #1 -
AMPS #2 -
Power Ground
Kg (5V) / lb (0V)
Select
Day (5V) / Night
(0V) Select connected to generator shunt connected to battery shunt
Not used
To Flight Data
Recorder connected to generator shunt connected to battery shunt
20
21
22
23
24
25
16
17
18
19
12
13
14
15
J2 DB25F Production Version
1
ARINC IN #1A
2
3
ARINC IN #1B
GPS RS232 Data In
4
5
6
7
GPS RS232 Data Out
Fuel Flow Signal
Fuel Flow +12V pwr
Fuel Flow Ground
8
9
10
11
FQ #1 0-5V
FQ #2 0-5V
Fuel Temp RTD -
Fuel Temp RTD + nCAL
14-28V Aux Pwr (BAT2)
ARINC OUT #1A
ARINC OUT #1B
Annunciator #1
Annunciator #2
Annunciator #3
Annunciator #4
FQ #3 0-5V
FQ #4 0-5V
N2, Np
N1, N2 Gnd
N1, Ng
Power Ground
Not used
Not used
Ground
Do Not
Connect
Ground = on
FAA Approved Installation Manual for the
Report No 908
EDM-900, PN 790000-A, EDM-930, PN 790000-C Page 50 of 50 Rev J
Primary Engine Data Management System Date 5-24-2014
46.
Appendix B ICA
Refer to:
Supplement No: 905-01
Revision: E or later
Check the web page, jpinstruments.com for the latest revision to the ICA

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Key features
- Comprehensive engine and aircraft system monitoring
- Customizable primary data display
- GPS integration for navigation and fuel management
- Automatic dimming for improved visibility
- Remote alarm display (RAD) for high-visibility alerts
- Easy to install and configure