TELEDYNE
HASTINGS
INSTRUMENTS
INSTRUCTION MANUAL
HFM-I-401 AND HFM-I-405
INDUSTRIAL
FLOW METERS
I S O 9 0 0 1
C E R T I F I E D
Qui
ck
Sta
rt
Inst
ruc
tion
s
Connect dry, clean gas and ensure connections are
leak free.
Connect Cable for power and analog signal output.
Check that electrical connections are correct.
(See diagrams below)
Replace front cover and cable feed-through ensuring
gasket is seated and fasteners are secure.
12
1
Terminal Strip
PINS
RS232
RS485
ETHERNET
SHIELD
GROUND
TRANSMIT
RECEIVE
UNUSED
UNUSED
GROUND
TX+ (A)
RX+ (A)
TX- (B)
GROUND
TD+
1
2
3
4
1
2
3
RD+
Digital Connector
TD-
4
RX- (B)
RD-
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CAUTION
CAUTION
This instrument is available with multiple pin-outs.
Ensure electrical connections are correct.
The 400-I series flow meters are designed for IEC
Installation/Over voltage Category II – single phase receptacle
connected loads.
The Hastings 400 Series flow meters are designed for
INDOOR and OUTDOOR operation.
NOTE
CAUTION
In order to maintain the integrity of the Electrostatic Discharge
immunity both parts of the remote mounted version of the HFM-
I-400 instrument must be screwed to a well grounded structure.
In order to maintain the environmental integrity of the enclosure
the power/signal cable jacket must have a diameter of 0.12 -
0.35” (3 – 9 mm) for the cable gland or 0.25 - 0.275” (6.5 – 7
mm) for the circular connector. The nut on the cable gland must
be tightened down sufficiently to secure the cable. This cable
must be rated for at least 85°C.
CAUTION
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Table of Contents
GENERAL INFORMATION.....................................................................................................................................1
1. GENERAL INFORMATION ....................................................................................................................................1
1.1. OVERVIEW......................................................................................................................................................1
1.1.1.
1.1.2.
1.1.3.
1.1.4.
400 Series Family ..................................................................................................................................1
400 Series Meters ..................................................................................................................................1
Measurement Approach.........................................................................................................................1
Additional Functions..............................................................................................................................1
1.2.
SPECIFICATIONS .............................................................................................................................................2
INSTALLATION.........................................................................................................................................................4
2. INSTALLATION....................................................................................................................................................4
2.1.
2.2.
2.3.
2.4.
2.5.
RECEIVING INSPECTION..................................................................................................................................4
ENVIRONMENTAL AND GAS REQUIREMENTS..................................................................................................4
MECHANICAL CONNECTIONS .........................................................................................................................4
MOUNTING THE ELECTRONICS REMOTELY.....................................................................................................5
ELECTRICAL CONNECTION .............................................................................................................................5
2.5.1.
2.5.2.
2.5.2.1.
2.5.2.2.
Power Supply.........................................................................................................................................6
Analog Output........................................................................................................................................6
Current Loop Output .........................................................................................................................6
Voltage output....................................................................................................................................9
2.6.
2.7.
DIGITAL CONNECTION....................................................................................................................................9
DIGITAL CONFIGURATION ..............................................................................................................................9
2.7.1.
2.7.2.
2.7.3.
RS-232 ...................................................................................................................................................9
RS-485 .................................................................................................................................................10
Ethernet ...............................................................................................................................................10
2.8.
2.9.
2.10.
2.11.
2.12.
ALARM OUTPUT CONNECTION .....................................................................................................................10
AUXILIARY INPUT CONNECTION ..................................................................................................................11
ROTARY GAS SELECTOR...........................................................................................................................12
ELECTRICAL REMOTE ZERO CONNECTION ...............................................................................................13
CHECK INSTALLATION PRIOR TO OPERATION...........................................................................................13
OPERATION.............................................................................................................................................................15
3. OPERATION ......................................................................................................................................................15
3.1.
3.2.
3.3.
ENVIRONMENTAL AND GAS CONDITIONS.....................................................................................................15
INTERPRETING THE ANALOG OUTPUT ..........................................................................................................15
DIGITAL COMMUNICATIONS.........................................................................................................................15
3.3.1.
3.3.2.
3.4.
3.4.1.
3.4.2.
Digitally Reported Flow Output ..........................................................................................................16
Digitally Reported Analog Input..........................................................................................................16
ZEROING THE INSTRUMENT ..........................................................................................................................16
Preparing for a Zero Check.................................................................................................................16
Adjusting Zero .....................................................................................................................................17
3.5. OVER-RANGE................................................................................................................................................17
3.6.
3.7.
REVERSE FLOW ............................................................................................................................................18
HIGH PRESSURE OPERATION ........................................................................................................................18
3.7.1.
3.7.2.
3.8.
3.9.
3.10.
3.11.
Zero Shift .............................................................................................................................................19
Span Shift.............................................................................................................................................19
WARNINGS/ALARMS ....................................................................................................................................19
MULTI-GAS CALIBRATIONS ..........................................................................................................................19
FLOW TOTALIZATION ...............................................................................................................................20
ADDITIONAL DIGITAL CAPABILITIES........................................................................................................20
PARTS AND ACCESSORIES .................................................................................................................................21
4. PARTS & ACCESSORIES.....................................................................................................................................21
4.1.
POWER POD – POWER & DISPLAY UNITS ......................................................................................................21
4.2. FITTINGS.......................................................................................................................................................22
4.3. CABLES ........................................................................................................................................................22
WARRANTY .............................................................................................................................................................23
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5. WARRANTY......................................................................................................................................................23
5.1.
5.2.
WARRANTY REPAIR POLICY.........................................................................................................................23
NON-WARRANTY REPAIR POLICY................................................................................................................23
APPENDICES............................................................................................................................................................24
6. APPENDICES .....................................................................................................................................................24
6.1.
6.2.
APPENDIX 1- VOLUMETRIC VERSUS MASS FLOW .........................................................................................24
APPENDIX 2 - GAS CONVERSION FACTORS...................................................................................................25
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1. General Information
1. General Information
1.1. Overview
1.1.1. 400 Series Family
The Hastings 400 Series is a family of flow instruments which is specifically designed to meet the needs
of the industrial gas flow market. The “I” family in the 400 Series features an IP-65 enclosure which
allows the use of the instrument in a wide variety of environments. The 400 I products consist of four
configurations: a flow meter, HFM-I-401, which has a nominal nitrogen full scale between 10 SLM and
300 SLM and a corresponding flow controller, the HFC-I-403; a larger flow meter, HFM-I-405, which
ranges from 100 SLM to 2500 SLM, and a corresponding flow controller, the HFC-I-407. These
instruments are configured in a convenient in-line flow-through design with standard fittings. Each
instrument in the series can be driven by either a +24 VDC power supply or a bipolar ±15 volt supply.
The electrical connection can be made via either a terminal strip located inside the enclosure or
optionally through an IP-65 compatible electrical connector. Also, these instruments include both
analog and digital communications capabilities.
1.1.2. 400 Series Meters
The Hastings HFM-I-401 and HFM-I-405 thermal mass flow meters are designed to provide very
accurate measurements over a wide range of flow rates and environmental conditions. The design is
such that no damage will occur from moderate overpressure or overflows and no maintenance is
required under normal operating conditions when using clean gases.
1.1.3. Measurement Approach
The instrument is based on mass flow sensing. This is accomplished by combining a high-speed thermal
transfer sensor with a parallel laminar flow shunt (see Figure 1-1). The flow through the meter is split
between the sensor and shunt in a constant ratio set by the full scale range. The thermal sensor consists
of a stainless steel tube with a heater at its center and two thermocouples symmetrically located
upstream and downstream of the heater. The ends of the sensor tube pass through an aluminum block
and into the stainless steel sensor base. With no flow in the tube the thermocouples report the same
elevated temperature; however a forward flow cools the upstream thermocouple relative to the
downstream. This temperature difference generates a voltage signal in the sensor which is digitized and
transferred to the main processor in the electronics enclosure. The processor uses this real-time
information and the sensor/shunt characteristics stored in non-volatile memory to calculate and report
the flow.
To ensure an inherently linear response to flow, both the thermal sensor and the shunt have been
engineered to overcome problems common to other flow meter designs. For example, nonlinearities and
performance variations often arise in typical flow meters due to pressure-related effects at the entrance
and exit areas of the laminar flow shunt. Hastings has designed the 400 Series meters such that the flow-
critical splitting occurs at locations safely downstream from the entrance effects and well upstream from
the exit effects. This vastly improves the stability of the flow ratio between the sensor and shunt. The
result of this design feature is a better measurement when the specific gravity of the flowing medium
varies, for instance due to changes in pressure or gas type. Also, a common problem in typical flow
meters is a slow response to flow changes. To improve response time, some flow meter designs
introduce impurities such as silica gel. Alternatively, Hastings has designed the 400 Series sensor with
reduced thermal mass to improve the response time without exposing additional materials to the gas
stream.
1.1.4. Additional Functions
These instruments contain a number of functions in addition to reporting flow which include:
•
Settable alarms and warnings with semiconductor switch outputs
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•
•
•
•
•
A digitally reported status of alarms and warnings such as overflow/underflow
A flow totalizer to track the amount of gas added to a system
A digitizing channel for an auxiliary analog signal
An internal curve fitting routine for “fine tuning” the base calibration
An alternate calibration set of 8 different ranges/gases
1.2.Specifications
WARNING
Do not operate this instrument in excess of the specifications
listed below. Failure to heed this warning can result in serious
personal injury and/or damage to the equipment.
HFM-I-401
HFM-I-405
Performance
Full Scale Flow Ranges
(in N2)
0-10 slm up to 0-350 slm
0-100 slm up to 0-2500 slm
Standard: ± 1% full scale
Optional: ± (0.5% reading + 0.2%FS)
± 0.1% of F.S.
Accuracy1
Standard: ± 1% full scale
Optional: ± (0.5% reading + 0.2%FS)
± 0.1% of F.S.
Repeatability
Operating Temperature
Warm up time
-20 to 70°C
-20 to 70°C
30 min for optimum accuracy
2 min for ± 2% of full scale
30 min for optimum accuracy
2 min for ± 2% of full scale
Settling Time/Reponse
Time
Temperature Coefficient
of Zero
< 2.5 seconds (to within ± 2% of full scale)
< ±0.05% of Full Scale /°C
< 2.5 seconds (to within ± 2% of full scale)
< ±0.05% of Full Scale /°C
Temperature Coefficient
of Span
< ±0.16% of reading/°C
< ±0.16% of reading/°C
Operating Pressure -
Maximium
Standard: 500 psig
Standard: 500 psig
Optional: 1500 psig
Optional: 1000 psig
Pressure Coefficient of
Span
Pressure Drop(N2@14.7
psia)
Attitude Sensitivity of
Zero
< 0.01%of reading /psi
< 1.1 psi at full scale flow
< 2% of F.S.
(N2, 0-1000 psig)
< 0.01%of reading /psi
< 5.1 psi at full scale flow
< 2% of F.S.
(N2, 0-1000 psig)
Electrical
18-38 VDC, 3.5 watts(Ethernet) 2.5
watts(RS232/485)
18-38 VDC, 3.5 watts(Ethernet) 2.5
watts(RS232/485)
Power Requirements
Analog Output
Standard: 4 – 20 mA
Standard: 4 – 20 mA
Optional: 0-10 VDC, 0-20 mA, 0-5 VDC, 1-5 VDC Optional: 0-10 VDC, 0-20 mA, 0-5 VDC, 1-5 VDC
Digital Output
Standard: RS 232
Standard: RS 232
Optional: RS 485
Optional: RS 485
Optional: Ethernet
Optional: Ethernet
Analog Connector
Digital Connector
Std: Terminal Block – M16 Cable Gland
Optional: 12 pin Circular Connector
4 pin, D-coded M12
Std: Terminal Block – M16 Cable Gland
Optional: 12 pin Circular Connector
4 pin, D-coded M12
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Mechanical
Fittings
Standard: 1/2" Swagelok
Standard: 1" Swagelok
Optional: ½" VCO®, ½" VCR®, ¾” Swagelok,
Optional: 1" VCO®,1" VCR®, ¾” Swagelok, ,
10mm Swagelok, 3/8" male NPT, ½” male NPT
1" male NPT, ¾” male NPT, 1 5/16"-12 straight
12mm Swagelok, ¾"-16 SAE/MS straight thread
< 1x10-8 sccs He
thread
< 1x10-8 sccs He
Leak Integrity
Wetted Materials
Weight (approx.)
316L SS, Nickel 200, 302 SS, Viton®
12 lb (5.5 kg)
316L SS, Nickel 200, 302 SS, Viton®
18 lb (8 kg)
Viton® is a trademark of DuPont Dow Elastomers, LLC.
Swagelok®, VCO®and VCR® are trademarks of the Swagelok Company.
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2. Installation
2. Installation
CAUTION
Many of the functions described in this section require removing
the enclosure front plate. Care must be taken when reinstalling
this plate to ensure that the sealing gasket is properly positioned
and the fasteners are secure to maintain an IP65 compliant seal.
2.1.Receiving Inspection
Your instrument has been manufactured, calibrated, and carefully packed so it is ready for operation.
However, please inspect all items for any obvious signs of damage due to shipment. Immediately advise
Teledyne Hastings and the carrier if any damage is suspected.
Use the packing slip as a check list to ensure all parts are present (e.g. flow meter, power supply, cables
etc.) and that the options are correctly configured (output, range, gas, connector).
If a return is necessary, obtain an RMA (Return Material Authorization) number from Teledyne
2.2.Environmental and Gas Requirements
•
•
•
•
Use the following guidelines prior to installing the flow meter:
Ensure that the temperature of all components and gas supply are between -20° and 70° C
Ensure that the gas line is free of debris and contamination
Ensure that the gas is dry and filtered (water and debris may clog the meter and/or affect its
performance)
•
If corrosive gases are used, purge ambient (moist) air from the gas lines
2.3.Mechanical Connections
The meter can be mounted in any orientation unless using dense gases or pressures higher than 250 psig
in which case a “flow horizontal” orientation is required. The meter’s measured flow direction is
indicated by the arrow on the electronics enclosure.
A straight run of tubing upstream or downstream is not necessary for proper operation of the meter. The
flow meter incorporates elements that pre-condition the flow profile before the measurement region. So
for example, an elbow may be installed upstream from the flow meter entrance port without affecting
the flow performance.
Compression fittings should be connected and secured according to recommended procedures for that
fitting. Two wrenches should be used when tightening fittings (as shown in the Quick Start Guide on
page iii) to avoid subjecting the flow meter body to undue torque and related stress.
The fittings are not intended to support the weight of the meter. For mechanical structural support,
four mounting holes (#1/4-20 thread, 3/8” depth) are located in the bottom of the meter. The position
of these holes is documented on the outline drawing in Appendix 3 (Section 6.3).
Leak-check all fittings according to an established procedure appropriate for the facility.
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2.4.Mounting the Electronics Remotely
In order to maintain the integrity of the Electrostatic Discharge
CAUTION
immunity both parts of the remote mounted version of the HFM-
I-400 instrument must be screwed to a well grounded structure.
The ferrite that is shipped with the instrument must be installed
on the cable next to the electronics enclosure.
The electronics enclosure can be separated
and relocated up to 30 feet away from the
flow meter base. This requires a cable which
is supplied with the instrument if ordered as
a cable mounted unit. Alternatively, a 2, 5,
or 10 meter cable can be purchased
separately. See section 4.2 for ordering
information and part numbers.
When remote mounting the electronics
enclosure, the support bracket can remain
attached to either the flow meter base or the
electronics. To separate the electronics
enclosure from the support bracket, remove
the two screws located on the back of the
support bracket. To separate the flow meter
base from the support bracket, remove the
four screws that mount the bracket to the top
of the flow meter base. Unscrew the
Figure 2-1 Accessing the terminal strip
electrical connector between electronics enclosure and the flow meter base. Remove the electronics
enclosure from the flow meter base. Connect the female end
of the remote electronics cable to the flow meter base and
Terminal Strip Pin-out
the male end to the electronics enclosure. The electronics
(Pins numbered right to left as
viewed from the front)
enclosure can be mounted remotely by using the two
threaded holes in the enclosure. The size and spacing of
these two holes are specified on the outline drawing in
Appendix 3 (Section 6.3). These holes may be used by
inserting fasteners from behind through a new mounting
bracket or they may be accessed from the front side by
temporarily removing the enclosure panel. This enables
mounting the enclosure to a wall or other solid structure.
Alternatively, if the instrument was originally configured as
a bracket mounted unit the bracket may be directly
mounted to a support structure. The bracket mounting
holes locations are the same as those for the flow meter base
mounting. (See the outline drawing in Appendix 3, Section
6.3.)
1
2
3
4
5
6
7
8
9
- Power Supply
+ Power Supply
- Flow Output
+ Flow Output
+ Auxiliary Input
- Auxiliary Input
No Connection
Digital Common
Remote Zero
2.5.Electrical Connection
10 Alarm 1
There are two electrical connectors on the Hastings 400-I
Series flow meters—an analog terminal strip (located
within the electronics enclosure) and a digital connector.
The analog connector provides for the power supply to
the meter along with analog signals and functions. As
such, its use is required for operation. The digital
11 Alarm 2
12 Alarm Common
Figure 2-2 Electrical
connections for analog
inputs/outputs and power
connector is used for communications in either of RS232,
RS485, or Ethernet mode depending on the instrument’s
configuration. The digital connector does not have to be used if the meter is operated as an analog-
only instrument.
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There are two possible connection methods to the analog terminal
strip. The standard method is by inserting a cable through the
supplied cable gland with an external jacket that meets the
specifications of the following caution note and tightening down the
cable gland nut securely to seal against the cable jacket.
There is also an optional sealed circular connector that may be ordered
with the instrument. If this connector is ordered the internal terminal
board will be connected to pins on the circular connector. This option
will be supplied with the mating connector (if a power cable was not
ordered with the instrument). This mating connector has pins that must
be soldered to wires (24 - 28 AWG) in a customer supplied cable that
meets the specifications in the caution note below. Other sealing collets for cable diameters other than
specified below can be ordered from Bulgin PX0482 (3 – 5 mm) or PX0483 (5 – 7 mm). Ensure that
the parts are installed on the cable assembly correctly before assembling. Installation and removal of the
outer housing may damage the latches and prevent the connector from making a leak-free seal.
In order to maintain the environmental integrity of the enclosure
the power/signal cable jacket must have a diameter of 0.12 -
0.35” (3 – 9 mm) for the cable gland or 0.25 - 0.275” (6.5 – 7
CAUTION
mm) for the circular connector. The nut on the cable gland must
be tightened down sufficiently to secure the cable. This cable
must be rated for at least 85°C.
2.5.1. Power Supply
Ensure that the power source meets the requirements detailed in the specifications section. Hastings
offers several power supply and readout products that meet these standards and are CE marked. If
multiple flow meters or other devices are sharing the same power supply, it must have sufficient
capability to provide the combined maximum current.
Power is delivered to the instrument through pins 1 and 2 of the analog terminal strip located within the
electronics enclosure (see Figure 2-1). As shown in the pin-out diagram Figure 2-2, the positive polarity
of the power supply is connected to pin 2 and the negative is connected to pin 1. (For a unipolar power
supply, pin 1 is power common and pin 2 is +24V. For a bipolar ±15V power supply, pin 1 is -15V and
pin 2 is + 15V.) To allow for inadvertent reversal of the power polarity, an internal diode bridge will
ensure that the proper polarity is applied to the internal circuitry. A green LED located next to the
terminal strip will illuminate when the meter is properly powered. The power supply inputs are
galvanically isolated from all other analog and digital circuitry.
2.5.2. Analog Output
The indicated flow output signal is found on pins 3 and 4 of the terminal strip as shown in Figure 2-2.
The negative output pin 3 is galvanically isolated from chasis ground and from the power supply input
common. The 400 Series meters can be configured to provide one of many available current and voltage
outputs; the standard 4 -20 mA or the optional 0 -20 mA, 0-5 Vdc, 1-5 Vdc, or 0-10 Vdc.
When the meter is configured with milliamp output it
cannot generate a signal that is below the zero current
value; therefore the 0-20 mA unit is limited in its ability
NOTE
to indicate a negative flow with the analog signal.
2.1.1.1. Current Loop Output
The standard instrument output is a 4 - 20 mA signal proportional to the measured flow (i.e. 4 mA =
zero flow and 20 mA = 100% FS). An optional current output of 0 – 20 mA (where 0 mA = zero flow
and 20 mA = 100% FS) may be selected at the time of ordering.
If either current loop output has been selected, the flow meter acts as a passive transmitter. It neither
sources nor sinks the current signal. The polarity of the loop must be such that pin 4 is at a higher
potential than pin 3 on the flow meter terminal strip. Loop power must be supplied with a potential in
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the range of 5-28 Vdc from a source external to the flow meter. The loop supply can be the same supply
as that for the instrument power or it can be an isolated loop supply.
Figure 2-3 shows a typical setup using the same supply. This method requires a jumper from pin 2 to
pin 4 on the terminal strip while connecting pin 3 to a wire that carries this signal to the indicator (for
example, a process ammeter, data acquisition system, or PLC board). To complete the current loop,
another wire carries the return signal from the flow indicator back to the negative end of the input
supply.(Alternatively, the loop current can be measured on the “high potential side” by connecting the
indicator between the pins 2 and 4 while connecting pin 3 to pin 1.)
Figure 2-4 shows an arrangement using a separate loop supply which is isolated from the instrument
power supply.
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Figure 2-3 Wiring diagram showing the current loop supply powered by the instrument supply
Figure 2-4 Wiring diagram showing the current loop powered by an external supply
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2.1.1.2. Voltage output
If the flow meter is configured for a voltage output, the signal will be available as a positive potential on
pin 4 relative to pin 3 of the terminal strip. Since these pins are galvanically isolated, the signal cannot
be read by an indicator between pin 4 and pin 1 of the terminal strip. Pin 3 must be used as the return
to properly read the output on pin 4. If an output that is referenced to power supply common is desired
then pins 3 and 1 must be connected. It is recommended that these signals be transmitted through
shielded cable, especially for installations where long cable runs are required or if the cable is located
near equipment that emits RF energy or uses large currents.
Note: When the meter is configured with a voltage output it cannot generate a signal that is more than a
few mV below the zero volt value; therefore the 0-5 volt and 0-10 volt units are limited in their ability to
indicate a negative flow with the analog signal.
2.6.Digital Connection
The digital signals are available on a sealed female D-coded M12 connector that is designed for use on
industrial Ethernet connections. There are many options for connecting to the M12. Hastings offers an
8 foot cable (stock# CB-RS232-M12) with a compatible male M12 connector to a 9-pin D connector
suitable for connecting the 400 I series instrument directly to the RS232 port on a PC. A cable to
convert USB to RS232 9-pin is available from Hastings (stock# CB-USB-RS232). Also, a 5 meter M12
male–male cable suitable for digital communications can be purchased from Hastings (stock# CB-
ETHERNET-M12). Other length cables are available from Lumberg (#0985 342 100/5 M) or Phoenix.
Converters from the M12 connector to a standard modular Ethernet connector are available from
Hastings or from Lumberg (#0981 ENC 100). A compatible M12 connector suitable for field wiring
can be acquired from Harting (21 03 281 1405) or Mouser (617-21-03-281-1405).
The pin-out for the digital connector is shown in Figure 2-5.
PINS
RS232
RS485
ETHERNET
SHIELD
GROUND
TRANSMIT
RECEIVE
UNUSED
UNUSED
GROUND
TX+ (A)
RX+ (A)
TX- (B)
GROUND
TD+
1
2
3
4
1
4
2
3
RD+
TD-
RX- (B)
RD-
Figure 2-5 Digital connector pin-out
2.7.Digital Configuration
Jumper
Enabled
RS485
Disabled
RS232
A Hastings 400-I Series flow meter is available with one
of three digital communications interfaces, RS232,
RS485, or Ethernet. Unless specified differently at the
time of ordering, the flow meter is configured for RS232
operation. For each interface, there are changes that can
be made to the configuration, either via software or
hardware settings. A brief overview of these is included
here. For more detailed information, consult the
Hastings 400 Series Software Manual.
1
2
3
4
5
6
Half Duplex
Full Duplex
TX Terminated Unterminated
RX Terminated Unterminated
9600 Baud
Addr = 99
Software Selected
Software Selected
2.7.1. RS-232
The default configuration for the RS-232 interface is
19200 baud, 8 data bits, no–parity, one stop bit. The
baud rate is software selectable and can be overridden
Figure 2-6 Functions for digital jumper field
by a hardware setting. Hardware settings for RS-232 and RS-485 are enacted on 12 pin jumper field
located on the left end of the top circuit board in the electronics enclosure. Only the state of jumpers 1,
2, and 5 affect the RS-232 operation. These jumpers are installed vertically over two pins when enabled
and are numbered from left to right. Jumper 1 must be disabled for RS-232; jumper 2 is used to select
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half or full duplex; and jumper 5 is enabled when a hardware override of the baud rate (forcing it to
9600) is desired. These functions are summarized in Figure 2-6.
2.7.2. RS-485
If RS485 is specified on the order, the flow meter is
set to the default values: address 61, unterminated Tx
and Rx lines. While the default address is 61, all
instruments will respond to an address of FF.
Hardware settings for RS-232 and RS-485 are
enacted on 12 pin jumper field located on the left end
of the top circuit board in the electronics enclosure.
Only the state of jumpers 1, 3, 4, and 6 affect the RS-
485 operation (see Figure 2-6). These jumpers are
installed vertically over two pins when enabled and
are numbered from left to right. Jumper 1 must be
enabled for RS-485. Enabling jumpers 3 and 4 effect
a 120 ohm resistance across the transmit and receive
signal pairs respectively. These should only be
enabled in the last instrument on a long buss.
Enabling jumper 6 forces the address to 99; this is
Figure 2-7 Web browser screen
sometimes used when initiating communications.
2.7.3. Ethernet
If Ethernet is specified on the order, the flow meter has IP
address 172.16.52.250 and communication port number
10001. There are no hardware settings required or available
to modify the configuration. This IP address can be changed
using a web browser to access the configuration of the
instrument by typing the IP address into the URL section of
the browser. Press OK to ignore the username/password
screen as shown in Figure 2-7. Select the new IP address
under the network section of the web page configuration
utility. If this address cannot be reached, the instrument can
be reconfigured by downloading and installing the Lantronix
Device Installer routine from:
tools/device-installer.html.
A standard web browser cannot be used to send and receive
messages (such as flow readings) from the main processor of
the flow meter. An Ethernet capable software program is
required to communicate with the meter’s processor.
Suitable examples of such programs are “Hyperterminal”
(typically installed as standard on PCs and shown in Figure
2-8) or custom Ethernet capable software such as LabView®.
For more information see the Software Manual.
Figure 2-8 Example Hyperterminal window
2.8.Alarm Output Connection
The Hastings 400 Series flow meters include two software settable hardware alarms. Each is an open-
collector transistor functioning as a semiconductor switch designed to conduct DC current when
activated. (See Figure 2-9.) These sink sufficient current to illuminate an external LED or to activate a
remote relay and can tolerate up to 70Vdc across the transistor. The alarm lines and the alarm common
are galvanically isolated from all other circuit components. The connections for Alarm 1, Alarm 2 and
Alarm Common are available as pins 10, 11, and 12 respectively on the analog terminal strip (see Quick
Start Guide on page iii).
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Since the alarms act as switches they do not produce
a voltage or current signal. However, they can be
used to generate a voltage signal on an Alarm Out
line. This is done by connecting a suitable pull-up
resistor between an external voltage supply and the
desired alarm line while connecting Alarm Common
to the common of the power supply. When activated,
the alarm line voltage will be pulled toward the alarm
common line generating a sudden drop in the signal
line voltage.
Alarm 1
Alarm 2
Alarm Common
To use the alarm to illuminate an LED connect the
positive terminal of the LED to a suitable power
supply and connect the other end to a current
limiting resistor. This resistor should be sized such
that the current is less than 20 mA when the entire
supply voltage is applied. Connect the other end of
the resistor to Alarm 1 or Alarm 2. Connect Alarm
Figure 2-9 Alarm circuit diagram
Common to the circuit common of the power supply. When activated, the alarm line is pulled toward
the alarm common generating sufficient current through the LED to cause it to illuminate.
Figure 2-10 shows an example of the LED circuit arrangement applied to Alarm 1 while Alarm 2 is
configured with a suitable pull-up resistor to provide a voltage output on an Alarm Out line.
Since the Alarm Common is a
shared contact, if both alarms
are being used independently
they must each be wired such
that the current passes
Alarm 1
through the external signaling
device before reaching the
alarm line.
V +
The alarm settings and
activation status are available
via software commands and
queries. The software
Alarm Out
V -
Alarm 2
interprets an activated Alarm
1 as an “Alarm” condition,
while an activated Alarm2 is
interpreted as a “Warning”
condition. The software
manual includes the detailed
descriptions for configuring
and interpreting the activation
of these alarms.
Alarm Common
Figure 2-10 Alarm circuit diagram for LED operation
2.9.Auxiliary Input
Connection
The Hastings 400 Series flow meters provide an auxiliary analog input function. The flow meter can
read the analog value present between pins 5 and 6 on the terminal strip (as shown in Figure 2-2) and
make its value available via the digital interface. The accepted electrical input signal is the same as that
configured for the analog output signal (4 – 20 mA, 0 -20 mA, 0-5 Vdc, 1-5 Vdc, or 0-10 Vdc). Unlike
the analog output signal, which is isolated and capable operating at common mode offsets of over
1000V, the analog input signal cannot be galvanically isolated from ground potential.
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2.2. Rotary Gas Selector
Record# Gas
The Hastings 400 Series flow meters can have up to eight different calibrations
stored internally. These are referred to as gas records. These records are used
to select different gases, but they can also be useful in other ways; for instance
reporting the flow in an alternate range, flow unit or reference temperature.
The records are referred to by their number label from #0 – #7.
0
1
2
3
4
5
6
7
Nitrogen
Air
Helium
Hydrogen
Argon
Oxygen
Custom
Custom
The first six records will, by default, be setup for most common six gases as
shown in Figure 2-11. If a gas other than one of these six is specified on the
customer order it will be placed in record #6. If a second different gas is
selected, it will be placed in record #7. If multiple different gases or ranges are
specified they will replace some of the standard six gases.
Figure 2-11 Gas record table
The purchased calibration certificate is provided for the gas (or
gases) specified by the customer when ordering. This gas will be
indicated with an “X” on the Gas Label (diagram below) that is
located on the top of the 400 Series Mass flow meter’s electronics
enclosure. The remaining gas records will have a different full scale
value and an unverified calibration. The full scale range
Full Scale
Range
100 slm
100.15 slm
140 slm
100.38 slm
140.37 slm
97.95 slm
Not included if
not specified
Not included if
not specified
can be calculated by using the Gas conversion factor or
GCF. A comprehensive list is found in Appendix 2 in
this manual.
Record#
Gas
Nitrogen
Air
Helium
Hydrogen
Argon
0
1
2
3
4
5
X= cal report
generated
(others use GCF)
0 N2
1 Air
2 He
3 H2
4 Ar
5 O2
6
X
Oxygen
7
6
7
Custom
Custom
S/N
Example 1
To convert the calibration of a full scale range of 100 slm of Nitrogen to the other full scale ranges:
GCF2
FS2 = FS1
GCF
1
1. Calculate full scale value of Helium
Calibrated gas = Nitrogen (GCF1 = 1.000)
Full scale range (FS1) = 100 slm
Secondary gas (FS2) = Helium (GCF2 = 1.40)
1.40/1 = 1.40, 1.40 x 100 = 140 slm of Helium
2. Calculate full scale value of Hydrogen
Calibrated gas = Nitrogen (GCF1 = 1.000)
Full scale range (FS1) = 100 slm
Secondary gas (FS2) = Hydrogen (GCF2 = 1.0038)
1.0038/1 = 1.0038, 1.0038 x 100 = 100.38 slm of Hydrogen
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Example 2- Changing the active gas record
Selecting the active gas record is accomplished in one of two ways:
1. Hardware setting
2. Software setting
Hardware:
The hardware setting is selected by accessing a rotary encoder on the upper PC board in the electronics
enclosure. When set to a number position from 0 to 7 it activates the corresponding gas record. If a
number greater than 7 is selected, then gas record control is passed to software.
Software:
See Section 3.9 Multi-Gas Calibrations and the software manual for more information about the
software control capabilities.
The software setting will override the hardware settings. If gas records are changed through the
software setting and the rotary encoder is not changed, the software setting will be active. However,
when the meter is powered down and subsequently powered up, the active setting will be based on the
rotary encoder setting.
2.10.
Electrical Remote Zero Connection
The Hastings 400 Series allows the flow meter zeroing operation to be activated remotely using pins 8
and 9 of the analog terminal strip. (See Drawing in Quick Start Guide.) If these pins are connected
together, the meter initiates an internal routine that measures the current reading, stores it in
nonvolatile memory as a zero offset, and removes this value from all subsequent readings. When the pin
9 is electrically isolated the flow meter operates normally. The typical implementation of this type of
remote zeroing operation involves connecting a remote switch or relay to pins 8 and 9 of the terminal
strip. (For more about the zeroing operation, see Section 3.4)
2.11.
Check Installation Prior to Operation
Before applying gas to the meter it is advisable to ensure that the mechanical and electrical connections
and digital communications (if applicable) are established and operating properly. This can be done by
following the guideline procedure below:
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3. Operation
3. Operation
The Hastings 400 Series flow meters are designed for operation with clean dry gas and in specified
environmental conditions (See Section 1.2). The properly installed meter measures and reports the
mass flow as an analog signal and, depending on the configuration and set up, as a digital response.
Other features can assist in the measurement operation and provide additional functions. The following
sections serves as a guide for correctly interpreting the analog and digital flow output, optimizing the
performance, and using the additional features of the instrument.
3.1.Environmental and Gas Conditions
For proper operation, the ambient and gas temperatures must be such that the flow meter remains
between -20 and 70°C. Optimal performance is achieved when the environment and gas temperatures
are equilibrated and stable. The 400 I series is intended for use with clean, non-condensing gases only.
Particles, contamination, condensate, or any other liquids which enter the flow meter body may
obstruct critical flow paths in the sensor or shunt, thus causing erroneous readings.
3.2.Interpreting the Analog Output
The analog output signal is proportional to mass flow rate. Each instrument is configured to provide
one of the available forms of analog output as described in Section 2.2. The signal read by an indicator
(for example, a process ammeter, data acquisition system, or PLC board) can be mapped to the
measured flow rate by applying the proper conversion equation selected from the table below.
Table 3-1 The Signal → Flow mapping equations
Analog Output Configuration
4 -20 mA
Mapping Equation
Flow = FS flow * (Iout – 4)/ 16
Flow = FS flow * Iout / 20
Flow = FS flow * Vout / 5
Flow = FS flow * Vout / 10
Flow = FS flow * (Vout -1)/ 4
0 -20 mA
0 – 5 Vdc
0 – 10 Vdc
1 – 5 Vdc
Alternatively an analog display meter can indicate the flow rate directly in the desired flow units by
setting the offset and scaling factors properly.
The flow meter is typically able to measure and report flow which slightly exceeds the full scale value.
Reverse or “negative” flows are indicated (to values up to 25% of full scale) by meters with 4-20 mA or
1-5 volt output. However, meters with 0-5 Volt, 0-10 volt or 0-20 mA output are limited in their ability
to indicate a negative flow with the analog signal since negative currents or voltages cannot be generated
by the meter’s circuitry.
3.3.Digital Communications
Many of the Hastings 400 Series flow meter’s operating parameters such as the flow measurement,
alarm settings, status, or gas type can be read or changed by digital communications. The digital
communications commands and protocols for each particular interface (RS-232, RS-485, and Ethernet)
are treated in detail in the Software Manual. However, the function and interpretation of flow output
and auxiliary input are also briefly presented here.
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3.3.1. Digitally Reported Flow Output
The flow rate can be read digitally by sending an ascii “F” command (preceded by the address for RS-
485). The instrument will respond with an ascii representation of the numerical value of the flow rate in
the units of flow specified on the nameplate label.
Example: A meter with RS-232 communications, calibrated for 500 slm FS N2
Computer transmits: {F}
HFM flow meter replies: {137.5}
This is interpreted as 137.5 slm of nitrogen equivalent flow.
In most situations, the flow meter can measure beyond its range (i.e. a flow that exceeds the full scale or
a reverse flow) and report the value via the digital output. While the meter can perform beyond its
stated range, the accuracy of these values has not been verified during the calibration process. Flows
that exceed 160% of the nominal shunt range (S46 response) should not be relied upon. See the
software manual for further information.
3.3.2. Digitally Reported Analog Input
The flow meter can read the analog value present on pins 5 & 6 of the terminal strip (See Section 2.9).
This function is typically used to read the analog output from a nearby sensor such as a pressure sensor
or vacuum gauge. This value is spanned for the same range as the analog output signal; it reads volts for
flow meter configured for 0-5, 0-10 or 1-5 volt output and milliamps for a flow meter configured for 0-
20 or 4-20 milliamp output. The value is accessed via the “S26” software query as shown below.
Example: A meter calibrated for 0-5 volt output and RS-232 communications.
Computer transmits: {S26}
HFM flow meter replies: {2.532}
This is interpreted as 2.532 volts.
3.4.Zeroing the Instrument
A proper zeroing of the flow meter is recommended after initial installation and warm-up. It is also
advisable to check the zero flow indication periodically during operation. Any uncertainty at zero flow is
an offset value which affects all subsequent flow readings. The frequency of these routine checks
depends on factors such as: the environmental conditions, the desired level of accuracy, and the desire
to measure low flow rates (relative to the meter full scale). To achieve the most precise flow readings,
the zeroing procedure is done while the meter is at the expected operating conditions including
temperature, line pressure, and gas type. This is especially true for cases where the flow meter is
operating at high pressure or with very dense gas.
3.4.1. Preparing for a Zero Check
Before checking or adjusting the meter’s zero, the following three requirements must be satisfied:
Warm-up – The instrument must be powered and in the operating environment for at least 30
minutes. Even though the meter will operate within a few minutes after power is applied, the entire
warm-up period is needed to establish a suitable zero reading.
No Flow – There must be an independent method to ensure that all flow through the instrument has
completely ceased before checking or adjusting the zero. Typically this is achieved by closing valve
downstream from the flow meter and waiting a sufficient time for any transient flow to decay. This is
especially critical for low flow units that have long piping lengths before or after the flow meter. In such
situations, it can require a significant settling time for the flow cease and enable a precise zero.
Stability – The flow meter must stabilize for at least 3 minutes at zero flow, especially following a high
flow or overflow condition. This will allow all parts of the sensor to come to thermal equilibrium
resulting in the best possible zero value.
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3.4.2. Adjusting Zero
The pre-conditions required for a zero check must also be followed when making a zero adjustment.
The zero adjustment is a digitally controlled “reset” type operation. When commanded, the meter
initiates an internal routine that performs the following sequence: measure the current flow reading,
store it in nonvolatile memory as a zero offset, and remove this value from all subsequent readings.
If the instrument is inadvertently or improperly zeroed, for
example while flow is passing through the instrument, the flow
reading is subtracted from all future flow readings. This will
NOTE
produce large flow indication errors.
This offset value can be accessed via the “S40” software query. The reported value is relative to an
internal, un-spanned sensor voltage. As an interpretation guideline, an offset that exceeds 0.15 volts
typically indicates that a faulty zero value is present.
There are three different methods to activate the zero reset function--manually, digitally, and
electrically.
Manually – With the electronics enclosure cover plate removed, a pushbutton switch on the upper
board is pressed.
CAUTION
Accessing the manual zero pushbutton requires removing the
enclosure front plate. Care must be taken when reinstalling this
plate to ensure that the sealing gasket is properly positioned and
the fasteners are secure to maintain an IP65 compliant seal.
Digitally – A “ZRO” (“*[address]ZRO” for RS485) command is received properly by the flow meter’s
main processor.
Electrically – An external contact closure generates continuity between pins 8 and 9 of the terminal
strip.
3.4.2.3.5. Over-range
The thermal mass flow sensor heats a portion of the gas in order to measure the flow rate. As the flow
increases the heated tube is cooled and the slope of the sensor output versus the flow rate decreases.
The sensor linearization function corrects for this effect while the flow rate is within the normal
operating region. If the flow exceeds the normal operating region the digital flow indication will
continue to track this increase with a reduced accuracy. The analog flow will also indicate this overflow
condition until the circuitry reaches its limits (approximately 10 -25% over-range).
As the flow continues to increase above the normal operating region the sensor will be cooled
sufficiently that the output of the sensor will reach a peak value around 2 – 4 times the full scale flow
rate. If the flow continues to increase the sensor output will begin decreasing and the digital flow will
indicate a decreasing flow rate even though the flow is actually getting increasing. At approximately 3 –
7 times the full scale flow rate the sensor output will drop within range of the normal output and even
the analog output will record an on-scale flow rate when there is a very large over range flow rate.
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Flow meter Output
250%
200%
150%
100%
50%
Analog Output
Digital Output
0%
0%
100%
200%
300%
400%
500%
600%
Flow (% Full Scale)
3.4.2.3.6. Reverse Flow
Pressure Effect
If the flow through the flow
meter reverses and flow
begins to enter the exit of the
flow meter and leave through
the entrance of the flow meter
the flow meter will measure
this flow and report it digitally
with reduced accuracy. The
analog output will also
8
7
6
5
indicate this by either
4
generating a negative output
voltage or decreases the
current output below 4 mA,
depending on whether a
voltage or current output has
been selected.
3
2
1
3.7.High Pressure
Operation
0
When operating at high
pressure, the meter’s
-1
performance can be affected
in two distinct and separate
ways—a zero shift and a span
(calibration) shift.
0
200
400
600
800
1000
Line Pressure (psig)
Figure 3-1 The pressure effect on flow calibration (for nitrogen)
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3.7.1. Zero Shift
The zero offset can occur as the result of natural convection flow through the sensor tube if the
instrument is not mounted in a level orientation with flow horizontal. This natural convection effect
causes a zero shift proportional to the system pressure. The overall effect is more pronounced for gases
with higher density. Normally the shift is within the allowable zero offset range and can be removed by
activating the zero reset at the operating pressure.
3.7.2. Span Shift
The gas properties which form the basis for the flow measurement, such as viscosity and specific heat,
exhibit a slight dependence on the gas pressure. Fortunately, this pressure dependence is predictable
and can be corrected for in cases where it has an impact on accuracy (typically only significant for
pressures in excess of 100 psig). The graph shown in Figure 3-1 shows the expected span shift as a
function of pressure for nitrogen. This behavior is similar for most diatomic gases (O2, H2, etc), whereas
this effect is insignificant for the monatomic gases (He, Ar, etc). This span shift must be considered and
accounted for as appropriate for accurate flow measurements at high pressure conditions.
3.8.Warnings/Alarms
There are two alarm contacts on the terminal strip connector within the electronics enclosure (See
Section 2.8). These function as isolated semiconductor switches sharing a single, isolated common line.
In its normal state each switch is “open”; when an alarm is activated the switch is “closed”.
The meter’s processor can be configured via the digital interface to establish the internal condition for
activating each alarm. There are many choices for internal alarms and warnings including overflow,
underflow, or various instrument error conditions. Each alarm can also be given a selectable “wait
time”—a period for which it must remain in the alarm condition before the physical alarm is activated.
See the Software Manual for detailed alarm setting and configuration information.
3.9.Multi-gas Calibrations
The Hastings 400 Series flow meters can have up to eight different calibrations stored internally. These
are referred to as gas records. These records are typically used to represent different gases, but they can
also be useful in other ways; for instance reporting the flow in an alternate range, flow unit or reference
temperature. The records are referred to by their number label from #0 – #7. The first six records are,
by default, setup for the same range in the most common six gases as shown in Figure 2-11. If a gas
other than one of these six is specified on the customer order it will be placed in record #6. If a second
different gas is selected, it will be placed in record #7. If multiple different gases or ranges are specified
they will replace some of the standard six gases. Only the gas(es) specified on the order will be verified.
The other records will use nominal gas factors to approximate the gas sensitivity until an actual
calibration is performed to correct for individual instrument variations. Selecting the active gas record
can be done in one of two ways—a hardware setting or a software setting. The hardware setting is done
by accessing a rotary encoder on the upper PC board in the electronics enclosure. When set to a
number position from 0 to 7 it activates the corresponding gas record. When set to a number greater
than 7, the gas record control is passed to software. If the software setting mode is enabled, then the
“S6” digital command can be used to set the active gas record as shown in the example below.
Example: To first determine and then change the active gas record using RS-232,
Computer transmits: {S6}
HFM flow meter replies: {0}
This indicates that gas record #0 is currently active.
Computer transmits: {S6=4}
This changes the active gas record to #4.
See the Software Manual for further information including how to setup a new gas record and how to
reconfigure an existing gas record.
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CAUTION
Accessing the rotary encoder requires removing the enclosure
front plate. Care must be taken when reinstalling this plate to
ensure that the sealing gasket is properly positioned and the
fasteners are secure to maintain an IP65 compliant seal.
The software command to change the active gas record will not
be executed unless the rotary encoder is set to a number greater
than 7. However, the software query will return the current active
gas record number even when it has been set by the hardware.
NOTE
3.10.
Flow Totalization
The Hastings 400 Series flow meters are capable of providing a value for the “total amount of gas” that
has passed through the flow meter since the last time the totalization function was reset. This value can
be used to determine for example, the amount of gas used to fill a chamber or drawn from a supply
vessel. To initialize the totalization function, reset the totalized flow value to zero using the S36 digital
command as shown in the example below. All subsequent flow readings are added over time and stored
as the totalized flow value. The totalized flow value can be read by querying the flow meter digitally as
in the example below. The totalized flow is reported in the flow units chosen for the active gas without
the time unit. For example, if the flow units are standard liters per minute, the totalized flow is reported
in standard liters; if flow units are standard cubic feet per hour, the totalized flow is reported in standard
cubic feet.
Example: For a 100 slm FS flow meter, to first reset/start the flow totalization function and then later read the
value using RS-232,
Computer transmits: {S36=0}
This resets the totalized value to zero and starts the totalization function. At some point later in time:
Computer transmits: {S36}
HFM flow meter replies: {45.7}
This is interpreted as a total gas amount of 45.7 standard liters has passed through the meter since the flow
totalizer was started.
3.11.
Additional Digital Capabilities
The Hastings 400 series flow meters have a wide selection of other functions, operating parameters, and
values that can be reported and configured via digital communications such as the calibration date, the
instrument temperature, the number of hours that gas has been flowing, etc. See the Software Manual
for detailed information on these additional digital features.
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4. Parts and Accessories
4. Parts & accessories
These are parts and accessories that are available by separate order from Teledyne Hastings Instruments.
4.1. Power Pod – Power & Display units
THPS-100 Singel Channel Power Supply
The Teledyne Hastings Instruments microprocessor based PowerPod-100 Thermal
Mass Flow Power Supply is a self-contained power supply and display for gas thermal
mass flow meters, pressure transducers or any device with a voltage output. The unit
features an automatically generated set point (0-5V or 0-10V), making it ideal for use
with thermal mass flow controllers and pressure controllers. Features include
4.5display, ±15 volt, 250mA transducer supply and an integrated +/- 15vdc @ 250ma
power supply is available providing a well regulated, short circuit and thermal overload
protected output, and CE compliance.
See the Teledyne Hastings Instruments Product Bulletin for the complete specification
on this product.
THPS-400 Four Channel Power Supply
The Teledyne Hastings Instruments Digital 4-Channel PowerPod is featured in a half-
rack profile for simple drop-in replacement of the existing Model 200 and 400 units,
or be used as a bench top unit.
The PowerPod-400 is equipped with a four line by twenty-character, vacuum
fluorescent display (VFD). The display emulates a liquid crystal display in its
command structure but the VFD gives the unit a greater viewing angle than available
with most conventional LED or LCD displays.
The PowerPod incorporates many features including an integrated totalizer with a
count-up or count-down option; user selected filtering of readings; serial or Ethernet
communications.
The unit also offers a simultaneous display of all four channels or selective blanking of
unused channels, ratio control with analog outputs for stacking multiple power
supplies, and easy to follow menu driven calibration and setup.
The digital design of the PowerPod allows the user to set both the minimum and
maximum display values corresponding to specific voltage or current inputs. One
advantage of this approach is that it negates the need to access hard to reach
transducers to re-zero them. Should the analog signal from the transducer change due
to a zero shift, the digital counts seen by the PowerPod can be changed to display zero
either manually from the front panel or via serial communication with the unit.
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4.1.Fittings
Fittings
Hastings#
HFM-I-401
1/2" Swagelok Fittings
1/2" VCO Fittings
1/2" VCR Fittings
3/4" Swagelok Fitting
10 mm Swagelok
3/8" Male NPT
1/2" Male NPT
12 mm Swagelok
3/4-16 SAE/MS Straight Female (no fitting)
41-03-086
41-03-119
41-03-090
41-03-152
41-03-153
41-03-154
41-03-155
41-03-160
N/A
HFM-I-405
1" Swagelok fitting
3/4" Swagelok
1" VCO Fitting
1" VCR fitting
1" Male NPT
3/4" Male NPT
1 5/16-12 Female SAE/MS straight thread (no fitting)
41-03-142
41-03-149
41-03-147
41-03-148
41-03-150
41-03-151
N/A
4.2.Cables
Hastings
Stock#
Description
Remote Electronics Cables
2 meter cable remote mounting cable
5 meter remote mounting cable
CB-8P-M12-2MRA
CB-8P-M12-5MRA
CB-8P-M12-10MRA
14-03-002
10 meter remote mounting cable
401 Local Bracket - mount direct to sensor
405 Local Bracket - mount direct to sensor
14-03-001
Digital Communications
9 pin RS232 to 400 series M12 connector
Digital M12 connector to M12 connector
USB to 9 pin RS232 connector
CB-RS232-M12
CB-ETHERNET-M12
CB-USB-RS232
CB-RJ45-M12
RJ45 Ethernet to M12 Ethernet connector
Analog I/O
CB-D15-Lead-8
CB-D15-Lead-25
CB-D15-Lead-100
8 foot D connector to 8 bare leads
25 foot D connector to 8 bare leads
100 foot D connector to 8 bare leads
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5. WARRANTY
5. Warranty
5.1.Warranty Repair Policy
Hastings Instruments warrants this product for a period of one year from the date of shipment to be free
from defects in material and workmanship. This warranty does not apply to defects or failures resulting
from unauthorized modification, misuse or mishandling of the product. This warranty does not apply to
batteries or other expendable parts, nor to damage caused by leaking batteries or any similar occurrence.
This warranty does not apply to any instrument which has had a tamper seal removed or broken.
This warranty is in lieu of all other warranties, expressed or implied, including any implied warranty as
to fitness for a particular use. Hastings Instruments shall not be liable for any indirect or consequential
damages.
Hastings Instruments, will, at its option, repair, replace or refund the selling price of the product if
Hastings Instruments determines, in good faith, that it is defective in materials or workmanship during
the warranty period. Defective instruments should be returned to Hastings Instruments, shipment
prepaid, together with a written statement of the problem and a Return Material Authorization (RMA)
number.
Please consult the factory for your RMA number before returning any product for repair. Collect freight
will not be accepted.
5.2.Non-Warranty Repair Policy
Any product returned for a non-warranty repair must be accompanied by a purchase order, RMA form
and a written description of the problem with the instrument. If the repair cost is higher, you will be
contacted for authorization before we proceed with any repairs. If you then choose not to have the
product repaired, a minimum will be charged to cover the processing and inspection. Please consult the
factory for your RMA number before returning any product repair.
TELEDYNE HASTINGS INSTRUMENTS
804 NEWCOMBE AVENUE
HAMPTON, VIRGINIA 23669 U.S.A.
ATTENTION: REPAIR DEPARTMENT
TELEPHONE
(757) 723-6531
1-800-950-2468
FAX
E MAIL
INTERNET ADDRESS
(757) 723-3925
Repair Forms may be obtained from the “Information Request” section of the
Hastings Instruments web site.
401-405 SERIES
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6. Appendices
6. Appendices
6.1.Appendix 1- Volumetric versus Mass Flow
Mass flow measures just what it says, the mass or weight of the gas flowing through the instrument.
Mass flow (or weight per unit time) units are given in pounds per hour (lb/hour), kilograms per sec
(kg/sec) etc. When your specifications state units of flow to be in mass units, there is no reason to
reference a temperature or pressure. Mass does not change based on temperature or pressure.
However, if you need to see your results of gas flow in volumetric units, like liters per minute, cubic feet
per hour, etc. you must consider the fact that volume DOES change with temperature and pressure.
A mass flow meter measures MASS (grams) and then converts mass to volume. To do this the density
(grams/liter) of the gas must be known and this value changes with temperature and pressure.
When you heat a gas, the molecules have more energy and they move around faster, so when they
bounce off each other, they become more spread out, therefore the volume is different for the same
number of molecules.
Think about this:
The density of Air at 0° C is 1.29 g/liter
The density of Air at 25C is 1.19 g/liter
The difference is 0.1 g/liter. If you are measuring flows of 100 liters per minute, and you don’t use the
correct density factor then you will have an error of 10 g/minute!
Volume also changes with pressure. Think about a helium balloon with a volume of 1 liter. If you
could scuba dive with this balloon and the pressure on it increases. What do you think happens to the
weight of the helium? It stays the same. What would happen to the volume (1 liter)? It would shrink.
Why is the word standard included with the volume terms liters and cubic feet in mass flow
applications?
A mass flow meter measures mass …and we know we can convert to volume.
To use density we must pick one (or standard) temperature and pressure to use in our calculation.
When this calculation is done, the units are called standard liters per minute (SLM) or standard cubic
feet per minute (SCFM), etc because it is referenced to a standard temperature and pressure when the
volume is calculated.
Using the example to the left, we can see a
standard liter can be defined differently. The
first balloon contains 0.179 grams of Helium at
0 ° C and 760 Torr (density of 0.179
grams/liter). Heat up that balloon to room
temperature and the volume increases, but the
mass has not changed – but the volume is not 1
liter anymore, it is 1.08 liters.
So to define a standard liter of Helium at 25 C,
we must extract only one liter from the second
balloon and that liter weighs only 0.175 grams.
If a mass flow meter is set up for STP at 0 C and
1.08 Liter
1 Liter
760 Torr, when it measures 0.179 grams of He,
it will give you results of 1 SLM.
If a second meter is set up for STP at 25 C and
760 Torr, when it measures 0.164 grams, it will
give results of 1 SLM.
1 Liter
0° C
0..179 grams/1
liter
25 C
0.179 g/1.08
liters
25° C
0.164 grams
401-405 SERIES
6.2.Appendix 2 - Gas Conversion Factors
The gas correction factors (GCF’s) presented in this manual were obtained by one of four methods.
The following table summarizes the different methods for determining GCF’s and will help identify for
which gases the highest degree of accuracy may be achieved when applying a correction factor.
1. Empirically determined
2. Calculated from virial coefficients of other investigator’s empirical data
3. From NIST tables
4. Calculated from specific heat data at 0° C at 1 atmosphere
The most accurate method is by direct measurement. Gases that are easily handled with safety such as
inert gases, gases common in the atmosphere or gases that are otherwise innocuous can be run through
a standard flow meter and the GCF determined empirically.
Many gases that have been investigated sufficiently by other researchers, can have their molar specific
heat (C’ p) calculated. The gas correction factor is then calculated using the following ratio:
GCF = C ’apN2
C’apGasX
GCF’s calculated in this manner have been found to agree with the empirically determined GCF’s
within a few tenths of a percent.
The National Institute of Standards[LH1] and Technology (NIST) maintains tables of thermodynamic
properties of certain fluids. Using these tables, one may look up the necessary thermophysical property
and calculate the GCF with the same degree of accuracy as going directly to the referenced investigator.
Lastly, for rare, expensive gases or gases requiring special handling due to safety concerns, one may look
up specific heat properties in a variety of texts on the subject. Usually, data found in this manner applies
only in the ideal gas case. This method yields GCF’s for ideal gases but as the complexity of the gas
increases, its behavior departs from that of an ideal gas. Hence the inaccuracy of the GCF increases.
Hastings Instruments will continue to search for better estimations of the GCF’s of the difficult gases
and will regularly update the list. Most Hastings flow meters and controllers are calibrated using
nitrogen. The correction factors published by Hastings are meant to be applied to these instruments. To
apply the GCF’s, simply multiply the gas flow reading times the GCF for the process gas in use.
Example:
Calculate the actual flow of argon passing through a nitrogen-calibrated meter that reads 20 sccm,
multiply the reading times the GCF for argon.
20.000 x 1.3978 = 27.956
Conversely, to determine what reading to set a nitrogen-calibrated meter in order to get a desired flow
rate of a process gas other than nitrogen, you divide the desired rate by the GCF. For example, to get a
desired flow of 20 sccm of argon flowing through the meter, divide 20 sccm by 1.3978
20.000 / 1.3978 = 14.308
That is, you ` (adjust the gas flow) to read 14.308 sccm.
401-405 SERIES
- 25 -
Some meters, specifically the high flow meters, are calibrated in air. The flow readings must then be
corrected twice. Convert once from air to nitrogen, then from nitrogen to the gas that will be measured
with the meter. In this case, multiply the reading times the ratio of the process gas’ GCF to the GCF of
the calibration gas.
Example:
A meter calibrated in air is being used to flow propane. The reading from the meter is multiplied by the
GCF for propane and then divided by the GCF of air.
20 x (0.3499/1.0015) = 6.9875
To calculate a target setting (20 sccm) to achieve a desired flow rate of propane using a meter calibrated
to air, invert the ratio above and multiply.
20 x (1.0015/0.3499) = 57.2449
Gas Conversion Table for Nitrogen
Rec
#
Density
(g/L)
Gas
Symbol
GCF
Derived
Z
25° C / 1
atm
1
2
Acetic Acid
C2H4F2
C4H6O3
C3H6O
C2H3N
C2H2
Air
0.4155
0.2580
0.3556
0.5178
0.6255
1.0015
0.4514
0.7807
1.4047
0.7592
0.3057
0.4421
0.5431
0.8007
0.3684
0.4644
0.3943
0.2622
0.2406
0.3056
0.7526
0.6160
1.0012
0.3333
4
4
4
4
4
1
4
2
1
5
4
4
4
4
4
4
4
2
4
4
1
4
4
4
2.700
4.173
2.374
1.678
1.064
1.185
1.638
0.696
1.633
3.186
3.193
4.789
2.772
6.532
6.759
5.351
6.087
2.376
3.030
2.293
1.799
3.112
1.145
6.287
2.0301
2.3384
1.7504
1.4462
0.9792
1.0930
1.3876
0.6409
2.1243
4.0839
2.0636
3.6531
2.4109
1.0000
4.2789
4.3990
4.1546
1.6896
1.9233
1.6700
1.7511
3.0744
1.0433
3.6196
Acetic Acid, Anhydride
Acetone
3
4
Acetonitryl
5
Acetylene
6
Air
7
Allene
C3H4
NH3
8
Ammonia
9
Argon
Ar
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
Arsine
AsH3
C6H6
BCl3
Benzene
Boron Trichloride
Boron Triflouride
Bromine
BF3
Br2
Bromochlorodifluoromethane
Bromodifluoromethane
Bromotrifluormethane
Butane
CBrClF2
CHBrF2
CBrF3
C4H10
C4H10O
C4H8
CO2
Butanol
Butene
Carbon Dioxide
Carbon Disulfide
Carbon Monoxide
Carbon Tetrachloride
CS2
CO
CCl4
25
Carbonyl Sulfide
COS
0.6680
4
2.456
2.4230
26
27
28
29
30
31
32
33
34
35
36
Chlorine
Cl2
0.8451
0.4496
0.2614
0.3216
0.4192
0.2437
0.3080
0.3004
0.4924
0.6486
0.3562
4
5
4
4
4
4
4
4
4
5
4
2.898
3.779
4.601
4.108
4.879
6.314
3.210
2.293
2.127
2.513
2.293
3.9995
2.8970
2.4954
2.5119
3.5284
2.9778
2.0756
1.6672
1.7626
2.4405
1.7091
Chlorine Trifluoride
Chlorobenzene
Chlorodifluoroethane
Chloroform
ClF3
C6H5Cl
C2H3ClF2
CHCl3
C2ClF5
C3H7Cl
C4H8
Chloropentafluoroethane
Chloropropane
Cisbutene
Cyanogen
C2N2
Cyanogen Chloride
Cyclobutane
ClCN
C4H8
401-405 SERIES
- 26 -
37
38
39
40
Cyclopropane
Deuterium
C3H6
0.4562
1.0003
0.5063
0.3590
4
4
5
4
1.720
0.165
1.131
8.576
1.4440
0.3102
1.0486
5.2998
H2
2
Diborane
B2H6
Dibromodifluoromethane
CBr2F2
41
Dichlorofluoromethane
CHCl2F
0.4481
4
4.207
3.2249
42
43
44
45
46
47
48
49
Dichloromethane
Dichloropropane
Dichlorosilane
Diethyl Amine
Diethyl Ether
CH2Cl2
C3H6Cl2
H2SiCl2
C4H11N
C4H10O
C4H10S
C2H2F2
C2H7N
0.5322
0.2698
0.4716
0.2256
0.2235
0.2255
0.4492
0.3705
4
4
5
4
4
4
4
4
3.472
4.618
4.129
2.989
3.030
3.686
2.617
1.843
3.0592
2.5291
3.3176
1.9080
1.9215
2.1300
2.0457
1.4793
Diethyl Sulfide
Difluoroethylene
Dimethylamine
50
51
Dimethyl Ether
C2H6O
C2H6S
0.4088
0.3623
4
4
1.883
2.540
1.5211
1.8455
Dimethyl Sulfide
52
53
Divinyl
C4H6
C2H6
0.3248
0.4998
4
2
2.211
1.229
1.6433
1.1175
Ethane
Ethane, 1-chloro-1,1,2,2-
tetrafluoro-
54
C2HClF4
0.2684
4
5.578
2.8629
Ethane, 1-chloro-1,2,2,2-
tetrafluoro-
55
56
C2HClF4
C2H6O
0.2719
0.4046
4
4
5.578
1.883
2.8806
1.5187
Ethanol
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
Ethylacetylene
Ethyl Amine
C4H6
0.3256
0.3694
0.2001
0.4124
0.4212
0.4430
0.6062
0.3173
0.3475
0.5308
0.4790
0.3506
0.3654
0.9115
0.7912
0.3535
0.3712
0.3792
0.4422
0.4857
0.5282
0.2327
0.3889
1.4005
0.1987
4
4
4
4
4
4
1
4
4
4
4
4
4
4
4
4
4
4
4
4
4
4
4
1
4
4
4
4
4
4
4
1
4
4
4
4
4
5
4
2.211
1.843
4.339
4.454
2.637
1.964
1.147
7.679
4.045
1.801
1.719
4.045
2.540
1.553
1.227
5.615
4.942
4.270
3.597
3.534
2.862
6.986
2.783
0.164
6.950
6.597
6.637
3.522
7.605
3.440
1.310
0.082
3.307
1.490
1.105
0.818
5.228
3.309
1.393
1.6438
1.4789
2.3099
3.1724
2.0018
1.5967
1.0475
4.1196
2.5846
1.5495
1.4552
2.5976
1.8499
1.5574
1.1232
3.4473
3.2026
2.8572
2.7242
2.8794
2.4487
3.1174
2.0253
0.2304
2.9681
3.2710
3.2794
2.1062
3.0771
2.0677
1.1757
0.3895
7.6975
1.5183
1.0003
0.6845
1.0000
5.1920
1.3174
C2H7N
C8H10
C2H5Br
C2H5Cl
C2H5F
C2H4
Ethylbenzene
Ethyl Bromide
Ethyl Chloride
Ethyl Fluoride
Ethylene
Ethylene Dibromide
Ethylene Dichloride
Ethylene Oxide
Ethyleneimine
Ethylidene Dichloride
Ethyl Mercaptan
Fluorine
C2H4Br2
C2H4Cl2
C2H4O
C2H4N
C2H4Cl2
C2H6S
F2
Formaldehyde
Freon 11
CH2O
CCl3F
CCl2F2
CClF3
CF4
Freon 12
Freon 13
Freon 14
Freon 22
CHClF2
CHF3
Freon 23
Freon 114
C2Cl2F4
C4H4O
He
Furan
Helium
Heptafluoropropane
Hexamethyldisilazane
Hexamethyldisiloxane
Hexane
C3HF7
C6H19NSi2 0.1224
C6H18OSi2 0.1224
C6H14
C6F6
C6H12
N2H4
H2
0.1828
0.1733
0.1918
0.5506
1.0038
1.0028
1.0034
0.7772
1.0039
0.9996
0.8412
0.8420
Hexafluorobenzene
Hexene
Hydrazine
Hydrogen
Hydrogen Bromide
Hydrogen Chloride
Hydrogen Cyanide
Hydrogen Fluoride
Hydrogen Iodide
Hydrogen Selenide
Hydrogen Sulfide
HBr
HCl
CHN
HF
HI
H2Se
H2S
401-405 SERIES
- 27 -
96
Isobutane
C4H10
C4H10O
C4H8
0.2725
0.2391
0.2984
0.2175
0.2931
0.4333
0.5732
1.4042
0.7787
0.6167
0.3083
0.4430
0.5360
0.6358
0.6639
0.1853
0.2692
0.2844
0.2743
0.7247
0.3975
0.6514
0.5409
0.2037
0.3435
1.4043
0.9795
1.0000
0.7604
0.3395
0.5406
0.4653
0.6357
0.7121
0.2121
0.1386
0.9779
0.6454
0.7022
0.1499
0.2175
0.4155
0.1711
2
4
4
4
4
4
4
4
1
4
4
4
4
4
4
4
4
4
4
4
4
4
4
4
4
4
4
1
4
4
5
4
4
1
4
4
1
4
4
5
4
4
4
2.376
3.030
2.293
2.949
2.456
2.823
1.718
3.425
0.656
1.310
3.028
1.638
1.269
3.881
2.064
4.013
2.416
2.456
3.113
1.391
2.455
5.802
1.966
3.440
2.374
0.825
1.226
1.145
1.880
3.761
2.902
2.495
2.676
1.799
2.949
4.669
1.308
2.207
1.962
2.580
2.949
4.188
8.176
1.6912
1.9228
1.6663
1.8975
1.7335
2.1501
1.5127
1.0000
0.6105
1.1818
1.9967
1.3847
1.1449
4.3841
1.9480
2.2334
1.7065
1.7285
1.9816
1.2790
1.8491
10.2105
1.6930
2.0555
1.7377
0.6173
1.1430
1.0434
1.8624
2.4128
2.5277
1.9912
2.6013
1.7098
1.9008
2.6119
1.2483
2.0766
1.8868
1.9855
1.8975
3.0075
3.1946
97
Isobutanol
98
Isobutene
99
Isopentane
C5H12
C3H8O
C3H3NO
C2H2O
Kr
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
Isopropyl Alcohol
Isoxazole
Ketene
Krypton
Methane
CH4
Methanol
CH4O
C3H6O2
C3H4
CH5N
CH3Br
CH3Cl
C7H14
C3H9N
C3H8O
C3H8S
CH3F
C2H4O2
CH3I
Methyl Acetate
Methyl Acetylene
Methylamine
Methyl Bromide
Methyl Chloride
Methylcyclohexane
Methyl Ethyl Amine
Methyl Ethyl Ether
Methyl Ethyl Sulfide
Methyl Fluoride
Methyl Formate
Methyl Iodide
Methyl Mercaptan
Methylpentene
Methyl Vinyl Ether
Neon
CH4S
C6H12
C3H6O
Ne
Nitric Oxide
NO
Nitrogen
N2
Nitrogen Dioxide
Nitrogen Tetroxide
Nitrogen Trifluoride
Nitromethane
Nitrosyl Chloride
Nitrous Oxide
n-Pentane
NO2
N2O4
NF3
CH3NO2
NOCl
N2O
C5H12
C8H18
O2
Octane
Oxygen
Oxygen Difluoride
Ozone
F2O
O3
Pentaborane
Pentane
B5H9
C5H12
ClFO3
C4F8
Perchloryl Fluoride
Perfluorocyclobutane
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
Perfluoroethane
Perfluoropropane
Phenol
C2F6
0.2530
0.1818
0.2489
0.4812
0.7859
0.4973
0.3499
0.3061
0.2860
0.4048
0.3222
0.6197
0.2583
0.2699
0.2826
0.2996
0.3110
0.3451
4
4
4
4
5
5
1
4
4
2
4
2
2
4
2
4
2
4
5.641
7.685
3.847
4.043
1.390
3.596
1.802
2.456
2.416
1.720
3.233
2.126
6.251
6.251
4.906
4.170
4.170
3.435
2.8112
3.0998
2.2089
3.3063
1.2956
2.9936
1.4516
1.7427
1.7126
1.4223
2.1151
1.9458
3.0368
3.1065
2.6844
2.4595
2.5001
2.2693
C3F8
C6H6O
COCl2
PH3
Phosgene
Phosphine
Phosphorus Trifluoride
Propane
PF3
C3H8
Propyl Alcohol
Propyl Amine
Propylene
Pyradine
C3H8O
C3H9N
C3H6
C5H5N
CH2F2
C2HCl2F3
C2HCl2F3
C2HF5
C2H2F4
C2H2F4
C2H3F3
R32
R123
R123A
R125
R134
R134A
R143
401-405 SERIES
- 28 -
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
R143A
C2H3F3
C2H4F2
C3F8
0.3394
0.3877
0.1818
0.3047
1.4043
0.2327
0.6809
0.3896
0.6878
0.2701
0.3752
0.4368
0.5397
0.2926
0.3395
0.3271
0.2298
0.3538
0.2448
0.2053
0.3133
4
4
4
4
4
4
5
5
4
1
4
4
4
4
4
4
4
4
4
4
4
3.435
2.700
7.685
4.780
9.074
3.030
1.313
4.254
2.619
5.970
4.417
3.640
3.273
6.778
4.088
2.947
3.030
2.783
3.766
2.293
5.453
2.2533
1.9753
3.0998
2.7342
1.0000
1.9213
1.1934
2.9041
2.7013
3.0092
2.9215
2.7312
2.8922
3.4711
2.5732
1.9924
1.9210
1.9586
2.1756
1.6978
3.0712
R152A
R218
R1416
C2H3Cl2F
Rn
Radon
Sec-butanol
Silane
C4H10O
SiH4
Silicone Tetrafluoride
Sulfur Dioxide
Sulfur Hexafluoride
Sulfur Tetrafluoride
Sulfur Trifluoride
Sulfur Trioxide
Tetrachloroethylene
Tetrafluoroethylene
Tetrahydrofuran
Tert-butanol
Thiophene
SiF4
SO2
SF6
SF4
SF3
SO3
C2Cl4
C2F4
C4H8O
C4H10O
C4H4S
C7H8
Toluene
Transbutene
Trichloroethane
C4H8
C2H3Cl3
178
179
180
181
182
183
184
185
186
187
188
189
190
191
Trichloroethylene
Trichlorotrifluoroethane
Triethylamine
Trimethyl Amine
Tungsten Hexafluoride
Uranium Hexafluoride
Vinyl Bromide
Vinyl Chloride
Vinyl Flouride
Water Vapor
C2HCl4
C2Cl3F3
C6H15N
C3H9N
WF6
0.3423
0.2253
0.1619
0.2822
0.2453
0.1859
0.4768
0.4956
0.5716
0.7992
1.4042
0.2036
0.1953
0.2028
4
4
4
4
5
4
4
4
5
5
4
4
4
4
6.820
7.659
4.136
2.416
12.174
14.389
4.372
2.555
1.882
0.742
5.366
4.339
4.339
4.339
3.9903
3.2607
2.3280
1.7109
4.7379
4.4681
3.5770
2.0988
1.6528
0.6715
1.0000
2.3103
2.3108
2.3102
UF6
C2H3Br
C2H3Cl
C2H3F
H2O
Xenon
Xe
Xylene, m-
C8H10
C8H10
C8H10
Xylene, o-
Xylene, p-
401-405 SERIES
- 29 -
HFM-I-405
Flow meter
401-405 SERIES
- 30 -
HFM-I-401
Flow Meter
401-405 SERIES
- 31 -
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