Omega Fma 1400 User Manual

Users Guide  
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FMA 1400 and FMA 1500  
Mass Flow Meters and Controllers  
TABLE OF CONTENTS  
1. UNPACKING THE FMA 1400/1500 MASS FLOW METER.............
1
1
1.1 Inspect Package for External Damage........................................
1
1.2 Unpack the Mass Flow Meter/Controller.....................................
1
1.3 Returning Merchandise for Repair..............................................
1
2. INSTALLATION............................................................  
1
2.1 Primary Gas Connections...........................................................
2
2.2 Electrical Connections................................................................
4
3. PRINCIPLE OF OPERATION..............................................  
5
4. SPECIFICATIONS...........................................................  
4.1 FMA 1500 Mass Flow Meters for ranges up to  
and above 10 L/min...................................................................
4.2 FMA 1400 Mass Flow Controllers for ranges up to  
5
6
and above 10 L/min...................................................................
7
4.3 CE Compliance...........................................................................
9
5. OPERATING INSTRUCTIONS.............................................  
9
5.1 Preparation and Warm Up..........................................................
10  
5.2 Flow Signal Output Readings.....................................................
10  
5.3 Swamping Condition..................................................................
10  
5.4 Set Point Reference Signal (FMA 1400).....................................
11  
5.5 TTL, Valve OFF Control (FMA 1400)...........................................
11  
5.6 Valve Test/Purge (FMA 1400).....................................................
12  
6. MAINTENANCE............................................................  
12  
6.1 Introduction................................................................................
12  
6.2 Flow Path Cleaning.....................................................................
12  
6.2.1 Restrictor Flow Element (RFE).............................................
13  
6.2.2 FMA 1400/1500 Ranges up to 10 L/min..............................
13  
6.2.3 FMA 1400/1500 Ranges above 10 L/min............................
13  
6.2.4 Valve Maintenance (FMA 1400)...........................................
14  
7. CALIBRATION PROCEDURES.............................................
14  
7.1 Flow Calibration..........................................................................
15  
7.2 Calibration of FMA 1500 Mass Flow Meters...............................
15  
7.2.1 Connections and Initial Warm Up........................................
16  
7.2.2 ZERO Adjustment................................................................
16  
7.2.3 SPAN Adjustment................................................................
7.3 Linearity Adjustment...................................................................16
7.3.1 Connections and Initial Warm Up........................................16  
7.3.2 ZERO Adjustment.................................................................17  
7.3.3 25% Flow Adjustment..........................................................17
7.3.4 50% Flow Adjustment..........................................................17  
7.3.5 75% Flow Adjustment..........................................................17
7.3.6 100% Flow Adjustment....................................................... 17  
7.4 Calibration of FMA 1400 Mass Flow Controllers.........................17
7.4.1 Disable Solenoid Valve.........................................................17  
7.4.2 Valve Adjustment.................................................................18  
7.4.3 Full Scale Flow Adjustment..................................................18  
7.4.4 25% Flow Adjustment..........................................................18  
7.4.5 50% Flow Adjustment..........................................................18  
7.4.6 75% Flow Adjustment......................................................... 18  
7.4.7 100% Flow Adjustment........................................................18  
8. TROUBLESHOOTING.......................................................19  
8.1 Common Conditions...................................................................19
8.2 Troubleshooting Guide................................................................20
8.3 Technical Assistance...................................................................22  
9. CALIBRATION CONVERSIONS FROM REFERENCE GASES...........22  
APPENDIX 1 COMPONENT DIAGRAMS.................................................23  
APPENDIX 2 GAS FACTOR TABLE ("K" FACTORS).................................24  
APPENDIX 3 DIMENSIONAL DRAWINGS..............................................28  
APPENDIX 4 WARRANTY.......................................................................32  
TRADEMARKS  
Omega®-is a registered trademark of Omega Engineering, Inc.  
VCR7 is a registered trademark of Crawford Fitting Co.  
Buna7 is a registered trademark of DuPont Dow Elastometers.  
Kalrez7 is a registered trademark of DuPont Dow Elastomers.  
Neoprene7 is a registered trademark of DuPont.  
Viton7 is a registered trademark of Dupont Dow Elastometers L.L.C.  
1.  
UNPACKING THE FMA 1400/1500  
MASS FLOW METER AND CONTROLLER  
1.1  
Inspect Package for External Damage  
Remove the Packing List and verify that you have received all equipment. If you  
have any questions about the shipment, please call the Omega7 Customer  
Service Department at 1-800-622-2378 or (203) 359-1660.  
Your FMA 1400/1500 Mass Flow Meter/Controller was carefully packed in a stur-  
dy cardboard carton, with anti-static cushioning materials to withstand shipping  
shock. Upon receipt, inspect the package for possible external damage. In case  
of external damage to the package contact the shipping company immediately.  
1.2  
Unpack the Mass Flow Meter/Controller  
Open the carton carefully from the top and inspect for any sign of concealed ship-  
ping damage. In addition to contacting the shipping carrier please forward a copy  
of any damage report to Omega7 directly.  
When unpacking the instrument please make sure that you have all the items indi-  
cated on the Packing List. Please report any shortages promptly.  
1.3  
Returning Merchandise for Repair  
Please contact an Omega customer service representative and request a Return  
Authorization Number (AR).  
It is mandatory that any equipment returned for servicing be purged and neutral-  
ized of any dangerous contents including but not limited to toxic, bacterially infec-  
tious, corrosive or radioactive substances. No work shall be performed on a  
returned product unless the customer submits a fully executed, signed SAFETY  
CERTIFICATE. Please request form from the Service Manager.  
2.  
INSTALLATION  
2.1  
Primary Gas Connections  
Please note that the FMA 1400/1500 Mass Flow Meter/Controller will not operate  
with liquids. Only clean gases are allowed to be introduced into the instrument. If  
gases are contaminated they must be filtered to prevent the introduction of imped-  
iments into the sensor.  
Caution: FMA 1400/1500 transducers should not be used for monitoring  
OXYGEN gas unless specifically cleaned and prepared for such application.  
For more information, contact Omega7.  
ƽ
Attitude sensitivity of the Mass Flow Meter is +15F.This means that the gas flow path  
of the Flow Meter/Controller must be horizontal within those stated limits. Should  
there be need for a different orientation of the meter, re calibration may be necessary.  
1
It is also preferable to install the FMA 1400/1500 transducer in a stable environment,  
free of frequent and sudden temperature changes, high moisture, and drafts.  
Prior to connecting gas lines inspect all parts of the piping system including fer-  
rules and fittings for dust or other contaminants.  
Be sure to observe the direction of gas flow as indicated by the arrow on the front  
of the meter when connecting the gas system to be monitored.  
Insert tubing into the compression fittings until the ends of the properly sized tub-  
ings home flush against the shoulders of the fittings. Compression fittings are to  
be tightened according to the manufacturer's instructions to one and one quarter  
turns. Avoid over tightening which will seriously damage the Restrictor Flow  
Elements (RFE's)!  
FMA 1400/1500 transducers are supplied with standard 1/4 inch (FMA 1400/1500  
for ranges up to and above 10 L/min) or 3/8 inch (FMA 1400/1500 for ranges  
above 10 L/min), or optional 1/8 inch inlet and outlet compression fittings which  
should not be removed unless the meter is being cleaned or calibrated for a new  
flow range.  
Using a Helium Leak Detector or other equivalent method perform a thorough  
leak test of the entire system. (All FMA 1400/1500's are checked prior to shipment  
for leakage within stated limits. See specifications in this manual.)  
2.2  
Electrical Connections  
FMA 1400/1500 transducers require a +15VDC and -15VDC power supply to  
operate. Additionally, a readout panel meter, digital multimeter, or other equiva-  
lent device is required to observe the flow signal. A variable analog 0-5VDC ref-  
erence input is required for FMA 1400 models. The Omega7 FMA14PD Series  
accessory Command Modules offer a convenient and compact means to fulfill  
these needs.  
FMA 1400/1500 transducers come with a 15 pin "D" connector. The pin diagram  
is provided on figure 2-3.  
2
FIGURE 2-1, WIRING DIAGRAM FOR FMA 1400/1500 TRANSDUCERS  
PIN FUNCTION  
1
2
3
4
5
6
7
8
9
Chassis Ground  
Common, Signal Ground For Pin 3  
0-5 VDC Flow Signal  
+15 VDC Power Supply  
(-) 4-20 mA Flow Signal (optional)  
+7 VDC for Local Set Point  
(unassigned)  
TTL Valve Off Control (FMA 1400)  
Control Set Point Input 0 5 VDC (FMA 1400)  
10 Common, Signal Ground for Pin 9  
11 Common, Power Supply  
12 Valve Test Point/Purge (FMA 1400)  
13 (unassigned)  
14 -15 VDC Power Supply  
15 (+) 4-20 mA Flow Signal (optional)  
FIGURE 2-3, FMA 1400/1500 15 PIN "D" CONNECTOR CONFIGURATION  
3
Important notes:  
In general, "D" Connector numbering patterns are standardized. There are, how-  
ever, some connectors with nonconforming patterns and the numbering sequence  
on your mating connector may or may not coincide with the numbering sequence  
shown in our pin configuration table above. It is imperative that you match the  
appropriate wires in accordance with the correct sequence regardless of the par-  
ticular numbers displayed on your mating connector.  
Make sure power is OFF when connecting or disconnecting any cables in the system.  
The (+) and (-) power inputs are each protected by a 750mA M (medium time-lag)  
resettable fuse. If a shorting condition or polarity reversal occurs, the fuse will cut  
power to the flow transducer circuit. Disconnect the power to the unit, remove the  
faulty condition, and reconnect the power. The fuse will reset once the faulty con-  
dition has been removed.  
Cable length may not exceed 9.5 feet (3 meters).  
Use of the FMA 1400/1500 flow transducer in a manner other than that specified  
in this manual or in writing from Omega7, may impair the protection provided by  
the equipment.  
3.  
PRINCIPLE OF OPERATION  
The stream of gas entering the Mass Flow transducer is split by shunting a small  
portion of the flow through a capillary stainless steel sensor tube. The remainder  
of the gas flows through the primary flow conduit.The geometry of the primary con-  
duit and the sensor tube are designed to ensure laminar flow in each branch.  
According to principles of fluid dynamics the flow rates of a gas in the two laminar  
flow conduits are proportional to one another. Therefore, the flow rates measured  
in the sensor tube are directly proportional to the total flow through the transducer.  
In order to sense the flow in the sensor tube, heat flux is introduced at two sec-  
tions of the sensor tube by means of precision wound heater-sensor coils. Heat is  
transferred through the thin wall of the sensor tube to the gas flowing inside. As  
gas flow takes place heat is carried by the gas stream from the upstream coil to  
the downstream coil windings. The resultant temperature dependent resistance  
differential is detected by the electronic control circuit. The measured gradient at  
the sensor windings is linearly proportional to the instantaneous rate of flow tak-  
ing place.  
An output signal is generated that is a function of the amount of heat carried by  
the gases to indicate mass-molecular based flow rates.  
Additionally, FMA 1400 model Mass Flow Controllers incorporate a proportionat-  
ing solenoid valve. The closed loop control circuit of the FMA 1400 continuously  
compares the mass flow output with the selected flow rate. Deviations from the set  
point are corrected by compensating valve adjustments, thus maintaining the  
desired flow parameters.  
4
4.  
SPECIFICATIONS  
FLOW MEDIUM: Please note that FMA 1400/1500 Mass Flow Meters and Controllers for  
ranges up to and above 10 L/min are designed to work with clean gases only. Never try to  
meter or control flow rates of liquids with any FMA 1500's or FMA 1400's.  
F
CALIBRATIONS: Performed at standard conditions [14.7 psia (1.01 bars) and 70 F  
F
(21.1 C)] unless otherwise requested or stated.  
ENVIRONMENTAL (per IEC 664): Installation Level II; Pollution Degree II  
4.1  
FMA 1500 Mass Flow Meters  
for ranges up to and above 10 L/min  
ACCURACY: +1% of full scale, including linearity for gas temperatures ranging from  
F
F
F
F
59 F to 77 F (15 C to 25 C) and pressures of 10 to 60 psia (0.7 to 4.1 bars).  
REPEATABILITY: +0.2% of full scale.  
F
TEMPERATURE COEFFICIENT: 0.1% of full scale/ C.  
PRESSURE COEFFICIENT: 0.01% of full scale/psi (0.07 bar).  
RESPONSE TIME: 300ms time constant; approximately 1 second to within +2% of set  
flow rate for 25% to 100% of full scale flow rate.  
GAS PRESSURE: 500 psig (34.5 bars) maximum; optimum pressure is 20 psig (1.4 bars).  
F
F
F
F
GAS AND AMBIENT TEMPERATURE: 41 F to 122 F (5 C to 50 C).  
RELATIVE GAS HUMIDITY: Up to 70%.  
LEAK INTEGRITY: 1 x 10-9 sccs He maximum to the outside environment.  
ATTITUDE SENSITIVITY: 1% shift for a 90 degree rotation from horizontal to vertical;  
standard calibration is in horizontal position.  
OUTPUT SIGNALS: Linear 0-5 VDC (2000 minimum load impedance); 4-20 mA  
optional (50-500 maximum loop resistance); 20 mV peak to peak max noise.  
TRANSDUCER INPUT POWER: +15 +5% VDC, 80 mA max, 1.2 watts; -15 +5% VDC, 10  
mA max, 0.15 watts.  
Power inputs are each protected by a 750mA M (medium time-lag) resettable fuse, and a  
rectifier diode for polarity protection.  
WETTED MATERIALS: 316 stainless steel, VITON7 O-rings; BUNA-N7, NEOPRENE7 or  
KALREZ7 O-rings are optional.  
5
Omega7 makes no expressed or implied guarantees of corrosion resistance of mass flow  
meters as pertains to different flow media reacting with components of meters. It is the  
customers' sole responsibility to select the model suitable for a particular gas based on  
the fluid contacting (wetted) materials offered in the different models.  
INLET AND OUTLET CONNECTIONS: 1/4"compression fittings standard on ranges up to  
50 L/min; 3/8” compression fittings standard on 60, 80, and 100 L/min ranges.  
Optional: 1/8” compression fittings and 1/4” VCR fittings on ranges up to 10 L/min.  
3/8” compression fittings and 1/4” VCR fittings on ranges above 10 L/min up  
to 50 L/min.  
TRANSDUCER INTERFACE CABLE: Flat cable with male 15-pin "D" connector is standard.  
Optional shielded cable is available with male/female 15-pin "D" connector ends. [Cable  
length may not exceed 9.5 feet (3 meters)].  
4.2  
FMA 1400 Mass Flow Controllers  
for ranges up to and above 10 L/min  
ACCURACY: +1% of full scale, including linearity for gas temperatures ranging from  
F
F
F
F
59 F to 77 F (15 C to 25 C) and pressures of 10 to 60 psia (0.7 to 4.1 bars).  
REPEATABILITY: +0.2% of full scale.  
F
TEMPERATURE COEFFICIENT: 0.1% of full scale/ C.  
PRESSURE COEFFICIENT: 0.01% of full scale/psi (0.07 bar).  
RESPONSE TIME: FMA 1400 for ranges up to 10 L/min:  
300ms time constant; approximately 1 second to within  
+2% of set flow rate for 25% to 100% of full scale flow.  
FMA 1400 for ranges above 10 L/min:  
600ms time constant; approximately 2 seconds to within  
+2% of set flow rate for 25% to 100% of full scale flow.  
GAS PRESSURE: 500 psig (34.5 bars) maximum; optimum pressure is 20 psig (1.4  
bars); 25 psig (1.7 bars gauge) for FMA 1400 ranges above 10 L/min.  
MAXIMUM DIFFERENTIAL PRESSURES: 40 psig (2.61 bars) for FMA 1400 ranges above  
10 L/min. 50 psig (3.34 bars) for FMA 1400 ranges up to and above 10 L/min. Optimum  
differential pressure is 25 psid (1.7 bars). See Table IV for pressure drops associated with  
various models and flow rates.  
F
F
F
F
GAS AND AMBIENT TEMPERATURE: 41 F to 122 F (5 C to 50 C).  
RELATIVE GAS HUMIDITY: up to 70%.  
LEAK INTEGRITY: 1 x 10-9 sccs He maximum to the outside environment.  
6
ATTITUDE SENSITIVITY: 1% shift for a 90 degree rotation from horizontal to vertical;  
standard calibration is in horizontal position.  
OUTPUT SIGNALS: Linear 0-5 VDC (2000 minimum load impedance); 4-20 mA  
optional (50-500 loop resistance); 20 mV peak to peak max noise.  
COMMAND SIGNAL: 0-5 VDC (200K input impedance).  
TRANSDUCER INPUT POWER:  
FMA 1400 ranges up to 10 L/min:  
(15 sLit/min max) +15 +5% VDC, 80 mA max, 1.2  
watts max; -15 +5% VDC, 200 mA max; 3 watts max;  
FMA 1400 ranges above 10 L/min:  
(100 sLit/min max) +15 +5% VDC, 80 mA max,  
1.2 watts max; -15 +5% VDC, 600 mA max,  
9 watts max.  
Power inputs are each protected by a 750mA M (medium time-lag) resettable fuse, and a  
rectifier diode for polarity protection.  
WETTED MATERIALS: 316 stainless steel, 416 stainless steel, VITON7 O-rings;  
BUNA-N7, NEOPRENE7 or KALREZ7 O-rings are optional.  
Omega7 makes no expressed or implied guarantees of corrosion resistance of mass flow  
meters as pertains to different flow media reacting with components of meters. It is the  
customers' sole responsibility to select the model suitable for a particular gas based on  
the fluid contacting (wetted) materials offered in the different models.  
INLET AND OUTLET CONNECTIONS: 1/4" (FMA 1400 ranges up to and above10 L/min)  
or 3/8" (FMA 1400 for ranges above 10 L/min) compression fittings standard; 1/8" or 3/8"  
compression fittings and 1/4" VCR7 fittings are optional.  
TRANSDUCER INTERFACE CABLE: Flat cable with female 15-pin "D" connector ends is  
standard. Optional shielded cable is available with male/female 15-pin “D” connector  
ends. [Cable length may not exceed 9.5 feet (3 meters)]  
4.3  
CE Compliance  
Any model FMA 1500 or FMA 1400 bearing a CE marking on it, is in compliance with the  
below stated test standards currently accepted.  
EMC Compliance with 89/336/EEC as amended;  
Emission Standard: EN 55011:1991, Group 1, Class A  
Immunity Standard: EN 55082 1:1992  
7
FLOW RANGES  
TABLE I FMA 1500/1400 FOR RANGES UP TO 10 L/MIN  
LOW FLOW MASS FLOW METER/CONTROLLERS*  
CODE  
scc/min [N2]  
std liters/min [N2]  
CODE  
02  
04  
0 to 10  
0 to 20  
14  
16  
0 to 1  
0 to 2  
06  
08  
10  
12  
0 to 50  
0 to 100  
0 to 200  
0 to 500  
18  
20  
0 to 5  
0 to 10  
TABLE II FMA 1500/1400 FOR RANGES ABOVE 10 L/MIN  
MEDIUM FLOW MASS FLOW METER/CONTROLLERS*  
standard liters/min [N2]  
CODE  
23  
15  
20  
30  
40  
50  
24  
26  
27  
28  
TABLE III FMA 1500/1400 FOR RANGES ABOVE 10 L/MIN  
HIGH FLOW MASS FLOW METER/CONTROLLERS*  
CODE  
standard liters/min [N2]  
40  
41  
42  
60  
80  
100  
F
F
*Flow rates are stated for Nitrogen at STP conditions [i.e. 70 F (21.1 C) at 1 atm].  
For other gases use the K factor as a multiplier from APPENDIX 2.  
8
TABLE IV PRESSURE DROPS  
MAXIMUM PRESSURE DROP  
FLOW RATE  
MODEL  
[std liters/min]  
[mm H2O]  
[psid]  
0.04  
0.09  
0.44  
1.18  
2.18  
3.23  
4.56  
[mbar]  
2.5  
up to 10  
15  
25  
63  
6.4  
20  
300  
800  
1480  
2200  
3100  
30  
30  
81  
40  
150  
223  
314  
FMA 1500  
50  
60  
80  
4422  
6.50  
448  
100  
up to 10  
5500  
720  
8.08  
1.06  
3.87  
2.00  
3.50  
5.50  
8.00  
11.00  
15.00  
18.89  
557  
75  
15  
20  
30  
40  
50  
60  
80  
100  
2630  
1360  
2380  
3740  
5440  
7480  
10204  
12850  
266  
138  
241  
379  
551  
758  
1034  
1302  
FMA 1400  
TABLE V APPROXIMATE WEIGHTS  
MODEL WEIGHT  
SHIPPING WEIGHT  
FMA 1500 ranges up to 10 L/min transmitter  
1.71 lbs (0.78 kg) 3.21 lbs (1.46 kg)  
FMA 1500 ranges above 10 L/min transmitter 2.42 lbs (1.10 kg) 3.92 lbs (1.78 kg)  
FMA 1400 ranges up to 10 L/min transmitter 2.20 lbs (1.00 kg) 3.70 lbs (1.68 kg)  
FMA 1400 ranges above 10 L/min transmitter 2.84 lbs (1.29 kg) 4.34 lbs (1.97 kg)  
5.  
5.1  
OPERATING INSTRUCTIONS  
Preparation and Warm Up  
It is assumed that the Mass Flow Meter or Controller has been correctly installed  
and thoroughly leak tested as described in section 2. Make sure the flow source  
is OFF. Power up the transducer using your own power supply (or turn the  
POWER switch to the ON position at the front panel of your FMA14PD Series  
Command Module). Allow the Mass Flow Meter or Controller to warm-up for a  
minimum of 15 minutes.  
9
During initial powering of the FMA 1400/1500 transducer, the flow output signal will be  
indicating a higher than usual output. This is indication that the FMA 1400/1500 trans-  
ducer has not yet attained it's minimum operating temperature. This condition will  
automatically cancel within a few minutes and the transducer should eventually zero.  
Caution: If the valve is left in the AUTO (control) or OPEN mode for  
an extended period of time, it may become warm or even hot to the the  
touch. Use care in avoiding direct contact with the valve during operation.  
ƽ
5.2  
Flow Signal Output Readings  
The flow signal output can be viewed on the panel meter, digital multimeter, or  
other display device used as shown in figure 2-1.  
When using the accessory FMA14PD Series Command Module the flow rate will  
appear on the display at the front panel.The observed reading is a 0 to 100% indi-  
cation (direct engineering units are optional). [If using a multichannel readout, be  
sure that the CHANNEL selector switch is set to the correct channel.]  
Analog output flow signals of 0 to 5 VDC or optional 4 to 20 mA are attained at  
the appropriate pins of the 15-pin "D" connector (see Figure 2-3) on the top of the  
FMA 1400/1500 transducer. The output flow signal is also available at the DATA  
connector on the rear panel of the FMA14PD Series Command Module.  
The default calibration is performed for 0 to 5 VDC output signal. If 4-20 mA out-  
put signal is used for flow indication on the FMA 1400, the accuracy of the actual  
flow rate will be in the specified range (+1.0%) of full scale, but the total uncer-  
tainty of the output reading may be in the range of +2.0% of full scale. Optional  
calibration for 4-20 mA output signal is available upon request at time of order.  
Meter signal output is linearly proportional to the mass molecular flow rate of the  
gas being metered. The full scale range and gas for which your meter has been  
calibrated are shown on the flow transducer's front label.  
5.3  
Swamping Condition  
If a flow of more than 10% above the maximum flow rate of the Mass Flow Meter  
is taking place, a condition known as "swamping" may occur. Readings of a  
"swamped" meter cannot be assumed to be either accurate or linear. Flow must  
be restored to below 110% of maximum meter range. Once flow rates are lowered  
to within calibrated range, the swamping condition will end. Operation of the meter  
above 110% of maximum calibrated flow may increase recovery time.  
5.4  
Set Point Reference Signal (FMA 1400)  
FMA 1400 flow controllers have a built-in solenoid valve and allow the user to set  
the flow to any desired flow rate within the range of the particular model installed.  
This valve is normally closed when no power is applied.  
The set point input responds to an analog 0 to 5 VDC reference voltage. This volt-  
10  
age is a linear representation of 0 to 100% of the full scale mass flow rate.  
Response time to set point changes are 1 second (FMA 1400 for ranges up to 10  
L/min) and 2 seconds (FMA 1400 for ranges above 10 L/min) to within 2% of the  
final flow over 25 to 100% of full scale.  
On pin 6 of the FMA 1400 transducer is a regulated and constant +5VDC output  
signal. This signal may be used in conjunction with a local set point potentiome-  
ter for flow setting.  
FIGURE 5-1, LOCAL SET POINT POTENTIOMETER CONNECTIONS  
It is recommended that a potentiometer between 5K to 100K ohm and capable of  
at least 10-turns or more for adjustment be used. Use the control potentiometer  
to command the percentage of flow desired.  
Alternatively, a variable 0 to 5VDC analog signal may be applied directly to the SET  
POINT and COMMON connections of the FMA 1400 transducer (see Figure 2-1).  
5.5  
TTL, Valve OFF Control (FMA 1400)  
It may, at times, be desirable to set the flow and maintain that setting while being  
able to turn the flow control valve off and on again. This can be accomplished by  
applying a (TTL compatible) high and low signal of +5 VDC and 0 VDC to pin 8,  
on the 15-pin "D" connector. When 0 VDC (LOW) signal is applied, the solenoid  
valve is not powered and therefore will remain normally closed. Conversely, a +5  
VDC (HIGH) signal applied will allow the solenoid valve to remain active.The sole-  
noid valve will remain active when the VALVE OFF pin remains "floating".  
The simplest means for utilizing the VALVE OFF control feature, is to connect a  
toggle switch between the COMMON and VALVE OFF pins of the FMA 1400  
transducer. Toggling the switch on and off will allow for activating and deactivating  
the solenoid valve.  
5.6  
Valve Test/Purge (FMA 1400)  
At times, it may be necessary to purge the flow system with a neutralizing gas  
such as pure dry nitrogen.The FMA 1400 transducer is capable of a full open con-  
dition for the solenoid valve, regardless of set point conditions. For FMA 1400's  
11  
utilizing +15VDC valve configuration, connecting the TEST pin 12 on 15-pin "D"  
connectors) to ground will fully open the valve. For FMA 1400's with a +30VDC  
valve configuration, connecting the TEST pin to +15VDC will fully open the valve.  
6.  
MAINTENANCE  
Introduction  
6.1  
It is important that the Mass Flow Meter/Controller is used with clean, filtered  
gases only. Liquids may not be metered. Since the RTD sensor consists, in part,  
of a small capillary stainless steel tube, it is prone to occlusion due to impedi-  
ments or gas crystallization. Other flow passages are also easily obstructed.  
Therefore, great care must be exercised to avoid the introduction of any potential  
flow impediment. To protect the instrument a 50 micron (FMA 1500/1400 for  
ranges up to 10 L/min) or 60 micron (FMA 1500/1400 for ranges above 10 L/min)  
filter is built into the inlet of the flow transducer. The filter screen and the flow  
paths may require occasional cleaning as described below. There is no other rec-  
ommended maintenance required. It is good practice, however, to keep the meter  
away from vibration, hot or corrosive environments and excessive RF or magnet-  
ic interference.  
If periodic calibrations are required they should be performed by qualified per-  
sonnel and calibrating instruments, as described in section 7. It is recommended  
that units are returned to Omega7 for repair service and calibration.  
CAUTION: TO PROTECT SERVICING PERSONNEL IT IS MANDATORY  
THAT ANY INSTRUMENT BEING SERVICED IS COMPLETELY  
ƽ
PURGED AND NEUTRALIZED OF TOXIC, BACTERIOLOGICALLY  
INFECTED, CORROSIVE OR RADIOACTIVE CONTENTS.  
6.2  
Flow Path Cleaning  
Before attempting any disassembly of the unit for cleaning, try inspecting the flow  
paths by looking into the inlet and outlet ends of the meter for any debris that may  
be clogging the flow through the meter. Remove debris as necessary. If the flow  
path is not unclogged, then proceed with steps below.  
Do not attempt to disassemble the sensor. If blockage of the sensor tube is not  
alleviated by flushing through with cleaning fluids, please return meter to Omega7  
for servicing.  
6.2.1 Restrictor Flow Element (RFE)  
The Restrictor Flow Element (RFE) is a precision flow divider inside the trans-  
ducer, which splits the inlet gas flow by a preset amount to the sensor and main  
flow paths. The particular RFE used in a given Mass Flow Meter/Controller  
depends on the gas and flow range of the instrument.  
12  
6.2.2 FMA 1400/1500 for ranges up to 10 L/min  
Unscrew the inlet compression fitting of meter. Note that the Restrictor Flow  
Element (RFE) is connected to the inlet fitting.  
Carefully disassemble the RFE from the inlet connection. The 50 micron filter  
screen will now become visible. Push the screen out through the inlet fitting. Clean  
or replace each of the removed parts as necessary. If alcohol is used for clean-  
ing, allow time for drying.  
Inspect the flow path inside the transducer for any visible signs of contaminant's.  
If necessary, flush the flow path through with alcohol. Thoroughly dry the flow  
paths by flowing clean dry gas through.  
Carefully re-install the RFE and inlet fitting, avoiding any twisting and deforming  
the RFE. Be sure that no dust has collected on the O-ring seal.  
Note: Over tightening will deform and render the RFE defective.  
ƽ
It is advisable that at least one calibration point be checked after re-installing the  
inlet fitting - see section 7.  
6.2.3 FMA 1400/1500 for ranges above 10 L/min  
Unscrew the four socket head cap screws (two 10-24 and two 6-32) at the inlet  
side of the meter.This will release the short square block containing the inlet com-  
pression fitting.  
The 60 micron filter screen will now become visible. Remove the screen. DO NOT  
remove the RFE inside the flow transducer! Clean or replace each of the removed  
parts as necessary. If alcohol is used for cleaning, allow time for drying.  
Inspect the flow path inside the transducer for any visible signs of contaminant's.  
If necessary, flush the flow path through with alcohol. Thoroughly dry the flow  
paths by flowing clean dry gas through.  
Re-install the inlet parts and filter screen. Be sure that no dust has collected on  
the O-ring seal.  
It is advisable that at least one calibration point be checked after re-installing the  
inlet fitting - see section 7.  
6.2.4 Valve Maintenance (FMA 1400)  
The solenoid valve consists of 316 and 416 stainless steel, and VITON7 (or  
optional NEOPRENE7 or KALREZ7) O-rings and seals. No regular maintenance  
is required except for periodic cleaning.Various corrosive gases may demand  
more frequent replacement of VITON7 O- rings and seals inside the valve. Be sure  
to use an elastomer material, appropriate for your specific gas application.  
13  
Contact Omega7 for optional sealing materials available.  
Set the FMA 1400 into PURGE mode, and attempt to flush through with a clean,  
filtered, and neutral gas such as nitrogen. [Another option for fully opening the  
valve is to remove the plastic cap on top of the valve, and turn the set screw coun-  
terclockwise until it stops. See section 7.4 for valve adjustment, to return the valve  
to functional use.]  
7.  
CALIBRATION PROCEDURES  
Note: Removal of the factory installed calibration seals and/or any  
adjustments made to the meter, as described in this section, will void  
any calibration warranty applicable.  
ƽ
7.1  
Flow Calibration  
Omega7 Engineering Flow Calibration Laboratory offers professional calibration  
support for Mass Flow Meters and Controllers, using precision calibrators under  
strictly controlled conditions. NIST traceable calibrations are available.  
Calibrations can also be performed at customers' site using available standards.  
Factory calibrations are performed using NIST traceable precision volumetric cal-  
ibrators incorporating liquid sealed frictionless actuators.  
Generally, calibrations are performed using dry nitrogen gas. The calibration can  
then be corrected to the appropriate gas desired based on relative correction [K]  
factors shown in the gas factor table see Appendix 2. A reference gas, other than  
nitrogen, may be used to closer approximate the flow characteristics of certain  
gases. This practice is recommended when a reference gas is found with ther-  
modynamic properties similar to the actual gas under consideration. The appro-  
priate relative correction factor should be recalculated - see section 9.  
It is standard practice to calibrate Mass Flow Meters/Controllers with dry nitrogen  
gas at 70FF (21.1FC), 20 psig (1.4 bars) [25 psig (1.7 bars) for FMA 1400 ranges  
above 10 L/min] inlet pressure and 0 psig (0 bar) outlet pressure. It is best to cal-  
ibrate the FMA 1400/1500 transducers to actual operating conditions. Specific gas  
calibrations of non-toxic and non-corrosive gases are available at specific condi-  
tions. Please contact Omega7 for a price quotation.  
It is recommended that a flow calibrator of at least four times better collective  
accuracy than that of the Mass Flow Meter/Controller to be calibrated be used.  
Equipment required for calibration includes a flow calibration standard and a cer-  
tified high sensitivity multimeter (which together have a collective accuracy of  
+0.25% or better), an insulated (plastic) screwdriver, a flow regulator (example:  
metering needle valve) installed upstream from the Mass Flow Meter and a pres-  
sure regulated source of dry filtered nitrogen gas (or other suitable reference gas).  
The gas and ambient temperature, as well as inlet and outlet pressure conditions  
should be set up in accordance with actual operating conditions.  
Calibration potentiometer locations are illustrated in Figure 7-1.  
14  
FIGURE 7-1, CALIBRATION POTENTIOMETER LOCATIONS  
7.2  
Calibration of FMA 1500 Mass Flow Meters  
All adjustments in this section are made from the outside of the meter, there is no  
need to disassemble any part of the instrument.  
FMA 1500 Mass Flow Meters may be field recalibrated/checked for the same  
range they were originally factory calibrated for. When linearity adjustment is  
needed, or flow range changes are being made proceed to step 7.3. Flow range  
changes may require a different Restrictor Flow Element (RFE). Additionally, a dif-  
ferent Solenoid Valve Orifice for the FMA 1400 Mass Flow Controller (see Table VI)  
may also be required. Consult Omega7 for more information.  
7.2.1 Connections and Initial Warm Up  
Connect the multimeter to output pins* [2] and [3] of the 15-pin “D” connector for  
0-5 VDC (or pins [5] and [15] for optional 4-20 mA) (see Figure 2-3).  
* If you are calibrating a Mass Flow Meter System that incorporates a  
FMA14PD Series Command Module, the multimeter may be connected via  
the DATA connector which is located at the back of the Command Module.  
Power up the Mass Flow Meter for at least 30 minutes prior to commencing the  
calibration procedure.  
15  
7.2.2 ZERO Adjustment  
Shut off the flow of gas into the Mass Flow Meter. To ensure that no seepage or  
leak occurs into the meter, it is good practice to temporarily disconnect the gas  
source. Using the multimeter and the insulated screwdriver, adjust the ZERO  
potentiometer [R29] through the access window for 0 VDC (or 4 mA respectively)  
at zero flow.  
7.2.3 SPAN Adjustment  
Reconnect the gas source. Using the flow regulator, adjust the flow rate to 100%  
of full scale flow. Check the flow rate indicated against the flow calibrator. If the  
deviation is less than +10% of full scale reading, correct the SPAN potentiometer  
[R21] setting by using the insulated screwdriver through the access window, to  
eliminate any deviation. If the deviation is larger than +10% of full scale reading,  
a defective condition may be present.  
LIKELY REASONS FOR A MALFUNCTIONING SIGNAL MAY BE:  
M Occluded or contaminated sensor tube.  
M Leaking condition in the FMA 1500 transducer or the gas line and fittings.  
M For gases other than nitrogen, recheck appropriate "K" factor from Gas Factor Table.  
M Temperature and/or pressure correction errors.  
See also section 8 TROUBLESHOOTING. If after attempting to remedy the above  
conditions, a malfunction still persists, return the meter for factory service, see  
section 1.1.  
At this point the calibration is complete. However, it is advisable that several addi-  
tional points between 0 and 100%, such as 25%, 50%, and 75% flow be checked.  
If discrepancies are found, proceed to step 7.3 for Linearity Adjustment.  
7.3  
Linearity Adjustment  
All adjustments in this section are made from the outside of the meter, there is  
no need to disassemble any part of the instrument.  
7.3.1 Connections and Initial Warm Up  
Connect the multimeter to output pins* [2] and [3] for 0 5 VDC (or pins [5] and [15]  
for optional 4-20 mA) (see Figure 2-3).  
* If you are calibrating a Mass Flow Meter System that incorporates a  
FMA14PD Series Command Module, the multimeter may be connected via  
the DATA connector which is located at the back of the Command Module.  
Power up the Mass Flow Meter for at least 30 minutes prior to commencing the  
calibration procedure.  
16  
7.3.2 ZERO Adjustment  
Shut off the flow of gas into the Mass Flow Meter. To ensure that no seepage or  
leak occurs into the meter, it is good practice to temporarily disconnect the gas  
source. Using the multimeter and the insulated screwdriver, adjust the ZERO  
potentiometer [R29] through the access window for 0 VDC (or 4 mA respectively)  
at zero flow.  
7.3.3 25% Flow Adjustment  
Reconnect the gas source. Using the flow regulator, adjust the flow rate to 25% of  
full scale flow. Check the flow rate indicated against the flow calibrator. Adjust the set-  
ting for potentiometer [R21] by using the insulated screwdriver through the access  
window, until the output of the flowmeter reads 1.25VDC +37mV (or 8mA +0.12mA).  
7.3.4 50% Flow Adjustment  
Using the flow regulator, increase the flow rate to 50% of full scale flow. Check the  
flow rate indicated against the flow calibrator. Adjust the setting for potentiometer  
[R45] by using the insulated screwdriver through the access window, until the out-  
put of the flowmeter reads 2.50VDC +37mV (or 12mA +0.12mA).  
7.3.5 75% Flow Adjustment  
Increase the flow rate to 75% of full scale flow. Check the flow rate indicated  
against the flow calibrator. Adjust the setting for potentiometer [R44] by using the  
insulated screwdriver through the access window, until the output of the flowme-  
ter reads 3.75VDC +37mV (or 16mA +0.12mA).  
7.3.6 100% Flow Adjustment  
Increase the flow rate to 100% of full scale flow. Check the flow rate indicated  
against the flow calibrator. Adjust the setting for potentiometer [R43] by using the  
insulated screwdriver through the access window, until the output of the flowme-  
ter reads 5.00VDC +37mV (or 20mA +0.12mA).  
Repeat steps 7.3.3 to 7.3.6 at least once more.  
7.4  
Calibration of FMA 1400 Mass Flow Controllers  
All adjustments in this section are made from the outside of the meter, there is no  
need to disassemble any part of the instrument.  
FMA 1400 Mass Flow Controllers may be field recalibrated/checked for the same  
range they were originally factory calibrated for.  
7.4.1 Disable Solenoid Valve  
Remove the round plastic cap on top of the solenoid valve. Turn the set screw on  
top of the valve counterclockwise until it stops, to open the valve. Set the valve  
into PURGE mode. This step essentially bypasses the flow control properties of  
17  
the transducer. The unit will now act as a mass flow meter.  
CAUTION: If the valve is left in the AUTO (control) or OPEN mode for an  
extended period of time, it may become warm or even hot to the touch.  
Use care in avoiding direct contact with the valve during operation.  
ƽ
Follow steps outlined in section 7.2 and 7.3, then continue with step 7.4.2 below.  
7.4.2 Valve Adjustment  
Discontinue the PURGE mode (set valve for the closed position). Apply an inlet  
pressure of 5 psig, and atmospheric pressure at the outlet. If a small flow occurs,  
turn the set screw on top of the solenoid valve clockwise until the flow through the  
FMA 1400 just stops.  
7.4.3 Full Scale Flow Adjustment  
Fully open the flow regulator upstream of the FMA 1400. Increase the inlet pres-  
sure to 20 psig (25 psig for FMA 1400 units above 10 L/min). Apply a +5.00 VDC  
set point reference. Using the calibrator check the flow rate. If necessary, adjust  
R21 to match the desired full scale flow rate. [In control mode, turning R21 clock-  
wise will decrease the flow. Conversely, turning R21 counterclockwise will  
increase the flow through the FMA 1400.]  
7.4.4 25% Flow Adjustment  
Change the set point to 1.25 VDC to control at 25% of full scale flow. Check the  
flow rate indicated against the flow calibrator. If the flow rate is not within +0.75%  
of full scale, re-adjust the setting for potentiometer [R21], until the flow output is  
correct.  
7.4.5 50% Flow Adjustment  
Change the set point to 2.50 VDC to control at 50% of full scale flow. Check the flow  
rate indicated against the flow calibrator. If the flow rate is not within +0.75% of full  
scale, re-adjust the setting for potentiometer [R45], until the flow output is correct.  
7.4.6 75% Flow Adjustment  
Change the set point to 3.75 VDC to control at 75% of full scale flow. Check the flow  
rate indicated against the flow calibrator. If the flow rate is not within +0.75% of full  
scale, re-adjust the setting for potentiometer [R44], until the flow output is correct.  
7.4.7 100% Flow Adjustment  
Change the set point to 5.00 VDC to control at 100% of full scale flow. Check the flow  
rate indicated against the flow calibrator. If the flow rate is not within +0.75% of full  
scale, re-adjust the setting for potentiometer [R43], until the flow output is correct.  
Repeat steps 7.4.4 to 7.4.7 at least once more.  
18  
TABLE VI FMA 1400 SOLENOID VALVE ORIFICE SELECTION TABLE  
FLOW RATE [N ]  
2
ORIFICE PART NUMBER  
OR.010  
under 10 sccm  
OR.020  
OR.040  
OR.055  
OR.063  
OR.073  
OR.094  
OR.125  
10 to 1000 sccm  
1 to 5 slpm  
5 to 10 slpm  
10 to 15 slpm  
15 to 20 slpm  
20 to 50 slpm  
50 to 100 slpm  
8.  
TROUBLESHOOTING  
Common Conditions  
8.1  
Your Mass Flow Meter/Controller was thoroughly checked at numerous quality  
control points during and after manufacturing and assembly operations. It was cal-  
ibrated in accordance to your desired flow and pressure conditions for a given gas  
or a mixture of gases.  
It was carefully packed to prevent damage during shipment. Should you feel that  
the instrument is not functioning properly please check for the following common  
conditions first:  
Are all cables connected correctly?  
Are there any leaks in the installation?  
Is the power supply correctly selected according to requirements?  
When several meters are used a power supply with appropriate  
current rating should be selected.  
Were the connector pinouts matched properly?  
When interchanging with other manufacturers' equipment, cables  
and connectors must be carefully wired for correct pin configurations.  
Is the pressure differential across the instrument sufficient?  
19  
8.2  
Troubleshooting Guide  
LIKELY REASON  
REMEDY  
INDICATION  
power supply off  
check connection of power supply  
lack of  
reading or  
output  
fuse blown  
(FMA 1400/1500)  
disconnect FMA 1400/1500 transducer  
from power supply; remove the short-  
ing condition or check polarities; fuse  
resets automatically  
fuse blown  
(FMA14PD Series)  
disconnect power cord from AC  
supply; remove and inspect fuses at  
AC power input connector of FMA14PD  
Series; replace as necessary  
filter screen obstructed at inlet REMOVE CAUSE OF SHORT CIRCUIT!  
occluded sensor tube  
flush clean or disassemble to remove  
impediments or replace  
flush clean or disassemble to remove  
impediments or return to factory for  
replacement  
pc board defect  
return to factory for replacement  
re-adjust valve (section 7.4)  
valve adjustment wrong  
fuse blown  
(FMA 1400/1500)  
disconnect FMA 1400/1500 transducer  
from power supply; remove the short-  
ing condition or check polarities; fuse  
resets automatically  
output reads  
at (+) or (- )  
saturation  
only  
REMOVE CAUSE OF SHORT CIRCUIT!  
inadequate gas pressure  
apply appropriate gas pressure  
flow reading  
does not  
filter screen obstructed at inlet flush clean or disassemble to remove  
impediments or replace  
coincide with  
the set point  
(FMA 1400  
models only)  
ground loop  
signal and power supply commons are  
different  
inadequate gas pressure  
apply appropriate gas pressure  
no response  
to set point  
(FMA 1400  
models only)  
cable or connector  
malfunction  
check cables and all connections or  
replace  
set point is too low  
(<2% of full scale)  
re-adjust set point  
valve adjustment wrong  
re-adjust valve (section 7.4)  
20  
LIKELY REASON  
REMEDY  
INDICATION  
gas leak  
locate and correct  
unstable or no  
zero reading  
pc board defective  
return to factory for replacement  
full scale out-  
put at "no flow"  
condition or  
with valve  
defective sensor  
gas Leak  
return to factory for replacement  
locate and repair  
closed  
gas metered is not the same as use matched calibration  
what meter was calibrated for  
calibration off  
composition of gas changed  
see K factor tables in APPENDIX 2  
gas leak  
locate and correct  
pc board defective  
RFE dirty  
return to factory for replacement  
flush clean or disassemble to remove  
impediments  
occluded sensor tube  
flush clean or disassemble to remove  
impediments or return to factory for  
replacement  
filter screen obstructed at inlet flush clean or disassemble to remove  
impediments or replace  
transducer is not mounted  
properly  
check for any tilt or change in the  
mounting of the transducer; generally,  
units are calibrated for horizontal  
installation (relative to the sensor tube)  
incorrect valve adjustment  
pc board defect  
re-adjust valve (section 7.4)  
FMA 1400  
valve  
does not work  
in open  
position  
return to factory for replacement  
cable or connectors malfunction check cable and connectors or replace  
differential pressure too high  
insufficient inlet pressure  
incorrect valve adjustment  
pc board defect  
decrease pressure to correct level  
adjust appropriately  
FMA 1400  
re-adjust valve (section 7.4)  
return to factory for replacement  
valve does not  
work in close  
position  
cable or connectors malfunction check cable and connectors or replace  
orifice obstructed  
disassemble to remove impediments  
or return to factory  
21  
For best results it is recommended that instruments are returned to the factory  
for servicing. See section 1.3 for return procedures.  
8.3  
Technical Assistance  
Omega7 Engineering will provide technical assistance over the phone to qualified  
repair personnel. Please call our Flow Department (800) 872-9436 extension  
2298.  
9.  
CALIBRATION CONVERSIONS FROM  
REFERENCE GASES  
The calibration conversion incorporates the K factor. The K factor is derived from  
gas density and coefficient of specific heat. For diatomic gases:  
1
=
Kgas  
d X Cp  
where d = gas density (gram/liter)  
Cp  
= coefficient of specific heat (cal/gram)  
Note in the above relationship that d and Cp are usually chosen at standard con-  
ditions of one atmosphere and 25F C.  
If the flow range of a Mass Flow Controller or Controller remains unchanged, a  
relative K factor is used to relate the calibration of the actual gas to the reference  
gas.  
Qa  
Qr  
Ka  
Kr  
=
=
K
where Qa  
=
=
=
=
mass flow rate of an actual gas (sccm)  
mass flow rate of a reference gas (sccm)  
K factor of an actual gas  
Qr  
Ka  
Kr  
K factor of a reference gas  
For example, if we want to know the flow rate of oxygen and wish to calibrate  
with nitrogen at 1000 SCCM, the flow rate of oxygen is:  
QO2 = Qa = Qr x K = 1000 X 0.9926 = 992.6 sccm  
where K = relative K factor to reference gas (oxygen to nitrogen)  
22  
APPENDIX 1  
COMPONENTS DIAGRAMS  
FMA 1500 METERING PC BOARD  
(ALSO INCORPORATED IN FMA 1400)  
FMA 1400 CONTROL PC BOARD  
23  
APPENDIX 2  
GAS FACTOR TABLE (“K” FACTORS)  
Cp  
[Cal/g]  
Density  
[g/I]  
K FACTOR  
Relative to N2  
ACTUAL GAS  
Acetylene C2H2  
Air  
.5829  
1.0000  
.4346  
.7310  
1.4573  
.6735  
.4089  
.5082  
.8083  
.38  
.4036  
.240  
1.162  
1.293  
1.787  
.760  
Allene (Propadiene) C3H4  
Ammonia NH3  
.352  
.492  
Argon Ar  
.1244  
.1167  
.1279  
.1778  
.0539  
.0647  
.1369  
.1161  
.1113  
.3514  
.4007  
.3648  
.336  
1.782  
3.478  
5.227  
3.025  
7.130  
11.18  
7.803  
6.108  
6.644  
2.413  
2.593  
2.503  
2.503  
2.503  
1.964  
3.397  
1.250  
6.860  
3.926  
2.945  
2.680  
3.163  
4.125  
3.858  
5.326  
6.892  
4.660  
2.322  
2.742  
1.877  
1.799  
1.235  
Arsine AsH3  
Boron Trichloride BCl3  
Boron Triflouride BF3  
Bromine Br2  
Boron Tribromide Br3  
Bromine Pentaflouride BrF5  
Bromine Triflouride BrF3  
Bromotrifluoromethane (Freon-13 B1) CBrF3  
1,3-Butadiene C4H6  
.26  
.3855  
.3697  
.3224  
.2631  
.2994  
.324  
Butane C4H10  
1-Butane C4H8  
2-Butane C4H8 CIS  
2-Butane C4H8 TRANS  
Carbon Dioxide CO2  
.291  
.374  
.7382  
.6026  
1.00  
.2016  
.1428  
.2488  
.1655  
.1654  
.1710  
.1651  
.114  
Carbon Disulfide CS2  
Carbon Monoxide CO  
Carbon Tetrachloride CCl4  
Carbon Tetrafluoride (Freon-14)CF4  
Carbonyl Fluoride COF2  
Carbonyl Sulfide COS  
Chlorine Cl2  
.31  
.42  
.5428  
.6606  
.86  
Chlorine Trifluoride ClF3  
Chlorodifluoromethane (Freon-22)CHClF2  
Chloroform CHCl3  
.4016  
.4589  
.3912  
.2418  
.3834  
.61  
.1650  
.1544  
.1309  
.164  
Chloropentafluoroethane(Freon-115)C2ClF5  
Chlorotrifluromethane (Freon-13) CClF3  
CyanogenC2N2  
.153  
.2613  
.1739  
.3177  
1.722  
.508  
CyanogenChloride CICN  
Cyclopropane C3H5  
.6130  
.4584  
1.00  
Deuterium D2  
Diborane B2H6  
.4357  
24  
Cp  
[Cal/g]  
Density  
[g/I]  
K Factor  
Relative to N2  
ACTUAL GAS  
Dibromodifluoromethane CBr2F2  
Dichlorodifluoromethane (Freon-12) CCl2F2  
Dichlofluoromethane (Freon-21) CHCl2F  
Dichloromethylsilane (CH3)2SiCl2  
Dichlorosilane SiH2Cl2  
Dichlorotetrafluoroethane (Freon-114) C2Cl2F4  
1,1-Difluoroethylene (Freon-1132A) C2H2F2  
Dimethylamine (CH3)2NH  
Dimethyl Ether (CH3)2O  
2,2-Dimethylpropane C3H12  
Ethane C2H6  
.1947  
.3538  
.4252  
.2522  
.4044  
.2235  
.4271  
.3714  
.3896  
.2170  
.50  
9.362  
5.395  
4.592  
5.758  
4.506  
7.626  
2.857  
2.011  
2.055  
3.219  
1.342  
2.055  
2.413  
2.879  
1.251  
1.965  
1.695  
3.127  
6.129  
5.395  
4.660  
6.644  
3.926  
4.592  
3.858  
8.360  
7.626  
6.892  
8.397  
3.418  
9.565  
.1786  
6.157  
3.845  
.0899  
3.610  
1.627  
1.206  
.15  
.1432  
.140  
.1882  
.150  
.1604  
.224  
.366  
.3414  
.3914  
.420  
Ethanol C2H6O  
.3918  
.3225  
.3891  
.60  
.3395  
.3513  
.244  
Ethyl Acetylene C4H6  
Ethyl Chloride C2H5Cl  
Ethylene C2H4  
.365  
Ethylene Oxide C2H4O  
Fluorine F2  
.5191  
.9784  
.4967  
.3287  
.3538  
.3834  
.3697  
.4210  
.4252  
.4589  
.2031  
.2240  
.2418  
.1760  
.5696  
.2668  
1.454  
.2421  
.1792  
1.0106  
1.000  
1.000  
1.070  
.268  
.1873  
.176  
Fluoroform (Freon-23) CHF3  
Freon-11 CCl3F  
.1357  
.1432  
.153  
Freon-12 CCl2F2  
Freon-13 CClF3  
Freon-13B1 CBrF3  
.1113  
.1654  
.140  
Freon-14 CF4  
Freon-21 CHCl2F  
Freon-22 CHClF2  
.1544  
.161  
Freon-113 CCl2FCClF2  
Freon-114 C2Cl2F4  
.160  
Freon-115 C2ClF5  
.164  
Freon-C318 C4F6  
.185  
Germane GeH4  
.1404  
.1071  
1.241  
.1834  
.3968  
3.419  
.0861  
.1912  
.3171  
Germanium Tetrachloride GeCl4  
Helium He  
Hexafluoroethane C2F6 (Freon-116)  
Hexane C6H14  
Hydrogen H2  
Hydrogen Bromide HBr  
Hydrogen Chloride HCl  
Hydrogen Cyanide HCN  
25  
Cp  
[Cal/g]  
Density  
[g/I]  
K Factor  
Relative to N2  
Actual Gas  
Hydrogen Fluoride HF  
.9998  
.9987  
.7893  
.80  
.3479  
.0545  
.1025  
.2397  
.1108  
.3872  
.3701  
.0593  
.5328  
.3274  
.3547  
.1106  
.1926  
.3221  
.2459  
.164  
.893  
5.707  
3.613  
1.520  
9.90  
Hydrogen Iodide HI  
Hydrogen Selenide H2Se  
Hydrogen Sulfide H2S  
Iodine Pentafluoride IF5  
Isobutane CH(CH3)3  
Isobutylene C4H6  
.2492  
.27  
3.593  
2.503  
3.739  
.715  
.2951  
1.453  
.7175  
.5843  
.4313  
.5835  
.6299  
.68  
Krypton Kr  
Methane CH4  
Methanol CH3  
1.429  
1.787  
4.236  
2.253  
1.518  
2.146  
6.669  
9.366  
2.011  
1.386  
.900  
Methyl Acetylene C3H4  
Methyl Bromide CH2Br  
Methyl Chloride CH3Cl  
Methyl Fluoride CH3F  
Methyl Mercaptan CH3SH  
Methyl Trichlorosilane (CH3)SiCl3  
Molybdenum Hexafluoride MoF6  
Monoethylamine C2H5NH2  
Monomethylamine CH3NH2  
Neon NE  
.5180  
.2499  
.2126  
.3512  
.51  
.1373  
.387  
.4343  
.246  
1.46  
Nitric Oxide NO  
.990  
.2328  
.2485  
.1933  
.1797  
.1632  
.2088  
.185  
1.339  
1.25  
Nitrogen N2  
1.000  
.737  
Nitrogen Dioxide NO2  
Nitrogen Trifluoride NF3  
Nitrosyl Chloride NOCl  
Nitrous Oxide N2O  
2.052  
3.168  
2.920  
1.964  
8.397  
1.427  
2.406  
2.144  
2.816  
3.219  
4.571  
8.388  
4.418  
1.517  
6.843  
5.620  
.4802  
.6134  
.7128  
.176  
Octafluorocyclobutane (Freon-C318) C4F6  
Oxygen O2  
.9926  
.6337  
.446  
.2193  
.1917  
.195  
Oxygen Difluoride OF2  
Ozone  
Pentaborane B5H9  
.2554  
.2134  
.3950  
.174  
.38  
Pentane C5H12  
.398  
Perchloryl Fluoride ClO3F  
Perfluoropropane C3F8  
Phosgene COCl2  
.1514  
.197  
.4438  
1.070  
.36  
.1394  
.2374  
.1324  
.1610  
Phosphine PH3  
Phosphorous Oxychloride POCl3  
Phosphorous Pentafluoride PH5  
.3021  
26  
Cp  
[Cal/g]  
Density  
[g/I]  
K Factor  
Relative to N2  
Actual Gas  
Phosphorous Trichloride PCl3  
Propane C3H8  
.30  
.1250  
.399  
6.127  
1.967  
1.877  
1.433  
7.580  
4.643  
2.858  
6.516  
4.562  
4.224  
4.64  
.35  
Propylene C3H6  
.40  
.366  
Silane SiH4  
.5982  
.284  
.3482  
.69  
.3189  
.1270  
.1691  
.1488  
.1592  
.1543  
.127  
Silicon Tetrachloride SiCl4  
Silicon Tetrafluoride SiF4  
Sulfur Dioxide SO2  
Sulfur Hexafluoride SF6  
Sulfuryl Fluoride SO2F2  
Tetrafluoroethane (Forane 134A) CF3CH2F  
Tetrafluorohydrazine N2F4  
Trichlorofluoromethane (Freon-11) CCl3F  
Trichlorosilane SiHCl3  
.2635  
.3883  
.5096  
.3237  
.3287  
.3278  
.182  
.1357  
.1380  
6.129  
6.043  
1,1,2-Trichloro-1,2,2 Trifluoroethane  
(Freon-113) CCl2FCClF2  
Triisobutyl Aluminum (C4H9)AL  
Titanium Tetrachloride TiCl4  
Trichloro Ethylene C2HCl3  
Trimethylamine (CH3)3N  
Tungsten Hexafluoride WF6  
Uranium Hexafluoride UF6  
Vinyl Bromide CH2CHBr  
Vinyl Chloride CH2CHCl  
Xenon Xe  
.2031  
.161  
8.36  
.0608  
.2691  
.32  
.508  
8.848  
8.465  
5.95  
.120  
.163  
.2792  
.2541  
.1961  
.4616  
.48  
.3710  
.0810  
.0888  
.1241  
.12054  
.0378  
2.639  
13.28  
15.70  
4.772  
2.788  
5.858  
1.44  
27  
APPENDIX 3  
DIMENSIONAL DRAWINGS  
FMA 1500 FOR RANGES UP TO 10 L/MIN  
MASS FLOW METER  
NOTES: Omega7 reserves the right to change designs and dimensions at its  
sole discretion at any time without notice. For certified dimensions  
please contact Omega7.  
28  
FMA 1500 FOR RANGES ABOVE 10 L/MIN  
MASS FLOW CONTROLLER  
NOTES: Omega7 reserves the right to change designs and dimensions at  
its sole discretion at any time without notice. For certified dimensions  
please contact Omega7.  
29  
FMA 1400 RANGES UP TO 10 L/MIN  
MASS FLOW CONTROLLER  
NOTES: Omega7 reserves the right to change designs and dimensions at its  
sole discretion at any time without notice. For certified dimensions  
please contact Omega7.  
30  
FMA 1400 RANGES ABOVE 10 L/MIN  
MASS FLOW CONTROLLER  
NOTES: Omega7 reserves the right to change designs and dimensions at its  
sole discretion at any time without notice. For certified dimensions  
please contact Omega7.  
31  
NOTES:  
32  
NOTES:  
33  
WARRANTY/DISCLAIMER  
OMEGA ENGINEERING, INC. warrants this unit to be free of defects in materials and workmanship for a  
period of 13 months from date of purchase. OMEGA’s Warranty adds an additional one (1) month grace  
period to the normal one (1) year product warranty to cover handling and shipping time. This ensures  
that OMEGA’s customers receive maximum coverage on each product.  
If the unit malfunctions, it must be returned to the factory for evaluation. OMEGA’s Customer Service  
Department will issue an Authorized Return (AR) number immediately upon phone or written request.  
Upon examination by OMEGA, if the unit is found to be defective, it will be repaired or replaced at no  
charge. OMEGA’s WARRANTY does not apply to defects resulting from any action of the purchaser,  
including but not limited to mishandling, improper interfacing, operation outside of design limits, improp-  
er repair, or unauthorized modification. This WARRANTY is VOID if the unit shows evidence of having  
been tampered with or shows evidence of having been damaged as a result of excessive corrosion; or  
current, heat, moisture or vibration; improper specification; misapplication; misuse or other operating con-  
ditions outside of OMEGA’s control. Components which wear are not warranted, including but not limited  
to contact points, fuses, and triacs.  
OMEGA is pleased to offer suggestions on the use of its various products. However, OMEGA nei-  
ther assumes responsibility for any omissions or errors nor assumes liability for any damages  
that result from the use of its products in accordance with information provided by OMEGA, either  
verbal or written. OMEGA warrants only that the parts manufactured by it will be as specified and  
free of defects. OMEGA MAKES NO OTHER WARRANTIES OR REPRESENTATIONS OF ANY KIND  
WHATSOEVER, EXPRESS OR IMPLIED, EXCEPTTHAT OFTITLE, AND ALL IMPLIED WARRANTIES  
INCLUDING ANY WARRANTY OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PUR-  
POSE ARE HEREBY DISCLAIMED. LIMITATION OF LIABILITY:The remedies of purchaser set forth  
herein are exclusive, and the total liability of OMEGA with respect to this order, whether based on  
contract, warranty, negligence, indemnification, strict liability or otherwise, shall not exceed the  
purchase price of the component upon which liability is based. In no event shall OMEGA be liable  
for consequential, incidental or special damages.  
CONDITIONS: Equipment sold by OMEGA is not intended to be used, nor shall it be used: (1) as a  
“Basic Component” under 10 CFR 21 (NRC), used in or with any nuclear installation or activity; or (2) in  
medical applications or used on humans. Should any Product(s) be used in or with any nuclear  
installation or activity, medical application, used on humans, or misused in any way, OMEGA assumes  
no responsibility as set forth in our basic WARRANTY/ DISCLAIMER language, and, additionally,  
purchaser will indemnify OMEGA and hold OMEGA harmless from any liability or damage whatsoever  
arising out of the use of the Product(s) in such a manner.  
RETURN REQUESTS/INQUIRIES  
Direct all warranty and repair requests/inquiries to the OMEGA Customer Service Department.  
BEFORE RETURNING ANY PRODUCT(S) TO OMEGA, PURCHASER MUST OBTAIN AN  
AUTHORIZED RETURN (AR) NUMBER FROM OMEGA’S CUSTOMER SERVICE DEPARTMENT (IN  
ORDER TO AVOID PROCESSING DELAYS). The assigned AR number should then be marked on the  
outside of the return package and on any correspondence.  
The purchaser is responsible for shipping charges, freight, insurance and proper packaging to prevent  
breakage in transit.  
FOR WARRANTY RETURNS, please have the  
following information available BEFORE  
contacting OMEGA:  
FOR NON-WARRANTY REPAIRS, consult OMEGA  
for current repair charges. Have the following  
information available BEFORE contacting OMEGA:  
1. Purchase Order number under which  
the product was PURCHASED,  
1. Purchase Order number to cover the  
COST of the repair,  
2. Model and serial number of the product  
under warranty, and  
2. Model and serial number of the  
product, and  
3. Repair instructions and/or specific problems  
relative to the product.  
3. Repair instructions and/or specific  
problems relative to the product.  
OMEGA’s policy is to make running changes, not model changes, whenever an improvement is possible.  
This affords our customers the latest in technology and engineering.  
OMEGA is a registered trademark of OMEGA ENGINEERING, INC.  
© Copyright 2001 OMEGA ENGINEERING, INC. All rights reserved. This document may not be copied, photo-  
copied, reproduced, translated, or reduced to any electronic medium or machine-readable form, in whole or in part,  
without the prior written consent of OMEGA ENGINEERING, INC.  
32  
Where Do I Find Everything I Need for  
Process Measurement and Control?  
OMEGA…Of Course!  
TEMPERATURE  
5
5
5
5
5
Thermocouple, RTD & Thermistor Probes, Connectors, Panels & Assemblies  
Wire: Thermocouple, RTD & Thermistor  
Calibrators & Ice Point References  
Recorders, Controllers & Process Monitors  
Infrared Pyrometers  
PRESSURE, STRAIN AND FORCE  
5
5
5
5
Transducers & Strain Gages  
Load Cells & Pressure Gages  
Displacement Transducers  
Instrumentation & Accessories  
FLOW/LEVEL  
5
5
5
5
Rotameters, Gas Mass Flow meter & Flow Computers  
Air Velocity Indicators  
Turbine/Paddlewheel Systems  
Totalizers & Batch Controllers  
pH/CONDUCTIVITY  
5
5
5
5
pH Electrodes, Testers & Accessories  
Benchtop/Laboratory Meters  
Controllers, Calibrators, Simulators & Pumps  
Industrial pH & Conductivity Equipment  
DATA ACQUISITION  
5
5
5
5
5
Data Acquisition & Engineering Software  
Communications-Based Acquisition Systems  
Plug-in Cards for Apple, IBM & Compatibles  
Datalogging Systems  
Recorders, Printers & Plotters  
HEATERS  
5
5
5
5
5
Heating Cable  
Cartridge & Strip Heaters  
Immersion & Band Heaters  
Flexible Heaters  
Laboratory Heaters  
ENVIRONMENTAL  
MONITORING AND CONTROL  
5
5
5
5
5
5
Metering & Control Instrumentation  
Refractometers  
Pumps & Tubing  
Air, Soil & Water Monitors  
Industrial Water & Wastewater Treatment  
pH, Conductivity & Dissolved Oxygen Instruments  
M1686/0606  

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