Mandatory Calibration and Tests for SmokeStack Testing Equipment (Malaysian Standard MS 1596 and MS 1723)

Doc ID: AERHQWW-ecy3-en
Last revised: 0, 23.07.06

This page contains a summary of the mandatory calibration (and tests/checks/verifications) required for equipment used in Malaysian Standard MS 1596 and MS 1723 for smokestack testing ("stack testing" and isokinetic sampling on stationary sources of air pollution).

For smokestack testing (and especially isokinetic sampling), the sampling procedures are more important than the analytical procedures. This is because of the difficulty in getting a representative sample of the flue gas inside the smokestack. The pollutants could be in solid, liquid, or gaseous states, or a mixture (e.g., solid in gas) which is not well mixed, and with many other interferences.

We strongly recommend attaching proof of the below calibrations and tests/checks to the final smokestack testing report.

Notes:

Please note that this page will be focusing on the more uncommon calibrations and tests, which are special to smokestack testing.
This page is based on what is written in MS 1596:2003 and MS 1723:2003. Refer to local authorities for actual local rules!
MS 1596:2003 and MS 1723:2003 are only for general particulate matter "dust", and not any specific chemical (in any state: solid, liquid, or gaseous)

MS 1596:2003 is based on ISO 9096:1992, and ISO 10780. Refer to the "Foreword" of the Standard.

As stated in section 10.1 of MS 1723:2003, a [smoke-stack] test shall be done a minimum of three times, to ensure reasonable accuracies and make it possible to compare results.

This is the same for US EPA Methods, where 1 stack "test" = 3 sampling "runs"
Refer also to the Environmental Quality Act (Clean Air) Regulations 2014, Regulation 23

Other useful links:

Aer Sampling Basic Training Video with names of equipment and their individual components
Click here to order Malaysian Standards at the Department of Standards
To order ISO Standards, click here to visit ISO online store
Why is calibration important? Click here to link to YouTube videos:

Video 1 (English; US Navy)
Video 2 (English; Omega Engineering)

To return to Aer Sampling's Smokestack Testing Encyclopedia content page, click here, or scan the QR Code below:

Overview of this webpage:

Images of entire sampling train of equipment for MS 1596:2003 (Method i, dry gas measurement)
Table of mandatory calibrations

Integrating Dry Gas Meter (DGM)
Critical Orifices (to calibrate DGM)
Temperature Sensor
Thermocouple Simulator (to calibrate temperature sensor)
Field Balance
Analytical Balance
Orifice Meters, Rotameters
Manometers and Pressure Gages
Calipers (to test S-type Pitot Tubes)
Angle Indicator or Inclinometers (to test S-type Pitot Tubes)
Profile Projector or equivalent (to test S-type Pitot Tubes)
Flue Gas Analyzers
Timer
Internal Diameter Micrometers (to test Sampling Nozzle)
Other Analytical Instruments
Rod to measure internal diameter of smoke-stack

*Table of mandatory tests/verifications

Leak Check - Pitot Line
Leak Check - Sampling Gas Line
Leak Check - Meter Console (Vacuum side, "Front-Half")
Leak Check - Meter Console (Pressure side, "Back-Half")
S-type Pitot Tube - in a Combination Probe
S-type Pitot Tube - by itself
Suction Nozzle - Entry Wall Thickness
Suction Nozzle - Diameter "Size"

Optional Calibrations

Barometer
S-type Pitot Tubes
L-type (Standard) Pitot tubes

Table of mandatory calibrations (click individual item for details):

Including calibrations to ensure metrological traceability

What to calibrate

Frequency

Calibrated Against

1. Integrating Dry Gas Meter (DGM), inside the Meter Console

Once a year (minimum)

Refer to:

MS 1596:2003, Section 7.6g
MS 1596:2003 Section 7.6, last paragraph

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

Recommend to use Critical Orifices

2. Critical Orifice (to calibrate DGM)

Once a year (minimum)

Refer to:

MS 1596:2003, Section 7.6 (c) and (g), and last paragraph

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

Recommend to use Bell Gas Provers

Click here (or scan QR Code below) to view Aer Sampling's traceable calibration service for Critical Orifices

3. Temperature Sensor, inside the Meter Console

Need to calibrate every thermocouple connected to Temperature Sensor too (via all the thermocouple plugs and sockets)

Once a year (minimum)

Refer to:

MS 1596:2003 Section 7.6, last paragraph

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

Recommend to use Thermocouple Simulators

4. Thermocouple Simulator

Used to calibrate the Temperature Sensor

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

Recommended: Minimum once a year

Refer to:

MS 1596:2003, Section 7.6, last paragraph

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

5. Field Balance

Used for weighing contents of impingers

Once a year (minimum)

Refer to:

MS 1596:2003 Section 7.6b, last paragraph

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

6. Analytical Balance

Used to measure weight of filter papers (MS 1596:2003: "particle separator")

Once a year (minimum)

Refer to:

MS 1596:2003 Section 7.6b, last paragraph

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

7. Flow rate measuring devices

Orifice Plate (Orifice Tube, Orifice Meter)

Used as a guide to adjust the pump valves, to vary velocity of gas entering sampling nozzles
Usually done together with Dry Gas Meter (DGM) calibration, refer to DGM section below
Location

Method i: Downstream of DGM
Method ii: Downstream of Particle Separator (Filter holder)

Rotameters (If in use)

Once a year (minimum)

Refer to:

MS 1596:2003 Section 7.6c, last paragraph

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

Recommended to use Critical Orifices, refer to section below

8. Manometers and Pressure Gages

Used to measure differential pressure head "Delta P" of flue gas inside smokestack, which is then used to calculate velocity

Once a year (minimum)

Refer to:

MS 1596:2003 Section 7.6c, last paragraph

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

9. Calipers

This is used to test S-type Pitot Tubes construction specifications (lengths and widths), to avoid having to calibrate the S-type Pitot Tubes.

Refer to:

MS 1596:2003, Appendix D

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

Recommended: Minimum once a year

Refer to:

MS 1596:2003, Section 7.6, last paragraph

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

10. Angle Indicator or Inclinometer, with Bull's Eye Level

These are used to test S-type Pitot Tubes construction specifications (angles), to avoid having to calibrate.

Refer to:

MS 1596:2003, Appendix D

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

Recommended: Minimum once a year

Refer to:

MS 1596:2003, Section 7.6, last paragraph

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

11. Profile Projector "Optical Comparator", or Microscope with image analysis software, or equivalent

This is used to test S-type Pitot Tubes construction specifications; dimension L1 and L2 of MS 1596:2003, Figure D1.

Refer to:

MS 1596:2003, Appendix D, paragraph 1, "dimension L1 and L2 in Figure D1 shall be equal for each leg"

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

Recommended: Minimum once a year

Refer to:

MS 1596:2003, Section 7.6, last paragraph

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

12. Flue Gas Analyzers

Wet-Chemistry Type (Orsat, Fyrite)
Instrumental Type (NDIR, electrochemical etc.)

Once a year (minimum)

Refer to:

MS 1596:2003, Section 7.6 (f)

Not mentioned (but usually calibration gases of specified and traceable purity)

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

Recommended standards:

US EPA Method 3
US EPA Method 3a, 7e
ISO 10849
ISO 7935

13. Timer

Used to countdown to sampling at the next traverse points inside the smokestack

Once a year (minimum)

Refer to:

MS 1596:2003 Section 7.6 (h), last paragraph

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

14. Internal Diameter Micrometers

Used to test entry diameter of Sampling Nozzles, which are used to determine flow rate etc.

Refer to:

MS 1596:2003, Section 7.3, and Section 14.g.iii.
MS 1596:2003, Table 1

dn1: Inner nozzle diameter
dn2: Outer nozzle diameter

MS 1596:2003, Figure 2 and Figure 3 (Suction Nozzle Diameter XIII)

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

Recommended: Minimum once a year

Refer to:

MS 1596:2003, Section 7.6, last paragraph

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

15. Other Analytical Instruments

Not mentioned in MS 1596:2003 and MS 1723:2003, because these Standards are for "dust" only

Some examples:

High Resolution Gas Chromatograph/Mass Spectrometer (HRGS/HRMS)
Ion Chromatograph (IC)
Atomic Absorption Spectrometer (AAS)
Etc.

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

Recommended: Minimum once a year

Refer to:

MS 1596:2003, Section 7.6, last paragraph

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

16. Rod to measure internal diameter of smokestack

Refer to:

MS 1596:2003, Table 3, Part number 27

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

Recommended: Minimum once a year

Refer to:

MS 1596:2003, Section 7.6, last paragraph

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

Related topics: ISO/IEC 17025, ILAC MRA, scope of accreditation, stationary/fixed sources of air pollution, SAMM

------

List of mandatory tests/verifications (click individual item for details):

What to test/verify

Frequency

Test Using

1. Leak Check: Pitot Line

The "Pitot Line" consist of three items: Pitot Tubes, Pitot Tube connections (Umbilical Cable), Manometers or Pressure Gages (inside Meter Console)

Refer to:

MS 1596:2003, Section 9.2, paragraph 2
MS 1596:2003, Appendix C, Section C2, paragraph 4

Before sampling starts (after equipment assembled)

Refer to:

MS 1596:2003, Section 9.2, paragraph 2

After each period of use (each stack test)

Refer to:

MS 1596:2003, Appendix C, Section C1, last paragraph
MS 1596:2003, Appendix C, Section C2, paragraph 4

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

Recommend to use Manometers or Pressure Gages, both in meter console

2. Leak Check: Sampled Gas Line

From the Suction Nozzle to the pump valves and fittings, and Dry Gas Meter (DGM) inside the Meter Console

Leak rate shall be less than 1% of the volumetric flow rate at a vacuum of at least 50 kPa (14.765 inHg)

Refer to:

MS 1596:2003, Section 9.2, paragraph 4

Before start of sampling (after assembling entire sampling train, from the nozzle to meter console)

Refer to:

MS 1596:2003, Section 9.2, paragraph 3, 5

Recommend to check for leaks after the sampling too

Dry Gas Meter (DGM), usually inside the Meter Console

3. Leak Check - Meter Console (Vacuum Side, "Front-Half")

From the Sampled Gas inlet to the pump valves and fittings inside the Meter Console

When necessary (This is part of the sampling gas line train leak check, but just for the meter console)

Dry Gas Meter (DGM), which is inside the Meter Console

Recommend to use procedures in US EPA Method 5

4. Leak Check - Meter Console (Pressure Side, "Back-Half")

From the pump valves and fittings to the Orifice Meter (downstream after the DGM)

When necessary (This is part of the

sampling gas line train leak check,

but just for the meter console)

Manometers or Pressure Gages); Analog or Digital), which are inside the Meter Console

Recommend to use procedures in US EPA Method 5

5. Suction Nozzle - Entry wall thickness

If the wall thickness at the mouth of the Nozzle is too thick, the diameter of the nozzle is calculated using a specified formula.

Refer to:

MS 1596:2003, Section 7.3, paragraph 2, and Figure 5

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

Recommended: Before each use, to test if nozzle still in original shape, given the importance of the nozzle in determining isokinetic velocity

Refer to:

MS 1596:2003, Section 7.3, Figure 5
MS 1596:2003, Appendix A, Section A4

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

Recommended: Vernier Calipers

6. Suction Nozzle - Diameter "Size"

The diameter of the sampling nozzle where the flue gas enters the nozzle. This directly impacts the isokinetic rate calculations.

Refer to:

MS 1596:2003, Section 7.3, paragraph 3, and Note 2
MS 1596:2003, Section 14.g.iii.

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

Recommended: Before each use, to test if nozzle size is still valid, and not dented or damaged in any way, because you would have to select the correct nozzle size to sample isokinetically

Refer to:

MS 1596:2003, Section 9.2, paragraph 5
MS 1596:2003, Section 10.2, paragraph 2
MS 1596:2003, Section 10.4.1, paragraph 7

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

Recommended: Internal Diameter Micrometers

7. S-Type Pitot Tube - as part of a Combination Probe

Combination Probes are probes where the suction nozzle, S-type pitot tubes, and temperature sensor are combined for sampling.

Construction dimensions to test and assign S-type Pitot Tube Calibration Factor ("Coefficient", "Calibration Constant") of 0.84. If failed any tests below, replace or repair pitot tube, or calibrate using Wind Tunnel (together with the Combination Probe), per MS 1596:2003 Appendix D. For clearer procedures, we recommend using procedures in US EPA Method 2, Section 10.1 and 10.1.1.

MS 1596:2003 Appendix D (Refer to ISO 10780 for more details):

Angles

Figure D1a): Transverse Tube Axis must be perpendicular to the Face opening planes (i.e., Zero degrees variation)
Figure D1a): Face opening plane must be parallel to one another (i.e., Zero degrees variation)
Figure D1b): A-side plane and B-side plane must be parallel to the Longitudinal Tube Axis (i.e., Zero degrees variation)
Figure D1c): The pitot tube must look like this in this view. The back leg cannot exceed the dimension of the front leg on any sides (i.e., Zero degrees variation on all sides)

Refer to US EPA Method 2, Figure 2-3 for the clearest diagrams on this

Lengths and Widths

Paragraph 1 and Figure D1b): L1 = L2
Paragraph 1: L1 or L2 must be between 1.05 and 10 times the external diameter of the tubing
Figure D2: Distance between opening of Impact Orifice (of Pitot Tube) and Nozzle Entry Plane must be sufficiently far apart

MS 1596:2003, Section 10.2, paragraph 5
Refer to Jabatan Alam Sekitar or ISO/IEC 17025 assessors for definition of "sufficiently far apart"

Figure D2: Dimension X > 19 mm (between S-type Pitot Tube and 13 mm diameter nozzle)
Figure D3: Dimension X > 75 mm
Figure D3: Dimension X > 19 mm (between thermocouple and S-type Pitot Tube)
Figure D3: Dimension X > 50 mm

After use at each field site

Refer to:

MS 1596:2003, Appendix E, paragraph 3
MS 1596:2003, Appendix C, Section C1, last paragraph

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

Recommended to use:

Calipers
Angle Indicators or Inclinometers
Profile Projectors or equivalent etc. (For L1 = L2 test only)

8. S-Type Pitot Tube - Without Probe

Pitot Tubes by itself, without nozzles, thermocouple etc.

Construction dimensions to test and assign S-type Pitot Tube Calibration Factor ("Coefficient", "Calibration Constant") of 0.84. If failed any tests below, replace or repair pitot tube, or calibrate using Wind Tunnel, per MS 1596:2003 Appendix D. For clearer procedures, we recommend using procedures in US EPA Method 2, Section 10.1 and 10.1.1.

MS 1596:2003 Appendix D (Refer to ISO 10780 for more details)

Angles

Figure D1a): Transverse Tube Axis must be perpendicular to the Face opening planes (i.e., Zero degrees variation)
Figure D1a): Face opening plane must be parallel to one another (i.e., Zero degrees variation)
Figure D1b): A-side plane and B-side plane must be parallel to the Longitudinal Tube Axis (i.e., Zero degrees variation)
Figure D1c): The pitot tube must look like this in this view. The back leg cannot exceed the dimension of the front leg on any sides (i.e., Zero degrees variation on all sides)

Refer to US EPA Method 2, Figure 2-3 for the clearest diagrams on this

Lengths and Widths

Paragraph 1 and Figure D1b): L1 = L2
Paragraph 1: L1 or L2 must be between 1.05 and 10 times the external diameter of the tubing

After use at each field site

Refer to:

MS 1596:2003, Appendix E, paragraph 3
MS 1596:2003, Appendix C, Section C1, last paragraph

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

Recommended to use:

Calipers
Angle Indicators or Inclinometers
Profile Projectors or equivalent etc. (For L1 = L2 test only)

Optional Calibrations

These are calibrations that are not mentioned inside Malaysian Standards MS 1596:2003 and MS 1723:2003, and are not used to calibrate other instruments.

What to Calibrate

Frequency

Calibrated Against

1. Barometer

Used to measure barometric pressure, which is used in isokinetic rate calculations

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

Recommended: Minimum once a year

Refer to:

MS 1596:2003, Section 7.6, last paragraph

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

Recommended: Mercury Barometer

2. Pitot Tubes (S-type)

If failed tests on constructions specifications, a calibration in a Wind Tunnel against a Standard (L-type) Pitot Tube (MS 1596:2003: "Standard Pitot Static Tube"), is required.

Refer to:

MS 1596:2003, Appendix D and E

Prior to use

Refer to:

MS 1596:2003, Section 9.1, paragraph 4
MS 1596:2003, Appendix E

---

After use at each field site (if it fails construction specification tests)

Refer to:

MS 1596:2003, Appendix D, paragraph 2, and Figure D1, D2, D3
MS 1596:2003, Appendix E, paragraph 1 and 3

---

Once a year (minimum)

Refer to:

MS 1596:2003 Section 7.6e, last paragraph

Standard (L-type) Pitot Tube in a Wind Tunnel

Refer to:

MS 1596:2003, Appendix E, paragraph 1 to 5

3. Pitot Tubes (Standard; L-type)

Other names:

MS 1596:2003, Appendix C

"Standard Pitot Static Tube"
"Pitot Static Tube"

ISO 10780:1994(E)

Prandtl Pitot tube

Once a year (minimum)

Refer to:

MS 1596:2003 Section 7.6e, last paragraph

Not mentioned

Refer to Jabatan Alam Sekitar or ISO/IEC 17025 Technical Assessors

-----

Information presented here is subjected to Aer Sampling Group's terms and conditions.
In case of discrepancy between English version and the non-English version, the English version shall prevail.