Appendix A to Part 154 - Guidelines for Detonation Flame Arresters
33:2.0.1.5.23.13.179.1.1 : Appendix A
Appendix A to Part 154 - Guidelines for Detonation Flame Arresters
This appendix contains the draft ASTM standard for detonation
flame arresters. Devices meeting this standard will be accepted by
the Commandant (CG-ENG).
1. Scope
1.1 This standard provides the minimum requirements for design,
construction, performance and testing of detonation flame
arresters.
2. Intent
2.1 This standard is intended for detonation flame arresters
protecting systems containing vapors of flammable or combustible
liquids where vapor temperatures do not exceed 60 °C. For all
tests, the test media defined in 14.1.1 can be used except where
detonation flame arresters protect systems handling vapors with a
maximum experimental safe gap (MESG) below 0.9 millimeters.
Detonation flame arresters protecting such systems must be tested
with appropriate media (the same vapor or a media having a MESG no
greater than the vapor). Various gases and their respective MESG
are listed in attachment 1.
2.2 The tests in this standard are intended to qualify
detonation flame arresters for all in-line applications independent
of piping configuration provided the operating pressure is equal to
or less than the maximum operating pressure limit specified in the
manufacturer's certification and the diameter of the piping system
in which the detonation arrester is to be installed is equal to or
less than the piping diameter used in the testing.
Note:
Detonation flame arresters meeting this standard as Type I
devices, which are certified to be effective below 0 °C and which
can sustain three stable detonations without being damaged or
permanently deformed, also comply with the minimum requirements of
the International Maritime Organization, Maritime Safety Committee
Circular No. 373 (MSC/Circ. 373/Rev.1).
3. Applicable Documents
3.1 ASTM Standards 1
1 Footnotes appear at the end of this article.
A395 Ferritic Ductile Iron Pressure-Retaining Castings For Use At
Elevated Temperatures. F722 Welded Joints for Shipboard Piping
Systems F1155 Standard Practice for Selection and Application of
Piping System Materials
3.2 ANSI Standards 2
B16.5 Pipe Flanges and Flanged Fittings.
3.3 Other Documents
3.3.1 ASME Boiler and Pressure Vessel Code 2
Section VIII, Division 1, Pressure Vessels Section IX, Welding and
Brazing Qualifications.
3.3.2 International Maritime Organization, Maritime Safety
Committee 3
MSC/Circ. 373/Rev. 1 - Revised Standards for the Design, Testing
and Locating of Devices to Prevent the Passage of Flame into Cargo
Tanks in Tankers.
3.3.3 International Electrotechnical Commission 4
Publication 79-1 - Electrical Apparatus for Explosive Gas
Atmospheres.
4. Terminology
4.1 Δ P/Po - The dimensionless ratio, for any deflagration and
detonation test of 14.3, of the maximum pressure increase (the
maximum pressure minus the initial pressure), as measured in the
piping system on the side of the arrester where ignition begins by
the device described in paragraph 14.3.3, to the initial absolute
pressure in the piping system. The initial pressure should be
greater than or equal to the maximum operating pressure specified
in paragraph 11.1.7.
4.2 Deflagration - A combustion wave that propagates
subsonically (as measured at the pressure and temperature of the
flame front) by the transfer of heat and active chemical species to
the unburned gas ahead of the flame front.
4.3 Detonation - A reaction in a combustion wave propagating at
sonic or supersonic (as measured at the pressure and temperature of
the flame front) velocity. A detonation is stable when it has a
velocity equal to the speed of sound in the burnt gas or may be
unstable (overdriven) with a higher velocity and pressure.
4.4 Detonation flame arrester - A device which prevents the
transmission of a detonation and a deflagration.
4.5 Flame speed - The speed at which a flame propagates along a
pipe or other system.
4.6 Flame Passage - The transmission of a flame through a
device.
4.7 Gasoline Vapors - A non-leaded petroleum distillate
consisting essentially of aliphatic hydrocarbon compounds with a
boiling range approximating 65 °C/75 °C.
5. Classification
5.1 The two types of detonation flame arresters covered in this
specification are classified as follows:
5.1.1 Type I - Detonation flame arresters acceptable for
applications where stationary flames may rest on the device.
5.1.2 Type II - Detonation flame arresters acceptable for
applications where stationary flames are unlikely to rest on the
device, and further methods are provided to prevent flame passage
when a stationary flame occurs. One example of “further methods” is
a temperature monitor and an automatic shutoff valve.
6. Ordering Information
6.1 Orders for detonation flame arresters under this
specification shall include the following information as
applicable:
6.1.1 Type (I or II).
6.1.2 Nominal pipe size.
6 1.3 Each gas or vapor in the system and the corresponding
MESG.
6.1.4 Inspection and tests other than specified by this
standard.
6.1.5 Anticipated ambient air temperature range.
6.1.6 Purchaser's inspection requirements (see section
10.1).
6.1.7 Description of installation.
6.1.8 Materials of construction (see section 7).
6.1.9 Maximum flow rate and the maximum design pressure drop for
that maximum flow rate.
6.1.10 Maximum operating pressure.
7. Materials
7.1 The detonation flame arrester housing, and other parts or
bolting used for pressure retention, shall be constructed of
materials listed in ASTM F 1155 (incorporated by reference, see §
154.106), or section VIII, Division 1 of the ASME Boiler and
Pressure Vessel Code. Cast and malleable iron shall not be used;
however, ductile cast iron in accordance with ASTM A395 may be
used.
7.1.1 Arresters, elements, gaskets, and seals must be made of
materials resistant to attack by seawater and the liquids and
vapors contained in the system being protected (see section
6.1.3).
7.2 Nonmetallic materials, other than gaskets and seals, shall
not be used in the construction of pressure retaining components of
the detonation flame arrester.
7.2.1 Nonmetallic gaskets and seals shall be non-combustible and
suitable for the service intended.
7.3 Bolting materials, other than that of section 7.1, shall be
at least equal to those listed in Table 1 of ANSI B16.5
(incorporated by reference, see 33 CFR 154.106).
7.4 The possibility of galvanic corrosion shall be considered in
the selection of materials.
7.5 All other parts shall be constructed of materials suitable
for the service intended.
8. Other Requirements
8.1 Detonation flame arrester housings shall be gas tight to
prevent the escape of vapors.
8.2 Detonation flame arrester elements shall fit in the housing
in a manner that will insure tightness of metal-to-metal contacts
in such a way that flame cannot pass between the element and the
housing.
8.2.1 The net free area through detonation flame arrester
elements shall be at least 1.5 times the cross-sectional area of
the arrester inlet.
8.3 Housings, elements, and seal gasket materials shall be
capable of withstanding the maximum and minimum pressures and
temperatures to which the device may be exposed under both normal
and the specified fire test conditions in section 14, and shall be
capable of withstanding the hydrostatic pressure test of section
9.2.3.
8.4 Threaded or flanged pipe connections shall comply with the
applicable B16 standards in ASTM F 1155 (incorporated by reference,
see § 154.106). Welded joints shall comply with ASTM F 722
(incorporated by reference, see § 154.106).
8.5 All flat joints of the housing shall be machined true and
shall provide for a joint having adequate metal-to-metal
contact.
8.6 Where welded construction is used for pressure retaining
components, welded joint design details, welding and
non-destructive testing shall be in accordance with Section VIII,
Division 1, of the ASME Code and ASTM F 722 (incorporated by
reference, see § 154.106). Welders and weld procedures shall be
qualified in accordance with section IX of the ASME Code.
8.7 The design of detonation flame arresters shall allow for
ease of inspection and removal of internal elements for
replacement, cleaning or repair without removal of the entire
device from the system.
8.8 Detonation flame arresters shall allow for efficient
drainage of condensate without impairing their efficiency to
prevent the passage of flame. The housing may be fitted with one or
more drain plugs for this purpose. The design of a drain plug
should be such so that by cursory visual inspection it is obvious
whether the drain has been left open.
8.9 All fastenings shall be protected against loosening.
8.10 Detonation flame arresters shall be designed and
constructed to minimize the effect of fouling under normal
operating conditions.
8.11 Detonation flame arresters shall be capable of operating
over the full range of ambient air temperatures anticipated.
8.12 Detonation flame arresters shall be of first class
workmanship and free from imperfections which may affect their
intended purpose.
8.13 Detonation flame arresters shall be tested in accordance
with section 9.
9. Tests
9.1 Tests shall be conducted by an independent laboratory
capable of performing the tests. The manufacturer, in choosing a
laboratory, accepts that it is a qualified independent laboratory
by determining that it has (or has access to) the apparatus,
facilities, personnel, and calibrated instruments that are
necessary to test detonation flame arresters in accordance with
this standard.
9.1.1 A test report shall be prepared by the laboratory which
shall include:
9.1.1.1 Detailed drawings of the detonation flame arrester and
its components (including a parts list identifying the materials of
construction).
9.1.1.2 Types of tests conducted and results obtained. This
shall include the maximum temperature reached and the length of
testing time in section 14.2 in the case of Type II detonation
flame arresters.
9.1.1.3 Description of approved attachments (reference
9.2.6).
9.1.1.4 Types of gases or vapors for which the detonation flame
arrester is approved.
9.1.1.5 Drawings of the test rig.
9.1.1.6 Record of all markings found on the tested detonation
flame arrester.
9.1.1.7 A report number.
9.2 One of each model Type I and Type II detonation flame
arrester shall be tested. Where approval of more than one size of a
detonation flame arrester model is desired, only the largest and
smallest sizes need be tested provided it is demonstrated by
calculation and/or other testing that intermediate size devices
have equal or greater strength to withstand the force of a
detonation and have equivalent detonation arresting
characteristics. A change of design, material, or construction
which may affect the corrosion resistance, or ability to resist
endurance burning, deflagrations or detonations shall be considered
a change of model for the purpose of this paragraph.
9.2.1 The detonation flame arrester shall have the same
dimensions, configuration, and most unfavorable clearances expected
in production units.
9.2.2 A corrosion test shall be conducted. In this test, a
complete detonation flame arrester, including a section of pipe
similar to that to which it will be fitted, shall be exposed to a
20% sodium chloride solution spray at a temperature of 25 °C for a
period of 240 hours, and allowed to dry for 48 hours. Following
this exposure, all movable parts shall operate properly and there
shall be no corrosion deposits which cannot be washed off.
9.2.3 The detonation flame arrester shall be subjected to a
hydrostatic pressure test of at least 350 psig for ten minutes
without rupturing, leaking, or showing permanent distortion.
9.2.4 Flow characteristics as declared by the manufacturer,
shall be demonstrated by appropriate tests.
9.2.5 Detonation flame arresters shall be tested for endurance
burn and deflagration/detonation in accordance with the test
procedures in section 14. Type I detonation flame arresters shall
show no flame passage when subjected to both tests. Type II
detonation flame arresters shall show no evidence of flame passage
during the detonation/deflagration tests in section 14.3. Type II
detonation flame arresters shall be tested for endurance burn in
accordance with section 14.2. From the endurance burn test of a
Type II detonation flame arresters, the maximum temperature reached
and the test duration shall be recorded and provided as part of the
laboratory test report.
9.2.6 Where a detonation flame arrester is provided with cowls,
weather hoods and deflectors, etc., it shall be tested in each
configuration in which it is provided.
9.2.7 Detonation flame arresters which are provided with a
heating arrangement designed to maintain the surface temperature of
the device above 85 °C shall pass the required tests at the maximum
heated operating temperature.
9.2.8 Each finished detonation arrester shall be pneumatically
tested at 10 psig to ensure there are no defects or leakage.
10. Inspection
10.1 The manufacturer shall afford the purchaser's inspector all
reasonable access necessary to assure that the device is being
furnished in accordance with this standard. All examinations and
inspections shall be made at the place of manufacture, unless
otherwise agreed upon.
10.2 Each finished detonation arrester shall be visually and
dimensionally checked to ensure that the device corresponds to this
standard, is certified in accordance with section 11 and is marked
in accordance with section 12. Special attention shall be given to
the checking of welds and the proper fit-ups of joints (see
sections 8.5 and 8.6).
11. Certification
11.1 Manufacturer's certification that a detonation flame
arrester meets this standard shall be provided in an instruction
manual. The manual shall include as applicable:
11.1.1 Installation instructions and a description of all
configurations tested (reference paragraph 9.2.6). Installation
instructions to include the device's limitations.
11.1.2 Operating instructions.
11.1.3 Maintenance requirements.
11.1.3.1 Instructions on how to determine when arrester cleaning
is required and the method of cleaning.
11.1.4 Copy of test report (see section 9.1.1).
11.1.5 Flow test data, maximum temperature and time tested (Type
II).
11.1.6 The ambient air temperature range over which the device
will effectively prevent the passage of flame.
Note:
Other factors such as condensation and freezing of vapors should
be evaluated at the time of equipment specification.
11.1.7 The maximum operating pressure for which the device is
suitable.
12. Marking
12.1 Each detonation flame arrester shall be permanently marked
indicating:
12.1.1 Manufacturer's name or trademark.
12.1.2 Style, type, model or other manufacturer's designation
for the detonation flame arrester.
12.1.3 Size of the inlet and outlet.
12.1.4 Type of device (Type I or II).
12.1.5 Direction of flow through the detonation flame
arrester.
12.1.6 Test laboratory and report number.
12.1.7 Lowest MESG of gases that the detonation flame arrester
is suitable for.
12.1.8 ASTM designation of this standard.
12.1.9 Ambient air operating temperature range.
12.1.10 Maximum operating pressure.
13. Quality Assurance
13.1 Detonation flame arresters shall be designed, manufactured
and tested in a manner that ensures they meet the characteristics
of the unit tested in accordance with this standard.
13.2 The detonation flame arrester manufacturer shall maintain
the quality of the arresters that are designed, tested and marked
in accordance with this standard. At no time shall a detonation
flame arrester be sold with this standard designation that does not
meet the requirements herein.
14. Test Procedures for Detonation Arresters
14.1 Media/Air Mixtures
14.1.1 For vapors from flammable or combustible liquids with a
MESG greater than or equal to 0.9 mm, technical grade hexane or
gasoline vapors shall be used for all tests in this section except
technical grade propane may be used for the deflagration/detonation
tests in section 14.3. For vapors with a MESG less than 0.9 mm, the
specific vapor (or alternatively, a media with a MESG less than or
equal to the MESG of the vapor) must be used as the test medium in
all Section 14 tests.
14.1.2 Hexane, propane, gasoline and other test vapors shall be
mixed with air to form the most easily ignitable mixture. 5
14.2 Endurance Burn Test Procedure
14.2.1 An endurance burning test shall be carried out as
follows:
14.2.1.1 The test rig shall consist of an apparatus producing an
explosive mixture, a small tank with a diaphragm, a prototype of
the detonation flame arrester and a firing source in close
proximity to the test device (see Figure 1). The detonation flame
arrester shall be installed so that the mixture emission is
vertically upwards, or installed in the position for which it is
designed and which will cause the most severe heating of the device
under the prescribed endurance burn conditions. In this position
the mixture shall be ignited.
14.2.1.2 Endurance burn test shall start by using the most
easily ignitable test vapor/air mixture with the aid of a pilot
flame or a spark igniter at the outlet. The flammable mixture may
be reignited as necessary in the course of the endurance burn.
14.2.1.3 Temperature measurement will be performed on the
surface of the arrester element half way between the center and its
edge.
14.2.1.4 By varying the proportions of the flammable mixture and
the flow rate, the detonation flame arrester shall be heated by a
stable flame on the surface of the arrester until the highest
obtainable temperature is reached on the ignited side or until the
temperature on the side which was not ignited (protected side)
rises 100 °C.
14.2.1.5 The flammable mixture proportions will then be varied
again until the conditions which result in the highest temperature
on the protected side are achieved. This temperature shall be
maintained for a period of ten minutes, after which the flow shall
be stopped and the conditions observed. The highest attainable
temperature is considered to have been reached when any subsequent
rise of temperature does not exceed 0.5 °C per minute over a ten
minute period.
14.2.1.6 If difficulty arises in establishing the highest
attainable temperature on the protected side, the following
criteria shall apply. When the increase in temperature on the
protected side occurs so slowly that its temperature does not rise
100 °C, the conditions which produced the highest temperature on
the ignited side of the arrester will be maintained for two hours.
For the condition in which the temperature on the protected side
continues to rise at a rate in excess of 0.5 °C per minute for a 10
minute period, endurance burning shall be continued, using the most
severe conditions of flammable mixtures and flow rate, for a period
of two hours. In either of these cases, at the end of the two hour
period, the flow shall be stopped and the conditions observed. The
two hour interval shall be measured commencing with the setting of
the conditions which produced the most severe conditions of mixture
and flow rate. For Type I detonation flame arresters, flame passage
shall not occur during this test. For Type II detonation flame
arresters, the maximum temperature obtained, and the time elapsed
from the time when the most severe conditions are set to when flame
passage occurs, shall be recorded. However, for Type II detonation
flame arresters the test may be terminated 15 minutes after setting
the most severe conditions on the protected side.
14.3 Deflagration/Detonation Test Procedure
14.3.1 A detonation flame arrester shall be installed at one end
of a pipe of the same diameter as the inlet of the detonation flame
arrester (see Figure 2). The length and configuration of the test
pipe shall develop a stable detonation 6 at the device and shall be
capable, by change in its length or configuration, of developing
deflagrations and unstable (overdriven) detonations as measured on
the side of the pipe where ignition occurs (run-up side). For
deflagration testing, two test piping arrangements shall be used on
the outlet side of the detonation flame arrester (the side which is
not ignited). In both of the following end arrangements, the outlet
side pipe diameter shall be equal to that on the run-up side. In
one arrangement, the outlet side pipe shall be at least 10 pipe
diameters long with a plastic bag over the free end. (Alternate end
of pipe closures are also acceptable provided they easily give way
during the course of the test, and the closure allows the required
gas concentration to be maintained throughout the test piping
arrangement.) In the other arrangement the outlet side pipe shall
be fitted with a restriction located 0.6 meters from the outlet
side arrester flange. The size of the restriction for each nominal
size detonation flame arrester shall be as follows:
| Nominal pipe diameter
(inches) |
Restriction diameter
(inches) |
| 3 |
1/2 |
| 4 |
1/2 |
| 6 |
1 |
| 8 |
1 1/2 |
| 10 |
1 1/2 |
| 12 |
2 |
| 18 |
2 |
| 24 |
2 |
The entire pipe shall be filled with the most easily ignitable
vapor/air mixture to a test pressure corresponding to or greater
than the upper limit of the device's maximum operating pressure
(see 11.1.7). In order to obtain this test pressure, a device such
as a bursting disc may be fitted on the open end of the device in
place of the plastic bag. The concentration of the mixture should
be verified by appropriate testing of the gas composition. The
vapor/air mixture shall then be ignited.
14.3.2 Flame speeds shall be measured by optical devices capable
of providing accuracy of ±5%. These devices shall be situated no
more than a distance equal to 3% of the length of the run-up pipe
apart with one device no more than 8 inches from the end of the
test pipe to which the detonation flame arrester is attached. In
addition, each outlet arrangement described in paragraph 14.3.1
shall be fitted with an optical device located no more than 8
inches from the detonation flame arrester outlet. 7
14.3.3 Explosion pressures within the pipe shall be measured by
a high frequency transducer situated in the test pipe no more than
8 inches from the run-up side of the housing of the detonation
flame arrester.
14.3.4 Using the first end arrangement (10 pipe diameter outlet)
described in paragraph 14.3.1, a series of tests shall be conducted
to determine the test pipe length and configuration that results in
the maximum unstable (overdriven) detonation having the maximum
measured flame speed at the detonation flame arrester. (These tests
may also be carried out using a single length of pipe with igniters
spaced at varying distances from the arrester.) The flame speeds,
explosion pressures and test pipe configurations shall be recorded
for each of these tests. The piping configuration that resulted in
the highest recorded unstable (overdriven) detonation flame speed
shall be used, and the device shall be subjected to at least four
additional unstable (overdriven) detonations. In the course of
testing, the device shall also demonstrate its ability to withstand
five stable detonations, five deflagrations (as determined by flame
speed) where Δ P/Po was less than 1 and five deflagrations (as
determined by flame speed) where Δ P/Po was greater than 1 but less
than 10. Initiation of deflagrations shall be at several locations
to generate a range for Δ P/Po. Deflagration tests using the
restricted outlet arrangement described in paragraph 14.3.1 shall
then be conducted. In these tests the device shall demonstrate its
ability to stop five deflagrations (as determined by flame speed)
generated by the same configurations which resulted in Δ P/Po being
less than 1 during the deflagration tests which were conducted
without the restricted end arrangements, and five deflagrations (as
determined by flame speed) generated by the same configurations
which resulted in Δ P/Po being greater than 1 but less than 10
during the deflagration tests which were conducted without the
restricted end arrangements. No evidence of flame passage shall
occur during these tests. The flame speeds and explosion pressures
for each of these tests shall be recorded.
14.3.5 A device that successfully passes the tests of 14.3.4
shall be considered to be directional (suitable for arresting a
detonation advancing only from the direction as tested) except;
14.3.5.1 A device may be tested according to 14.3.4 for
detonations approaching from either direction, or
14.3.5.2 The design of the device is symmetrical where each end
may be considered to be identical when approached by a detonation
from either direction.
1 Available from the American Society for Testing and Materials
(ASTM), 100 Barr Harbor Dr., West Conshohocken, PA 19428-2959.
2 Available from the American Society of Mechanical Engineers
International, Three Park Avenue, New York, NY 10016-5990.
3 Available from the International Maritime Organization, 4
Albert Embankment, London SE1 7SR, England.
4 Available from the International Electrotechnical Commission,
1 rue de Varembe, Geneva, Switzerland.
5 See IEC Publication 79-1.
6 Some data are available for the estimation of flame speeds in
horizontal pipes without detonation flame arresters. Some data
indicate that the presence of small obstacles, fittings or bends in
the test pipe can accelerate the flame speeds appreciably.
7 Other pressure and/or flame speed measuring techniques may be
used if effective.
| Inflammable gas
or vapour |
Experimental
maximum safe gap |
| mm |
in. |
| Methane |
1.170 |
0.046 |
| Blast furnace
gas |
1.193 |
0.047 |
| Propane |
0.965 |
0.038 |
| Butane |
1.066 |
0.042 |
| Pentane |
1.016 |
0.040 |
| Hexane |
0.965 |
0.038 |
| Heptane |
0.965 |
0.038 |
| Iso-octane |
1.040 |
0.041 |
| Decane |
1.016 |
0.040 |
| Benzene |
0.99 |
0.039 |
| Xylene |
1.066 |
0.042 |
| Cyclohexane |
0.94 |
0.037 |
| Acetone |
1.016 |
0.040 |
| Ethylene |
0.71 |
0.028 |
|
Methyl-ethyl-ketone |
1.016 |
0.040 |
| Carbon
monoxide |
0.915 |
0.036 |
|
Methyl-acetate |
0.990 |
0.039 |
| Ethyl-acetate |
1.04 |
0.041 |
|
Propyl-acetate |
1.04 |
0.041 |
| Butyl-acetate |
1.016 |
0.040 |
| Amyl-acetate |
0.99 |
0.039 |
| Methyl
alcohol |
0.915 |
0.036 |
| Ethyl alcohol |
1.016 |
0.040 |
|
Iso-butyl-alcohol |
0.965 |
0.038 |
| Butyl-alcohol
(Normal) |
0.94 |
0.037 |
| Amyl-alcohol |
0.99 |
0.039 |
| Ethyl-ether |
0.864 |
0.034 |
| Coal gas (H2
57%) |
0.482 |
0.019 |
| Acetylene |
≤0.025 |
≤0.001 |
| Carbon
disulphide |
0.203 |
0.008 |
| Hydrogen |
0.102 |
0.004 |
| Blue water gas (H2
53% CO 47%) |
0.203 |
0.008 |
| Ethyl nitrate |
≤0.025 |
≤0.001 |
| Ammonia |
1 3.33 |
1 0.133 |
| Ethylene
oxide |
0.65 |
0.026 |
| Ethyl nitrite |
0.922 |
0.038 |
[CGD 88-102, 55 FR 25435, June 21, 1990; 55 FR 39270, Sept. 26,
1990, as amended by CGD 96-026, 61 FR 33666, June 28, 1996;
USCG-1999-5832, 64 FR 34715, June 29, 1999; USCG-2000-7223, 65 FR
40058, June 29, 2000; USCG-2010-0351, 75 FR 36284, June 25, 2010;
USCG-1999-5150, 78 FR 42641, July 16, 2013; USCG-2014-0410, 79 FR
38436, July 7, 2014]