BW Technologies 54-53-A01032180NW, 54-53-A09148000NW, 54-53-A14008000NW, 54-53-B00008000A, 54-53-A01025280NW User manual

Reference Manual

PH D6™ Gas D etector

Part Number 13-322 Version 5

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PHD6 PERSONAL PORTABLE GAS DETECTORS HAVE BEEN DESIGNED FOR THE DETECTION AND MEASUREMENT

IN ORDER TO ASSURE THAT THE USER IS PROPERLY WARNED OF POTENTIALLY DANGEROUS ATMOSPHERIC

CONDITIONS, IT IS ESSENTIAL THAT THE INSTRUCTIONS IN THIS REFERENCE M ANUAL BE READ, FULLY

No page or part of this operation manual may be reproduced in any form without written permission of the copyright

OF POTENTIALLY HAZARDOUS ATMOSPHERIC CONDITIONS

UNDERSTOOD, AND FOLLOWED.

Honeywell Analytics, Inc.

Lincolnshire, Illinois 60069

Honeywell Analytics reserves the right to correct typographical errors.

Specifications are subject to change without notice.

PHD6™

Reference Manual

Part Number 13-322

Version 5

Copyright 2015

by

All rights reserved.

owner shown above.

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CERTIFICATION INFORMATION ........................................................................................................................................................... 4

TABLE OF CONTENTS

OPERATING TEMPERATURE AND HUMIDITY LIMITS ............................................................................................................................. 4

SIGNAL WORDS ................................................................................................................................................................................ 4

WARNINGS AND CAUTIONS ............................................................................................................................................................... 5

CONDITIONS FOR SAFE USE:............................................................................................................................................................. 7

CONDITIONS POUR UNE UTILISATION EN TOUTE SÉCURITÉ: ................................................................................................................ 7

1. DESCRIPTION ........................................................................................................................................................................ 8

1.1 Methods of sampling ............................................................................................................................................... 8

1.2 Multi-sensor capability ............................................................................................................................................ 8

1.3 Calibration ................................................................................................................................................................ 8

1.4 Alarm logic ................................................................................................................................................................ 8

1.4.1 Atmospheric hazard alarms .................................................................................................................................. 9

1.4.2 Low battery alarms................................................................................................................................................ 9

1.4.3 Sensor over range alarms ..................................................................................................................................... 9

1.4.4 PID lamp out alarm ............................................................................................................................................... 9

1.4.5 LEL response failure due to lack of O2 alarm ........................................................................................................ 9

1.4.6 Security beep/flash ............................................................................................................................................... 9

1.4.7 Latching alarms .................................................................................................................................................... 9

1.4.8 Fault detection ...................................................................................................................................................... 9

1.5 Other electronic safeguards .................................................................................................................................. 10

1.6 Sensors ................................................................................................................................................................... 10

1.6.1 Cross Sensitivity ................................................................................................................................................. 10

1.7 Optional sample draw pump ................................................................................................................................. 10

1.7.1 Special precautions when using the PHD6 pump ............................................................................................... 10

1.8 Data storage ........................................................................................................................................................... 10

1.8.1 Black box data recorder ...................................................................................................................................... 10

1.8.2 Event logger ........................................................................................................................................................ 11

1.9 PHD6 design components ..................................................................................................................................... 11

1.10 PHD6 standard accessories .................................................................................................................................. 11

1.10.1 Alkaline PHD6 detectors ..................................................................................................................................... 11

1.10.2 Li-Ion PHD6 detectors......................................................................................................................................... 11

1.11 PHD6 kits ................................................................................................................................................................ 11

1.11.1 PHD6 Confined Space Kits ................................................................................................................................. 11

1.11.2 PHD6 Value Packs ............................................................................................................................................. 11

2. BASIC OPERATIONS ............................................................................................................................................................ 12

2.1 Turning the P HD6 On ............................................................................................................................................. 12

2.1.1 Start up with pump .............................................................................................................................................. 12

2.1.2 Start up with PID or IR sensor ............................................................................................................................ 13

2.2 Operating Logic ...................................................................................................................................................... 13

2.2.1 Status Bar ........................................................................................................................................................... 13

Battery Status Icon ........................................................................................................................................................ 13

IR Hourglass Symbol ..................................................................................................................................................... 13

PID Hourglass Symbol .................................................................................................................................................. 13

Heartbeat Symbol .......................................................................................................................................................... 13

Pump Status Icon .......................................................................................................................................................... 13

Calibration and Bump Due Warnings ............................................................................................................................ 13

Time 13

2.2.2 Screen Flip .......................................................................................................................................................... 13

2.3 Turning the PHD6 Off ............................................................................................................................................. 14

2.4 Atmospheric Hazard Alarms ................................................................................................................................. 14

2.4.1 O2 Alarms ........................................................................................................................................................... 14

2.4.2 Combustible Gas Alarms .................................................................................................................................... 14

2.4.3 Toxic and VOC sensor alarms ............................................................................................................................ 14

2.4.4 Alarm Descriptions .............................................................................................................................................. 14

Warning Alarms ............................................................................................................................................................. 14

Danger Alarms .............................................................................................................................................................. 14

STEL Alarms 14
TWA Alarms 14

2.5 Other Alarms .......................................................................................................................................................... 14

2.5.1 Missing Sensor Alarms ....................................................................................................................................... 14

2.5.2 Sensor Overrange alarm..................................................................................................................................... 14

2.5.3 PID Lamp Out Alarm ........................................................................................................................................... 15

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2.5.4 O2 Too Low for LEL Alarms ................................................................................................................................ 15

2.5.5 Low Battery Alarms ............................................................................................................................................. 15

2.5.6 Calibration Due Warning ..................................................................................................................................... 15

2.5.7 Out of Temperature Range ................................................................................................................................. 15

2.6 PC Connection via Infrared Port ........................................................................................................................... 15

2.7 PID Sensor Correction Factors ............................................................................................................................. 16

2.7.1 Displa yed VOC ................................................................................................................................................... 16

2.7.2 Specified VOC Calibration Gas ........................................................................................................................... 16

2.8 Special Instructions for NDIR sensors ................................................................................................................. 16

2.8.1 Special Calibration Requirement for NDIR CO2 (Carbon Dioxide) Sensor .......................................................... 16

2.8.2 Special Consideration for IR CH4 Methane sensor gas calibration ..................................................................... 16

2.8.3 Hydrogen Warning for IR CH4 Methane Sensor ................................................................................................. 16

3. SAMPLING .......................................................................................................................................................................... 17

3.1 Manual sample draw kit ......................................................................................................................................... 17

3.1.1 Manual sample draw kit usage ........................................................................................................................... 17

3.2 Motorized sample draw pump ............................................................................................................................... 18

3.2.1 Starting the motorized sample pump .................................................................................................................. 18

3.2.2 Turning off the pump ........................................................................................................................................... 18

3.2.3 Pump low flow alarm ........................................................................................................................................... 18

3.3 Sample draw probe ................................................................................................................................................ 19

4. CALIBRATION...................................................................................................................................................................... 19

4.1 Functional (Bump) testing ..................................................................................................................................... 19

4.2 Fresh Air/Zero Calibration ..................................................................................................................................... 20

4.2.1 Fresh air calibration failure .................................................................................................................................. 20

Possible causes and solutions ...................................................................................................................................... 20

Recommended action: .................................................................................................................................................. 20

4.2.2 Forced fresh air calibration ................................................................................................................................. 20

4.2.3 Fresh air calibration in a contaminated atmosphere ........................................................................................... 21

4.3 Gas Calibration ....................................................................................................................................................... 21

4.3.1 Gas calibration failure: All sensors except oxygen .............................................................................................. 21

Possible causes of gas calibration failure and remedies: .............................................................................................. 21

4.3.2 Gas calibration failure: Oxygen sensors ............................................................................................................. 22

4.4 Special Calibration Instruction for NDIR CO2 sensor .......................................................................................... 22

4.4.1 CO2 Sensor True Zero ........................................................................................................................................ 22

4.5 Special Calibration Instructions for NDIR-CH4 Sensor ....................................................................................... 22

5. MENU OPTIONS................................................................................................................................................................... 23

5.1 Basic Menu ............................................................................................................................................................. 23

5.1.1 Entering the Basic Menu ..................................................................................................................................... 23

5.2 Main Menu ............................................................................................................................................................... 23

5.2.1 Entering the Main Menu ...................................................................................................................................... 24

5.2.2 Using the submenus ........................................................................................................................................... 24

5.2.3 Alarms Menu ....................................................................................................................................................... 24

5.2.4 Calibration Menu ................................................................................................................................................. 24

5.2.5 Configuration Menu............................................................................................................................................. 25

5.2.6 Screen Menu ...................................................................................................................................................... 25

5.2.7 Information Menu ................................................................................................................................................ 25

5.2.8 Datalogger Menu ................................................................................................................................................ 25

6. MAINTENANCE .................................................................................................................................................................... 26

6.1 Batteries .................................................................................................................................................................. 26

6.2 Replacing alkaline batteries .................................................................................................................................. 26

To replace the alkaline batteries:................................................................................................................................... 26

6.3 Maintaining Li-Ion battery packs .......................................................................................................................... 26

6.3.1 Storage guidelines for the Li-Ion battery ............................................................................................................. 26

6.3.2 Charging guidelines for Li-Ion battery ................................................................................................................. 26

6.3.3 Charging procedure for Li-Ion battery ................................................................................................................. 26

6.3.4 Charging with the pump attached ....................................................................................................................... 26

6.3.5 Battery troubleshooting ....................................................................................................................................... 27

6.4 Sensors ................................................................................................................................................................... 27

6.4.1 Sensor replacement ............................................................................................................................................ 27

6.4.2 Care and maintenance of PID sensors ............................................................................................................... 27

6.4.2.1 Troubleshooting the PID .......................................................................................................................... 27

6.4.2.2 Cleaning and replacing PID components ................................................................................................. 27

6.5 Sample probe assembly ........................................................................................................................................ 28

6.5.1 Changing sample probe filters ............................................................................................................................ 28

6.5.2 Changing sample probe tubes (wands) .............................................................................................................. 29

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6.6 PHD6 Pump Maintenance ...................................................................................................................................... 29

6.6.1 Replacing pump filters ........................................................................................................................................ 29

APPENDICES ................................................................................................................................................................................... 30

Appendix A Toxic gas measurement – Warning, Danger, STEL and TWA alarms .......................................................... 30

1. Warning and Danger Alarms ............................................................................................................................... 30

2. Time Weighted Average (TWA) .......................................................................................................................... 30

3. Short Term Exposure Limits (STEL) ................................................................................................................... 30

Appendix B Calibration Frequency Recommendation ....................................................................................................... 31

Appendix C PHD6 Sensor Information ................................................................................................................................ 32

Appendix D Electrochemical Toxic Sensor Cross-Sensitivity........................................................................................... 33

HONEYWELL ANALYTICS WARRANTY GAS DETECTION PRODUCTS .................................................................................................. 34

General 34

Instrument & Accessory Warranty Periods .......................................................................................................................... 34

Sensor Warranty Periods ....................................................................................................................................................... 34

Certification Information

The PHD6 carries the following certifications:

QPS Class I Division 1 Groups A,B,C,D Temp Code T3C (Approved to UL 913)
QPS Class II Division 1 Groups E,F,G (Approved to UL 913)
QPS Class III (Approved to UL 913)
CSA Class I, Division 1 Groups A,B,C,D Temp Code T3C
ONLY THE COMBUSTIBLE GAS DETECTION PORTION OF THIS INSTRUMENT HAS BEEN ASSESSED FOR

PERFORMANCE.
ATEX: Ex d ia IIC 170 °C (T3) Gb
IECEx: Ex d ia IIC 170 °C (T3) Gb
CE Mark
KTL 13-KB4BO-0218X1
UL 913, Seventh Edition
CSA C22.2 No. 0-M91, C22.2 No. 30-M1986, C22.2 No. 152-M1984, C22.2 No. 157-92
EN 60079-0:2012, EN 60079-11:2012
IEC 60079-0:2011, IEC 60079-11:2011

Operating Temperature and Humidity Limits

The PHD6’s operating temperature range is -20 °C to +50 °C. Use of Honeywell Gas Detectors outside of the
instrument’s specified operating temperature range may result in inaccurate and potentially dangerous readings.

Signal Words

The following signal words, as defined by ANSI Z535.4-1998, are used in the PHD6 Reference Manual.

indicates an imminently hazardous situation which, if not avoided, will result in death or serious injury.

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indicates a potentially hazardous situation which, if not avoided, could result in death or serious injury.

CAUTION used without the safety alert symbol indicates a potentially hazardous situation which, if not avoided, may result in
property damage.

indicat es a potentially hazardous situation, which if not avoided, may result in moderate or minor injury.

Warnings and Cautions

1. The PHD6 personal, portable gas detector has been designed for the detection of
dangerous atmospheric conditions. An alarm condition indicates the presence of a potentially life-threatening
hazard and should be taken very seriously. Failure to immediately leave the area may result in serious injury or
death.

2. In the event of an alarm condition it is important to follow established procedures. The
safest course of action is to immediately leave the affected area, and to return only after further testing
determines that the area is once again safe for entry. Failure to immediately leave the area may result in serious
injury or death.

3. The PHD6 must be located in a non-hazardous location whenever alkaline batteries are
removed from the alkaline battery pack. Removal of the alkaline batteries from the battery pack in a hazardous
area may impair intrinsic safety.

4. Use only Duracell MN1500 or Ultra MX1500, Eveready Energizer E91-LR6, Eveready EN91
batteries in the alkaline battery pack. Substitution of batteries may impair intrinsic safety.

5. To reduce the risk of explosion, do not mix old or used batteries with new batteries and do
not mix batteries from different manufacturers.

6. Do not charge the PHD6 with any charger other than the appropriate PHD6 charger.
Standard versions of the PHD6 must be charged with the UL/CSA-approved charger, which is part number 54­49-103-1. European versions of the PHD6 must be charged with the ATEX-approved charger, which is part
number 54-49-103-5.

7. The PHD6 must be located in a non-hazardous location during the charging cycle.
Charging the PHD6 in a hazardous location may impair intrinsic safety.

8. PHD6 rechargeable battery packs are supplied with Panasonic CGR18650D Lithium-Ion
batteries. The Li-Ion batteries in the battery packs may not be replaced by the user. The rechargeable pack
must be obtained from Honeywell Analytics and replaced as a complete assembly to maintain intrinsic safety.

9. The accuracy of the PHD6 should be checked periodically with known concentration
calibration gas. Failure to check accuracy can lead to inaccurate and potentially dangerous readings. (The
Canadian Standards Association (CSA) requires an accuracy check using known concentration calibration gas
prior to each day’s use.)

10. Fresh air/zero calibrations may only be performed in an atmosphere that is known to
contain 20.9% oxygen, 0.0% LEL and 0 PPM toxic gas.

11. The accuracy of the PHD6 should be checked immediately following any known exposure
to contaminants by testing with known concentration test gas before further use. Failure to check accuracy can
lead to inaccurate and potentially dangerous readings.

12. A sensor that cannot be calibrated or is found to be out of tolerance should be replaced
immediately. An instrument that fails calibration may not be used until testing with known concentration test
gas determines that accuracy has been restored, and the instrument is once again fit for use.

13. Do not reset the calibration gas concentration unless you are using a calibration gas
concentration that differs from the one that is normally supplied by Honeywell Analytics for use in calibrating
the PHD6.
Customers are strongly urged to use only Honeywell calibration materials when calibrating the PHD6. Use of
non-standard calibration gas and/or calibration kit components can lead to dangerously inaccurate readings
and may void the standard Honeywell Analytics warranty.

14. Use of non-standard calibration gas and/or calibration kit components when calibrating
the PHD6 can lead to inaccurate and potentially dangerous readings and may void the standard Honeywell
Analytics warranty.
Honeywell Analytics offers calibration kits and long-lasting cylinders of test gas specifically developed for easy

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PHD6 calibration. Customers are strongly urged to use only Honeywell calibration materials when calibrating
the PHD6.

15. Substitution of components may impair intrinsic safety.

16. For safety reasons this equipment must be operated and serviced by qualified personnel
only. Read and understand this reference manual before operating or servicing the PHD6.

17. A rapid up-scale reading followed by a declining or erratic reading may indicate a
hazardous combustible gas concentration that exceeds the PHD6’s zero to 100 percent LEL detection range.

18. The PHD6 is not designed for use in oxygen enriched atmospheres.

19. Do not use the PHD6 pump for prolonged periods in an atmosphere containing a
concentration of solvent or fuel that may be greater than 50% LEL.

20. Do not unplug the NDIR-CH4 or NDIR-CO2 sensors in an explosive atmosphere.
Unplugging IR sensors in an explosive atmosphere may impair intrinsic safety.

Avertissements et mises en garde

1. Le détecteur de gaz PHD6 personnel et portable a été conçu pour la détection de conditions
atmosphériques dangereuses. Un état d’alarme indique la présence d’un danger potentiel critique et doit être
pris très au sérieux. Ne pas quitter immédiatement la zone peut entraîner une blessure grave ou mortelle.

2. En cas d’alarme, il est important de suivre les procédures établies. La procédure la plus
sûre est de quitter immédiatement la zone affectée, et de n’y revenir qu’après des tests déterminant l’absence
de risque dans la zone. Ne pas quitter immédiatement la zone peut entraîner une blessure grave ou mortelle.

3. Le PHD6 doit être situé dans une zone non dangereuse à chaque fois que les piles alcalines
sont retirées du bloc-piles. L’extraction des piles alcalines du bloc-piles dans une zone dangereuse peut porter
atteinte à la sécurité intrinsèque.

4. Utilisez uniquement des piles Duracell MN1500 ou Ultra MX1500, Eveready Energizer E91­LR6, Eveready EN91 dans le bloc-piles alcalines. La substitution des piles peut compromettre la sécurité
intrinsèque.

5. Pour réduire le risque d’explosion, évitez de mélanger des piles vieilles ou usagées avec
des piles neuves ou de mélanger des piles de marques différentes.

6. Ne rechargez pas le PHD6 avec un chargeur autre que le chargeur PHD6 approprié. Des
versions standard du PHD6 doivent être chargées avec le chargeur approuvé par UL/CSA, qui est un Honeywell
référence 54-49-103-1. Les versions européennes du PHD6 doivent être chargées avec le chargeur approuvé par
ATEX, qui est un Honeywell référence 54-49-103-5.

7. Le PHD6 doit être placé dans un endroit non dangereux pendant la période de chargement.
Charger le PHD6 dans un endroit dangereux peut compromettre la sécurité intrinsèque.

8. Les blocs-piles rechargeables PHD6 sont fournis avec des piles au lithium-ion Panasoni c
CGR18650D. Les piles au Li-Ion dans les blocs-piles ne peuvent pas être remplacées par l’utilisateur. Le pack
rechargeable doit être obtenu auprès de Honeywell et remplacé dans son intégralité pour maintenir la sécurité
intrinsèque.

9. Vérifiez périodiquement la précision du PHD6 en utilisant un gaz d’étalonnage de
concentration connue. L’absence de vérification de la précision peut entraîner des relevés imprécis et
potentiellement dangereux. (L’Association Canadienne de Normalisation (CSA) préconise un contrôle de
précision avec du gaz d’étalonnage de concentration connue tous les jours, avant utilisation).

10. L’étalonnage air propre/zéro peut uniquement être exécuté dans une atmosphère contenant
20,9 % d’oxygène, 0,0 % de LIE et 0 PPM de gaz toxique.

11. La précision du PHD6 doit être vérifiée immédiatement à la suite de toute exposition
connue aux polluants en le testant à l’aide de gaz de test de concentration connue avant toute nouvelle
utilisation. L’absence de vérification de la précision peut générer des relevés imprécis et potentiellement
dangereux.

12. Un capteur qui ne peut être étalonné ou se trouve hors des limites de tolérance doit être
remplacé sans tarder. Un instrument dont l’étalonnage échoue ne peut être utilisé avant qu’un test avec des
gaz de concentration connue ait confirmé le retour de sa précision et l’état de bon fonctionnement de
l’instrument.

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13. Ne réinitialisez pas la concentr ation du gaz d’étalonnage à moins que vous n’utilisiez un
gaz d’étalonnage qui diffère de celui qui est normalement fourni par Honeywell pour l’étalonnage du PHD6.

Il est vivement recommandé aux clients de n’utiliser que du matériel Honeywell pour étalonner le PHD6.
L’utilisation d’un gaz d’étalonnage et/ou de pièces de kit d’étalonnage autres que ceux qui sont prescrits peut
générer des relevés imprécis dangereux et peut annuler la garantie standard de Honeywell.

14. L’utilisation d’un gaz d’étalonnage et/ou de pièces de kit d’étalonnage autres que ceux qui
sont prescrits pour étalonner le PHD6 peut générer des relevés imprécis ou potentiellement dangereux et
annuler la garantie standard de Honeywell.
Honeywell offre des kits d’étalonnage et des cylindres durables de gaz de test développés pour faciliter
l’étalonnage du PHD6. Il est vivement recommandé aux clients de n’utiliser que du matériel Honeywell pour
étalonner le PHD6.

15. La substitution des pièces peut compromettre la sécurité intrinsèque.

16. Pour des raisons de sécurité, cet appareil doit être utilisé et révisé par du personnel
qualifié uniquement. Prenez le temps de lire et de comprendre ce manuel de référence avant d’utiliser ou de
réparer le PHD6.

17. Un relevé en hausse rapide suivi d’une valeur irrégulière ou en baisse peut signaler une
concentration dangereuse de gaz combustible qui dépasse la plage de détection LIE de zéro à cent pour cent du
PHD6.

18. Le PHD6 n’a pas été conçu pour être utilisé dans des atmosphères enrichies en oxygène.

19. N’utilisez pas la pompe du PHD6 pendant des périodes prolongées dans une atmosphère
contenant une concentration de solvant ou de combustible supérieure à 50 % LIE.

20. Ne débranchez pas les capteurs NDIR-CH4 ou NDIR-CO2 dans une atmosphère explosive.
Débrancher les capteurs infrarouges dans une atmosphère explosive peut compromettre la sécurité
intrinsèque.

Conditions for Safe Use:

The ambient temperature range of the PhD6 (-20 °C ≤ T

The battery shall be recharged or changed exclusively outside of the hazardous area.

Docking stations and Charger models 54-54-103-X, PhD6 IQ6, Model 54-54-9000 are considered associated equipment and
are to be located outside of the hazardous area.

The warning markings regarding (1) proper use of alkaline batteries, (2) not changing alkaline batteries in the hazardous
location, and (3) not charging the rechargeable battery in the hazardous location have to be present on the name plate.

The measuring function according to Annex II, paragraph 1.5.5 of the ATEX directive is not a matter of the EC-Type
examination of the PhD6.

≤ +50 °C) deviates from the standard temperature range.

amb

Conditions pour une utilisation en toute sécurité:

La plage de températures ambiantes pour le PhD6 (- 20 °C ≤ T

La batterie devra être rechargée ou changée exclusivement en dehors de la zone dangereuse.

Les stations d'accueil et les modèles de chargeur 54-54-103-X, PhD6 IQ6, Model 54-54-9000 sont considérés comme des
équipements associés et doivent se trouver en dehors de la zone dangereuse.

Les marquages d'avertissement concernant (1) l'utilisation appropriée des piles alcalines, (2) le non remplacement des piles
alcalines dans la zone dangereuse et (3) le non chargement de la batterie rechargeable dans la zone dangereuse doivent être
présents sur la plaque signalétique.

La fonction de mesure conformément à l'annexe II, paragraphe 1.5.5 de la directive ATEX ne fait pas l'objet de l'examen de
type CE du PhD6.

≤ + 50 °C) dévie de la plage de températures standard.

amb

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Type of Hazard

Measurement unit

Oxygen (O2)

Percentage by volume

%/Vol CH4

(NDIR – CH4)

%/Vol CH4

(PID Sensor)

(0.1PPM)

(0.1PPM)

CO2 sensor

1. Description

The PHD6 is a multi-sensor gas detector that can be
configured to meet a wide variety of user requirements. This
chapter provides an overview of many of the features of the
PHD6. More detailed descriptions of the specific features of
the PHD6 are contained in the subsequent chapters of this
manual.

Note: The accuracy of the PHD6 must be verified by
calibration with known concentration test gas whenever
a change is made to the sensors installed in the
instrument.

Calibration procedures are discussed in detail in
Chapter 4.

The PHD6 can utilize a variety of sensor types to detect
atmospheric contaminants including electrochemical
sensors, PID (Photo Ionization Detector) sensors, NDIR
(Non-Dispersive Infra-Red Absorbance) sensors and
catalytic hot-bead LEL sensors.

Different measurement units are used depending on the gas
being measured.

1.1 Methods of sampling

The PHD6 may be used in either diffusion or sample-draw
mode. In either mode, the gas sample must reach the
sensors for the instrument to register a gas reading. The
sensors are located at the lower front of the instrument.

of obstruction. Blocked sensor ports can lead to
inaccurate and potentially dangerous readings.

In diffusion mode, the atmosphere being measured reaches
the sensors by diffusing through the sensor ports at the front
of the instrument. Normal air movements are enough to
carry the sample to the sensors. The sensors react quickly
to changes in the concentrations of the gases being
measured. Diffusion-style operation monitors only the
atmosphere that immediately surrounds the detector.

The PHD6 can also be used to sample remote locations with
its hand-aspirated sample-draw kit or with its motorized,
continuous sample draw pump. During remote sampling,
the gas sample is drawn into the sensor compartment
through the probe assembly and a length of tubing. Remote
sampling operations only monitor the atmosphere at the end
of the sample draw probe.

Use of the hand-aspirated sample draw kits is covered
in section 3.1.

Use of the motorized sample draw pump is covered in
section 3.2.

A detailed description of the PHD6 probe assembly is
given in section 6.5.

The sensor ports must be kept free

1.2 Multi-sensor capability

The PHD6 can be configured to simultaneously monitor
oxygen, combustible gases and vapors, volatile organic
compounds (VOCs), and a wide variety of toxic gases. All
sensors are replaceable in the field.

Calibration procedures are discussed in detail in Chapter 4.

Combustible gas (LEL
Sensor)

Hydrocarbon-specific
combustible gas sensor

Volatile Organic
Compounds (VOCs)

Toxic Gases (by
electrochemical sensor

Toxic Gas by NDIR –

Table 1.2. PHD6 Units of Measurement

Percentage of lower
explosive limit (%LEL) or

Percentage of lower
explosive limit (%LEL) or

Parts-per-million (PPM) or
tenths of a part-per-million

Parts-per-million (PPM) –
some sensors capable of
tenths of a part-per-million

%/Vol CO2

1.3 Calibration

The PHD6 detector features fully automatic fresh air and gas
calibration.

be checked periodically with known concentration
calibration gas. Failure to check accuracy can lead to
inaccurate and potentially dangerous readings. (The
Canadian Standards Association (CSA) requires an
accuracy check using known concentration calibration
gas prior to each day’s use.)

Calibration procedures are discussed in detail in
Chapter 4.

Recommended calibration frequency is discussed in
Appendix B.

The accuracy of the PHD6 should

1.4 Alarm logic

PHD6 gas alarms can be adjusted manually using the
PHD6’s built in menu functions, with BioTrak II software via
IrDA interface, or with the IQ Database Manager Program
through the IQ6 Dock. (See Chapter 6 for direct menu
programming instructions). Alarms may be set anywhere
within the nominal range of the specific sensor. When an
alarm set point is exceeded a loud audible alarm sounds,
and the bright red LED alarm lights flash.

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1.4.1 Atmospheric hazard alarms

been designed for the detection of deficiencies of
oxygen, accumulations of flammable gases and vapors,
and accumulations of specific toxic gases. An alarm
condition indicating the presence of one or more of
these potentially life-threatening hazards should be
taken very seriously. Failure to immediately leave the
area may result in serious injury or death.

it is important to follow established procedures. The
safest course of action is to immediately leave the
affected area, and to return only after further testing
determines that the area is once again safe for entry.
Failure to immediately leave the area may result in
serious injury or death.

by a declining or erratic reading may indicate a
hazardous combustible gas concentration that exceeds
the PHD6’s zero to 100 percent LEL detection range.
Failure to immediately leave the area may result in
serious injury or death.

The combustible gas alarms are activated when the reading
for combustible gases exceeds one of the alarm setpoints.
Combustible gas readings are typically given in terms of
percent of LEL (Lower Explosive Limit), but may also be
shown in terms of percent-by-volume methane (CH4). The
PHD6 includes Warning and Danger alarms for the both the
LEL sensor and the NDIR-CH4 sensor.

Two oxygen alarm set points have been provided; a low
alarm for oxygen deficiency and a high alarm for oxygen
enrichment.

Up to four alarm set points are provided for the PID sensor
and for each toxic gas sensor: Warning, Danger, STEL
(Short Term Exposure Limit) and TWA (Time Weighted
Average).

Appendix A discusses Warning, Danger, STEL and TWA
alarms.

PHD6 portable gas detectors have

In the event of an alarm condition

A rapid up-scale reading followed

1.4.2 Low battery alarms

The PHD6 includes multi-staged alarms for both the Li-Ion
and alkaline battery packs to let the user know that the
battery is running low.

For detailed information concerning the low battery
alarms, see section 2.5.5.

MX1500, Eveready Energizer E91-LR6, Eveready EN91
batteries. Substitution of batteries may impair intrinsic
safety.

Use only Duracell MN1500 or Ultra

1.4.3 Sensor over range alarms

The PHD6 will go into alarm if a sensor is exposed to a
concentration of gas that exceeds its established range. In
the case of an LEL or NDIR-CH4 sensor reading that
exceeds 100% LEL, the sensor channel will be automatically
disabled by the instrument and the instrument will remain in
constant alarm until it is turned off, brought to an area that is
known to be safe, and then turned back on. The display will

show a vertical arrow with two heads in place of the sensor
reading for any channel that has gone into over range alarm.

See section 2.5.2 for further details.

alarm the PHD6 must be turned off, brought to an area
that is known to be safe and then turned on again to
reset the alarm.

In the event of an LEL overrange

1.4.4 PID lamp out alarm

The PHD6 monitors the status of the PID lamp to ensure
that it is functioning properly. Alarms are generated if the
PHD6 determines that the lamp is out. See section 2.5.3 for
further details.

1.4.5 LEL response failure due to lack of
O

alarm

The PHD6 features automatic warning against LEL sensor
response failure due to lack of oxygen. See section 2.5.4 for
details.

2

1.4.6 Security beep/flash

The PHD6 includes a security beep function that is designed
to notify the user that the instrument is powered up and
running. Once enabled the PHD6 will emit a short audible
beep and give a short flash on the LED at a user-defined
interval .

The security beep/flash can be enabled manually through
the Main Menu (see chapter 5), with BioTrak II software or
through the IQ6 Dock.

1.4.7 Latching alarms

The PHD6’s alarms are self-resetting unless the alarm latch
is enabled. With the PHD6’s alarm latch enabled, the
audible and visible alarms will continue to sound after the
atmospheric hazard has cleared. To reset the alarms,
simply press the MODE button. If the alarm latch is disabled
and the alarm condition is no longer present, the instrument
will automatically return to normal operation, and the visible
and audible alarms cease without further input from the user.

Latching alarms can be enabled manually through the Main
Menu (see chapter 5), with BioTrak II software or through
the IQ6 Dock.

1.4.8 Fault detection

PHD6 software includes a number of additional alarms
designed to ensure the proper operation of the instrument.
When the PHD6 detects that an electronic fault or failure
condition has occurred, the proper audible and visible
alarms are activated and an explanatory message is
displayed.

Faults and other electronic safeguards are discussed in
detail in section 2.5.

potentially life threatening atmospheric conditions. Any
alarm condition should be taken seriously. The safest
course of action is to immediately leave the affected
area, and return only after further testing determines
that the area is once again safe for entry.

The PHD6 is designed to detect

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1.5 Other electronic safeguards

Several automatic programs prevent tampering and misuse
of the PHD6 by unauthorized persons. Each time the
detector is turned on, the PHD6 automatically tests the LED
alarm lights, audible alarm, internal memory and pump
status (if so equipped). The battery is monitored
continuously for proper voltage. The PHD6 also monitors
the connection of sensors that are currently installed. The
detection of any electronic faults causes the activation of the
audible and visible alarms and causes the display of the
appropriate explanatory message.

1.6 Sensors

The PHD6 can be configured to simultaneously monitor
oxygen, combustible gases and vapors, volatile organic
compounds (VOCs) and a number of toxic gases. The
sensor configuration of the PHD6 may be specified at the
time of purchase, or changed in the field by appropriately
trained personnel.

The PHD6 must be calibrated following any sensor
replacement.

Replacement sensor part numbers and sensor ranges
are given in Appendix C.

or is found to be out of tolerance must be replaced
immediately. An instrument that fails calibration may
not be used until testing with known concentration test
gas determines that accuracy has been restored, and
the instrument is once again fit for use.

Calibration procedures are discussed in detail in
Chapter 4.

A sensor that cannot be calibrated

1.6.1 Cross Sensitivity

Sensor cross-sensitivity figures are given in Appendix D.

The CO channel in the Duo-Tox sensor in the PHD6 may
exhibit high levels of cross sensitivity to organic vapors
(VOCs). For best performance in an atmosphere known to
contain VOCs, use a dedicated CO sensor.

1.7 Optional sample draw pump

A motorized sample-draw pump is available for the PHD6 for
situations requiring continuous "hands free" remote
monitoring.

draw pump (part number 54-54-102) is the only pump
that can be used with the PHD6.

The pump contains a pressure sensor that
detects restrictions in airflow caused by
water or other obstructions being drawn into
the unit and immediately acts to turn the
pump off in order to protect the sensors,
pump, and other PHD6 components from
damage.

Pump status is continuously monitored by
the PHD6 microcontroller. When the pump
is active and functioning properly, the
spinning pump icon is displayed in the

The PHD6 continuous sample

status bar at the bottom of the display. Low flow or other
pump fault conditions activate audible and visible alarms and
cause the display of the appropriate explanatory message.

1.7.1 Special precautions when using the PHD6 pump

The rubber material used in the PHD6 diaphragm pump is
susceptible to temporary compromise by exposure to high
levels of flammable fuel and solvent vapors. If the PHD6 is
being used to sample atmospheres that exceed 50% LEL,
test the pump frequently to ensure that pump function has
not been compromised.

To test the pump, block the end of the sampling line (probe)
inlet with a finger. The pump should quickly go into alarm,
which indicates proper function. If the pump fails to go into
alarm while the inlet is blocked, it is not working properly;
and the PHD6 may not be providing an accurate reading. If
the pump test fails, the safest course of action is to

immediately leave the affected area and to return only
after further testing with known, functional detection
equipment confirms that the area is once again safe for
entry.

for prolonged periods in conditions where the
concentration of solvent or fuel vapors may be greater
than 50% LEL.

Do not use the pump to sample

1.8 Data storage

The PHD6 includes a black box data recorder and an event
logger as standard features. A full datalogger is available as
an upgrade at any time.

1.8.1 Black box data recorder

A black box data recorder is a standard feature in the PHD6.
The “black box” is continually in operation whether the user
is aware of it or not. The black box stores important
information such as gas readings, turn-on times, turn-off
times, temperatures, battery conditions, the most recent
calibration date and settings, types of sensors currently
installed, sensor serial numbers, warranty expiration and
service due dates, and current alarm settings.

There is a finite amount of memory storage available in the
black box data recorder. Once the memory is “full”, the
PHD6 will begin to write the new data over the oldest data.
The black box data recorder will store a minimum of 63
hours of data in one-minute increments before it begins to
write new data over the oldest data. In this way, the newest
data is always conserved.

To extract the information from the black box data recorder,
the PHD6 must be returned to Honeywell Analytics. Once
the data is downloaded from the instrument, a report will be
generated. The unit and the report will then be returned to
the user. Simply call Honeywell Analytics’ Instrument
Service Department to obtain a return authorization number.
There is no charge for the downloading service, but the user
is responsible for any freight charges incurred.

The “black box” data recorder in the PHD6 can be upgraded
to a fully enabled datalogger at any time. All that is required
is the activation code that corresponds to the serial number
of the PHD6 and the PHD6 Upgrade Utility Program.

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1.8.2 Event logger

The event logger in the PHD6 stores data associated with
alarm conditions. Each (alarm) event includes the following
data for each of the installed sensors:

• Sensor type

• Max reading

• Average reading

• Start time

• End time

• Duration of the event.

The PHD6 stores the data from the 20 most recent alarm
events. Once 20 events have been stored, the PHD6 will
begin to systematically overwrite the data from the oldest
event in memory with data from new events. One event may
be a combination of different alarms occurring
simultaneously or in immediate succession. The event
logger may be downloaded using BioTrak II software. The
PC must be equipped with IrDA to provide a connection.

1.9 PHD6 design components

1. Case: The instrument is enclosed in a solid PC

(polycarbonate) case with TPE (rubber) overmold.

2. Front face: The front face of the instrument houses

the MODE button, navigation keys, LCD (liquid crystal
display), LED alarm lights, and audible alarm ports.

3. Display: A liquid crystal display (LCD) shows

readings, messages, and other information.

4. Alarm LEDs: Top, front and side-mounted LED (light

emitting diode) alarm lights provide a visual indication
of alarm state.

5. Infrared Port: The infrared port is located at the

bottom of the instrument and is used for
communication between the PHD6 and a PC.

6. On / Off "MODE" button: The large black push-

button on the front of the instrument is the "MODE"
button. The MODE button is used to turn the PHD6
on and off as well as to control most other operations,
including the initiation of the automatic calibration
adjustment.

7. Navigation Keys: The up and down navigation keys

are located between the MODE button and the
display.

8. Sensor compartment cover: The sensors are

located in a vented compartment at the bottom of the
instrument.

9. Audible alarm ports: Two cylindrical ports extending

through the front of the instrument on opposing sides
of the MODE button house the loud audible alarms.
The waterproof audible alarms seat directly to the
rubber inner-liner to protect the instrument against
leakage or exposure to liquids.

10. Battery pack: Two types of interchangeable battery

packs (rechargeable Lithium Ion (Li-Ion) and
disposable alkaline) are available for use. Li-Ion
battery packs are recharged with the pack installed on
the PHD6.

11. Battery charger connector: A water-resistant

connector at the bottom of the case assembly is used
to connect the PHD6 to the “drop in” style charger.

12. Battery Compartment / Clip: The battery inserts

from the back of the instrument. A sturdy clip
attached to the battery allows the user to wear the
PHD6 on a belt or other article of clothing.

1.10 PHD6 standard accessories

Standard accessories included with every PHD6 include
calibration adapter, additional tubing for use during
calibration, manual sample draw kit, reference manual and
quick reference card. The manual sample draw kit consists
of a sample draw / calibration adapter, squeeze bulb,
replacement sample probe filters, ten feet/three meters of
tubing and a sample probe.

Standard configurations of the PHD6 are delivered in a
cardboard box with cardboard inserts.

1.10.1 Alkaline PHD6 detectors

If the PHD6 has been purchased as an alkaline instrument,
the standard accessories include an alkaline battery pack
and a set of 3 disposable AA alkaline batteries.

1.10.2 Li-Ion PHD6 detectors

If the PHD6 has been purchased as a Li-Ion rechargeable
instrument, the standard accessories include Li-Ion battery
pack and a slip-in PHD6 charger.

1.11 PHD6 kits

PHD6 detectors may also be purchased as part of a
complete kit that includes calibration gas, fixed-flow
regulator and a hard-shell carrying case.

1.11.1 PHD6 Confined Space Kits

In addition to the standard accessories listed above,
Confined Space Kits also include calibration fittings, fixed­flow regulator with pressure gauge, and appropriate large
cylinder(s) of calibration gas in a foam-lined, waterproof
hard-shell carrying case.

1.11.2 PHD6 Value Packs

PHD6 Value Packs include an alkaline PHD6, all standard
accessories, calibration fittings, small cylinder of calibration
gas, and fixed flow regulator in a foam-lined non-waterproof
hard-shell carrying case.

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2. Basic Operations

The PHD6 is a three-button gas detector. Most day-to-day
functions are initiated solely with the MODE button. The
MODE button controls:

• Turning the PHD6 on and off

• Turning on the backlight

• Viewing the MAX, STEL and TWA reading screens

• Initiating the calibration sequence

2.1 Turning the PHD6 On

To turn the PHD6 on, press and hold the MODE button for
one second. The introduction screen is followed by a screen
showing a list of installed sensors and the sensor ports they
occupy. The PHD6 has 5 sensor ports, but can display
readings for as many as 6 distinct gases.

activated during the self-test. For details on start up
procedures for pump-equipped PHD6 instruments see
section 2.1.1 below.

The PHD6 will then display each installed sensor along with
any associated alarms levels.

→ →

The serial number will then be
shown. If the detector has a fully
enabled datalogger, the interval and
memory capacity will be shown.

The sampling interval is given in
minutes and seconds. The
datalogger samples continuously, so
the data stream must be broken into
intervals to be recorded. The
datalogging interval defines the frequency of the breaks in
the data stream. The capacity is the number of hours and
minutes it will take to completely fill the datalogger’s
memory. Once the memory is filled, the PHD6 will start to
write new data over the oldest data in order to conserve that
most recent data.

The sampling interval in the fully enabled datalogger may be
modified using BioTrak II Software, the IQ Systems or
manually through the Main Menu.

If the PHD6 is equipped with the
standard black box datalogger, it will
show Black Box.

In the PHD6, a one-minute sampling
interval will result in the ability to
store a minimum of 63 hours of
readings before the oldest data is
overwritten by new data. If fewer
than 5 sensors are used, the capacity
will increase.

As the instrument performs a basic
electronic self test, the date, time,
temperature and battery type will be
displayed. During the self-test, the
PHD6 performs a system memory
check and tests to see if a motorized
pump is attached to the instrument.
If a pump is detected, it will be briefly

For more information concerning atmospheric hazard
alarms, see section 2.4.

After the alarm screens, the PHD6 will show that “Starting
Session, Resetting Averages” followed by the calibrations
status screen. Whenever the PHD6 is turned on, it
automatically starts a new operating session and resets
STEL and TWA calculations. The MAX reading is also reset
for the new session.

If calibration is due and the calibration due warning is
enabled, the user will need to acknowledge the calibration
due status by pressing the MODE
button. Once the MODE button is
pressed, the PHD6 will continue to the
current gas readings screen and the
appropriate calibration due icons will
flash to remind the user that the
instrument is past due for calibration.
If calibration is not due, the number of
days until the next calibration will be
shown before the instrument
proceeds to the current gas readings screen.

→

→

2.1.1 Start up with pump

PHD6 instruments that are equipped with a built-in
motorized sample draw pump will have a slightly longer start
up sequence. After the calibration status screens, the PHD6
will prompt you to leak test the pump.

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See section 3.2 for further instructions on using the
PHD6 pump.

2.1.2 Start up with PID or IR sensor

When a PID or IR sensor is installed in
the PHD6, there will be a warm-up
period during which the hourglass icon
and either “PID” or “IR” will be shown. The
VOC gas type and reading are shown in
reverse text.

displayed during the sensor warm up period should not
be considered accurate. The use of the PHD6 to
monitor for compounds detected by the PID or IR
sensor during the warm up period may lead to
inaccurate and potentially dangerous readings.

PID and IR readings that are

2.2 Operating Logic

Once the PHD6 has completed the start up sequence, the
current gas readings screen will be shown. The status bar
at the bottom of the display shows time plus calibration,
pump and battery status.

To turn on the backlight press the MODE button once. To
view the peak readings screen, press the MODE button a
second time. Press the MODE button a third time to view
the Short Term Exposure Limit (STEL) and Time Weighted
Averages (TWA) for the operating session

Screens that are accessible with the MODE button (including
the Peak and STEL/TWA screens) are selectable by the
user. See section 5.2.6 for details.

Note: The PHD6 must be in continuous operation for at
least 15 minutes before it will be able to calculate STEL
or TWA values. For the first 15 minutes of any operating
session, the screen will show the length of time that the
instrument has been operating instead of the STEL and
TWA values.

→

2.2.1 Status Bar

The status bar at the bottom of the current gas readings
shows general information including:

• Battery Status

• Heartbeat (instrument status)

• Pump Status

• PID Hourglass (PID warmup period)

• PID Lamp Status (shows “Check Sen.”)

• Bump Due Warning

• Calibration Due Warning

• Time

Battery Status Icon

The battery status icon is located at the far lower left of the
screen. The battery icon gives an indication of how much
power is left in the battery.

When the battery icon is empty, it is considered
a low battery condition and the user should
take the appropriate steps to either recharge
the Li-Ion battery or replace the alkaline
batteries.

For more information on the low battery
alarms, see section 2.5.5.

IR Hourglass Symbol

The hourglass symbol along with IR are
shown in the status bar during the IR
sensor’s 1-minute warm-up period. Once the
warm-up period is over, the hourglass will no longer be
shown.

PID Hourglass Symbol

The hourglass symbol along with PID are shown in the
status bar during the PID sensor’s 5­minute warm-up period. Once the
warm-up period is over, the hourglass
will no longer be shown.

When a PHD6 is equipped with both an IR and a PID
sensor, the PID hourglass is shown since the PID sensor
takes longer to warm up than the IR sensor.

Heartbeat Symbol

When the instrument is properly charged,
calibrated and functioning normally, the
heartbeat symbol will flash in the status bar.

Pump Status Icon

If the pump is attached and functioning,
the moving fan icon will appear in the
status bar.

Calibration and Bump Due

Warnings

If the PHD6 is due for calibration the
calibration bottle icon and triangular
warning symbol will be flash in the status bar.

Time

The time is shown on the current gas
readings screen at the lower right.

2.2.2 Screen Flip

The screen orientation of the PHD6 may be flipped (so that it
can be read looking down from above instead of up from
below) by pressing the up and down arrows simultaneously
at the Current Gas Readings screen.

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2.3 Turning the PHD6 Off

To turn the PHD6 off, press and
hold the MODE button until the
display reads “Release MODE to
shut down”. Then release the
MODE button. The display will
briefly show “Shutting Down” and
“Saving Sensors” before the display
goes blank.

→

2.4 Atmospheric Hazard Alarms

The PHD6 is configured with a series of alarms that are
designed to warn the user of hazardous atmospheric
conditions.

potentially life threatening atmospheric conditions. Any
alarm condition should be taken seriously. The safest
course of action is to immediately leave the affected
area, and return only after further testing determines
that the area is once again safe for entry.

The PHD6 is designed to detect

2.4.1 O2 Alarms

The PHD6 is equipped with both high and low alarms for
oxygen. Fresh air contains 20.9% oxygen.

The low oxygen alarm indicates oxygen deficiency and is
normally set at 19.5% at the factory.

The high alarm indicates oxygen enrichment and is normally
set at 23.5% at the factory.

2.4.2 Combustible Gas Alarms

The PHD6 is equipped with a 2-stage alarm for
concentrations of combustible gas.

The default LEL warning alarm setting is 10% LEL. The
default LEL danger alarm setting is 20% LEL.

The default warning alarm for NDIR-CH4 sensors is 10%
LEL or 0.5%/vol CH4. The default danger alarm is 20% LEL
or 1.0%/vol CH4.

2.4.3 Toxic and VOC sensor alarms

The PHD6 is equipped with up to four different alarms for
toxic gases and volatile organic compounds (VOCs). The
combination of alarms is designed to protect the user from
both chronic and acute toxic hazards.

Current alarm settings are shown during the startup
sequence, and can also be accessed through the Alarms
Menu.

2.4.4 Alarm Descriptions

Warning Alarms

Warning alarms indicate a hazardous atmospheric condition
that has not yet risen to the level necessary to initi ate the
danger alarms.

Warning alarms can be temporarily silenced by pressing the
MODE button.

Danger Alarms

Danger alarms indicate a significantly hazardous condition.
The danger alarms cannot be silenced by the user.

STEL Alarms

STEL (Short Term Exposure Limit) alarm values represent
the average concentration of instrument readings for the
target gas for the most recently completed 15 minutes of
operation.

TWA Alar ms

TWA (Time Weighted Average) values are calculated by
taking the sum of exposure to a particular toxic gas in the
current operating session in terms of parts-per-million-hours
and dividing by an eight-hour period.

2.5 Other Alarms

The PHD6 will display warnings or error messages when it
detects problems during operation.

2.5.1 Missing Sensor Alarms

During startup, if the PHD6 fails to detect a sensor that was
present when the instrument was last turned off, it will show
the sensor channel with “None” and the triangular warning
symbol at the Loading Sensors screen.

Press MODE to acknowledge the missing sensor

If the PHD6 loses connection with a sensor during an
operating session, it will immediately go into
alarm and show an “X” in the space on the
display allotted for the sensor reading. The
PHD6 must be turned off to reset the
missing sensor alarm.

↔

2.5.2 Sensor Overrange alarm

The PHD6 will show a vertical double-headed arrow and go
into alarm if a sensor is exposed to a concentration of gas
that exceeds its established range. In the case of an LEL
reading that exceeds 100% LEL, the LEL
channel will be automatically disabled by the
instrument and the alarm will latch (remain
on) until the instrument is turned off. The
PHD6 must be turned off, brought to an area
that is known to be safe (containing 20.9% oxygen, 0% LEL
and 0 PPM toxic gases), and then turned back on. The
display will show a vertical arrow with two heads in place of

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the sensor reading for any channel that has gone into over
range alarm.

alarm indicates a potentially explosive atmosphere.
Failure to leave the area immediately may result in
serious injury or death!

alarm the PHD6 must be turned off, brought to an area
that is known to be safe (containing 20.9% oxygen, 0%
combustible gases and 0 PPM toxic gases), and then
turned on again to reset the alarm.

A combustible sensor overrange

In the event of an LEL overrange

2.5.3 PID Lamp Out Alarm

The PID sensor in the PHD6 uses a lamp to
ionize the gas sample and generate a
reading.

If the lamp fails to light during instrument
startup, the PHD6 will attempt to start it for the duration of
the warm-up cycle. If the lamp lights, the PHD6 will complete
the warm-up cycle and then enter standard operating mode.
If the lamp fails to light by the end of the 5-minute warm-up
cycle, the instrument will display an X in the PID channel
and the instrument will go into alarm. The status bar at the
bottom of the screen will also show “Check Sen.” to let the
user know that the PID sensor is not functioning.

The PHD6 also tests the lamp in the PID sensor at regular
intervals during normal operation. If the PHD6 determines
that the lamp has gone out, the X will appear on the display
in the PID channel, the instrument will go into alarm and the
status bar will show “Check Sen.”

2.5.4 O2 Too Low for LEL Alarms

The LEL sensor in the PHD6 requires a certain amount of
oxygen to function properly. When oxygen levels fall below
11% by volume, the PHD6 will show “X“ in place of the LEL
reading and will indicate the oxygen levels are too low.

2.5.5 Low Battery Alarms

When the battery icon in the LCD appears empty,
it means that a low battery condition exists.
Leave the area immediately.

If the PHD6 is equipped with an alkaline battery
pack, proceed to an area that is known to be safe
area (containing 20.9% oxygen, 0% combustible
gases and 0 PPM toxic gases) and change the
batteries.

non-hazardous location whenever alkaline batteries are
removed from the alkaline battery pack. Removal of the
alkaline batteries from the battery pack in a hazardous
area may impair intrinsic safety.

CAUTION Always turn the PHD6 off prior to removing
the battery pack. Removal of the battery pack with the
instrument turned on may cause corruption of stored
data in the PHD6.

The PHD6 must be located in a

If the PHD6 is equipped with a Li-Ion battery pack, proceed
to an area that is known to be safe and recharge the battery
pack.

If the PHD6 continues to be used during a low battery
condition, it will eventually go into a low battery alarm, and
the warning alarm will sound and the screen will display the
low battery warning. To silence the alarms, the user will
need to acknowledge the low battery condition by pressing
the MODE button before the instrument will resume
monitoring. Once the MODE button is pressed, the empty
battery cell and the caution icon will flash. After 5 minutes
the warning will sound again. This cycle will continue until
the battery reaches a “very low battery” condition, when the
instrument will go into alarm for the last time, notify the user
that it is shutting itself and proceed to turn itself off.

Alkaline battery replacement and Li-Ion battery charging
instructions are contained in sections 6.2 and 6.3.

non-hazardous location during the charging cycle.
Charging the PHD6 in a hazardous location may impair
intrinsic safety.

The PHD6 must be located in a

2.5.6 Calibration Due Warning

If the PHD6 is due for calibration, the
triangular warning symbol and span
bottle icons will flash in the status bar at
the bottom of the LCD once per second
as a reminder.

2.5.7 Out of Temperature Range

If the operating temperature falls outside of
the normal operating range of a sensor in
the PHD6, the instrument will go into alarm
and the thermometer icon will be shown on
the display at the sensor.

2.6 PC Connection via Infrared Port

PHD6 instruments that are equipped
with a fully enabled datalogger can be
downloaded to a PC using BioTrak II
or IQ software through the PHD6’s
infrared port. The IrDA port is located
on the bottom of the instrument
towards the back.

1. If the PHD6 is turned off, hold

the MODE button down for about 5 seconds until
“Communication Mode” is shown. If the PHD6 is on
already, proceed to step 2.

2. Align the infrared port on the

PHD6 with the PC’s infrared
port to complete the
connection.

Note: For further instructions
concerning the download
procedure for the PHD6, see the
BioTrak II or IQ System manual as
appropriate.

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2.7 PID Sensor Correction Factors

The PHD6 may be equipped with a PID (Photo Ionization
Detector) sensor designed to detect Volatile Organic
Compounds. The PID sensor employs an ultraviolet lamp to
ionize the VOCs in the sample. The detector is then able to
measure the level of the VOCs and generate a reading.

PID sensors are broadband in nature. This means that they
are inherently non-specific. Any gas or vapor that is ionized
at the UV lamp energy will give a response.

selection of a particular VOC or gas from the onboard
PID library in the PHD6 does not imply that the detector
will only respond to that material. It only means that the
sensitivity scale (and default alarms) has been set to
approximate the target material.

Regardless of the library material selected, the PID sensor
always remains broadband in nature and therefore will
respond to any gases/vapors in the ambient environment
that are present and are ionized at the UV lamp energy.
This consideration is particularly important when trace or
hard to detect materials (higher correction factor (CF) are
present in highly contaminated backgrounds. In this case
the PID would be a poor choice for detection of the target
gas/vapor.

onboard PID library for various, common VOCs and
gases should be considered as approximate. The PHD6
with PID has been fully tested and validated only for
performance with isobutylene.

For other materials requiring verified accuracy it is
necessary to calibrate the detector to the gas/vapor to be
monitored directly. Further if using remote sample draw
and/or physical conditions in the field that differ from
ambient, to perform calibrations as close to the physical and
actual setup conditions as possible.

The convention in the gas detection industry is to
calibrate the PID sensor to a known concentration of
isobutylene and (as required) to use response factors or
to select the scale of target gas from a pre-programmed
menu. Sensitivity scale is displayed on the channel with
7 character designation whether it is isobutylene or
another material.

It must be understood that the

Correction factors in the PHD6

2.7.1 Displayed VOC

To change the displayed VOC, first
enter the Basic Menu by holding the
MODE button to turn the PHD6 off.
When “Release MODE to Shut
Down” is shown, continue to hold
the MODE Button until the Basic
Menu is shown.

At the Basic Menu press the down
arrow once to select “Displayed
VOC”. A list of Volatile Organic Compounds will be shown.
Use the navigation arrows to highlight the appropriate VOC
and press MODE to select it. The new VOC will be shown
when the PHD6 is restarted.

2.7.2 Specified VOC Calibration Gas

To change the calibration gas for PID sensor, follow the
instruction in section 5.2.1 to reach the Main Menu. Then
access the Calibration Menu followed by the Gas Values
submenu. Once in the Gas Values submenu, select the
VOC sensor. Then select Cal Gas Type and specify the
appropriate compound and amount for calibration.

2.8 Special Instructions for NDIR sensors

Two NDIR sensors are available for the PHD6: One for the
detection of carbon dioxide (CO2), and one for the detection
of methane (CH4).

2.8.1 Special Calibration Requirement
for NDIR CO

(Carbon Dioxide)

2

Sensor

Unlike most sensors the Infrared CO2 sensor requires two
different gas sources to fully calibrate the instrument. The
reason for this is that it is effectively impossible to zero
calibrate a CO2 detector in ambient air because there is an
unknown and varying amount of background CO2 present in
the atmosphere.

See section 4.4 for more details.

2.8.2 Special Consideration for IR CH4 Methane sensor gas calibration

The NDIR-CH4 sensor is designed specifically for the
detection of methane. Gas calibration should always be
done with methane calibration gas at the actual amount of
methane shown on the cylinder. See section 4.5 for details.

2.8.3 Hydrogen Warning for IR CH4 Methane Sensor

Unlike other types of sensors used to measure combustible
gases and vapors, the IR CH4 sensor used in the PHD6
does not respond to hydrogen.

for the detection of hydrogen. Unlike catalytic hot-bead
LEL sensors, the NDIR CH4 sensor in the PHD6 does not
respond to hydrogen. Use the of the NDIR CH4 for the
detection hydrogen may lead to property damage,
personal injury or death.

Do not use the NDIR CH4 sensor

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Gas Type

Tubing Length

CL2, CLO

2

Up to 10 ft/3m Max.

HCN

Up to 100 ft/30m Max.

PH3, NH

3

3. Sampling

The PHD6 may be used in either
diffusion or sample-draw mode. In
either mode, the gas sample must
reach the sensors for the instrument to
register a gas reading. The sensors
are located on the front of the
instrument near the bottom in a vented
compartment.

ports must be kept free of
obstruction. Blocked sensor ports
can lead to inaccurate and
potentially dangerous readings.

In diffusion mode, the atmosphere being measured reaches
the sensors by diffusing through vents in the instrument.
Normal air movements are enough to carry the sample to
the sensors. The sensors react quickly to changes in the
concentrations of the gases being measured. Diffusion-style
operation monitors only the atmosphere that immediately
surrounds the detector.

The PHD6 can also be used to sample remote locations with
either the hand-aspirated sample-draw kit, or with the
motorized sample draw pump. During remote sampling, the
gas sample is drawn into the sensor compartment through
the probe assembly and a length of tubing.

sample draw kit that contains 10 feet/3 meters of
polyester urethane (fuel-resistant) tubing part number
53-001. This material is completely compatible with
common combustible gases/vapors, and the toxic gases
CO and H2S. When using the PHD6 with a sample draw
pump or kit to sample with any of the gas types and
tubing lengths listed in the chart below, FEP-Lined
Tubing (part number 53-036) should be used.

PID, SO2, NO, NO2,

Standard polyester urethane (fuel-resistant) tubing (part
number 53-001) can be used otherwise. Use of other
types of tubing may cause inaccurate and potentially
dangerous readings that could result in serious injury or
death.

For sampling using a PID sensor please refer to the
Application Note titled “Usage and Applications of PID
sensors version B1” included with your PhD
documentation or contact customer service at 800-711­6776 to request a copy.

for the detection of hydrogen. Unlike catalytic hot-bead
LEL sensors, the NDIR CH4 sensor in the PHD6 does not
respond to hydrogen. Use of the NDIR CH4 for the
detection of hydrogen may lead to property damage,
personal injury or even death.

The sensor

The PHD6 is delivered with a

> than 10 ft/3m up to 100
ft/30m Max.

Do not use the NDIR CH4 sensor

3.1 Manual sample d raw kit

The manual sample draw kit is comprised of a sample draw
probe, 2 sections of tubing, a squeeze bulb and an adapter
that is used to connect the sample draw accessories system
to the PHD6.

Note: The maximum amount of tubing that can be used
with the manual sample draw kit is 50 feet/15 meters.

3.1.1 Manual sample draw kit usage

PHD6’s manual sample draw
kit may not be used for the
detection of chlorine (Cl2) or
chlorine dioxide (ClO2) due to
the reactive properties of these
gases.

To use the manual sample draw
kit:

1. Connect the short section

of hose that comes off the
squeeze bulb to the sample draw adapter.

2. To test the seals in the sample draw system, cover

the end of the sample draw probe with a finger, and
squeeze the aspirator bulb. If there are no leaks in
the sample draw kit components, the bulb should stay
deflated for a few seconds.

3. Secure the calibration adapter (with the sample draw

assembly attached) to the PHD6 by inserting the tab
and tightening the knurled screw into the brass nut at
the bottom of the adapter.

4. Insert the end of the sample probe into the location to

be sampled.

5. Squeeze the aspirator bulb to draw the sample from

the remote location to the sensor compartment.

To ensure accurate readings while using the
manual sample draw kit, it is necessary to
squeeze the bulb once for every one foot of
sampling hose for the sample to first reach the
sensors, and then to continue squeezing the bulb
once per second for an additional 45 seconds or
until readings stabilize. As an example, if 10
feet/3 meters of tubing is used, it will be
necessary to draw the sample in by squeezing the
bulb continuously for a minimum of 55 seconds
or until readings stabilize.

6. Note the gas measurement readings.

CAUTION: Hand-aspirated remote sampling only
provides continuous gas readings for the area in which
the probe is located while the bulb is being
continuously squeezed. Each time a reading is desired,
it is necessary to squeeze the bulb a sufficient number
of times to bring a fresh sample to the sensor
compartment.

The

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3.2 Motorized sample draw pump

continuous sample draw pump (part

PHD6 for situations requiring continuous
"hands free" remote monitoring. The
pump is powered by the PHD6 battery.
When the pump is attached to the
instrument, the spinning fan icon will be
shown on the display in the current gas
readings screen.

Note: The maximum amount of tubing
that can be used with the motorized sample draw pump
is 100 feet/30 meters.

To ensure accurate readings while using the continuous
sample pump, it is necessary to allow the pump to draw
the sample for one second for every one foot of
sampling hose plus an additional 45 seconds or until
readings stabilize. For example, with 10 ft/3m of tubing,
it will be necessary to allow a minimum of 55 seconds
for the sample to be drawn into the sensor chamber and
for the readings to stabilize.

PHD6 instruments are designed to automatically recognize
the pump whenever it is attached to the instrument. If the
pump is attached when the PHD6 is turned off, the
instrument will automatically initiate the pump start up
sequence when the instrument is turned on. If the pump is
attached while the instrument is running, the PHD6 will
automatically initiate the pump test sequence before
returning to the current gas readings screen.

prolonged periods in an atmosphere containing a
concentration of solvent or fuel that may be greater than
50% LEL.

The PHD6

number 54-54-102) is the
only pump that can be
used with the PHD6.

A motorized sample-draw
pump is available for the

Do not use the PHD6 pump for

3.2.1 Starting the motorized sample pump

First attach the probe and tubing to the pump, then secure
the pump (with the sample draw assembly attached) to the
PHD6 by hooking the tabs on the pump into the
corresponding slots on the back of the PHD6. Once the
pump is in position over the sensors, tighten the knurled
screw on the adapter into receptor at the center of the
sensor cover.

Note: The sample probe assembly must be attached to
the pump when the pump is attached to the instrument.

Once the pump is recognized, the pump test sequence will
be initiated automatically. The instrument will instruct you to
block the sample inlet.

Block the sampling inlet by placing a finger over the end of
the sample probe assembly. Once the blockage is detected,
the PHD6 will indicate that the test has been passed and
instruct you to remove the blockage. Once the blockage is
removed, it will proceed to the current gas readings screen
and the pump icon will be shown in the status bar.

If the instrument is unable to detect the vacuum resulting
from the pump blockage within 30 seconds, the test will fail,
the instrument will go into alarm and you will be directed to
remove the pump.

Remove the pump and press the MODE button to resume
diffusion operation.

→

→

3.2.2 Turning off the pump

To turn off the pump, simply remove the pump from the
bottom of the instrument. The screen will show “Pump
Fault” followed by “Pump Disconnected”. Press MODE to
continue without the pump.

→

3.2.3 Pump low flow alarm

The PHD6 Pump contains a pressure sensor that
continuously monitors for restrictions in airflow caused by
water or other fluids being drawn into the unit and
immediately acts to turn the pump off in order to protect the
sensors, pump, and other PHD6 components from damage.

CAUTION: Never perform remote sampling w ith the
PHD6 without the sample probe assembly. The sample
probe handle contains replaceable filters designed to
block moisture and remove particulate contaminants. If
the pump is operated without the probe assembly in

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place, contaminants may cause damage to the pump,
sensors and internal components of the PHD6.

When the pump is active and functioning
properly, the moving pump icon is shown on
the lower status bar on the display. Low
flow or other pump fault conditions activate
audible and visible alarms and cause the
display of the appropriate explanatory message.

Press MODE once the blockage has been cleared to restart
the pump.

The pressure sensor in the sample draw pump is designed
to detect pressure changes while the sample-draw probe is
being held in a vertical position. If the probe is held
horizontally or at a low angle while inserted into a fluid, a
pressure drop sufficient to cause the pump to shut down
may not be generated, and water could be drawn into the
pump assembly causing damage to the pump, sensors and
internal components of the PHD6.

CAUTION: Insertion of the sample draw tube into a fluid
horizontally or at a low angle may lead to water ingress
and may cause damage to the sensors and internal
components of the PHD6.

If the PHD6 determines that a significant increase in
pressure has occurred, it will go into alarm and notify the
user that there is a blockage of the pump. The display will
alternate between the following two screens.

Remove the blockage and press the MODE button to
acknowledge the alarm and resume sampling.

→

3.3 Sample draw probe

The PHD6’s sample draw probe is the standard probe
assembly from Honeywell Analytics. The sample probe
handle contains moisture barrier and particulate filters
designed to remove contaminants that might otherwise harm
the instrument.

Particulate contaminants are removed by means of a
cellulose filter. The hydrophobic filter includes a Teflon
barrier which blocks the flow of moisture as well as any
remaining particulate contaminants.

Sample probe filters should be replaced whenever visibly
discolored due to contamination.

See section 6.5 for a probe diagram and a list of
available sample probe filter replacement kits.

4. Calibration

The accuracy of the PHD6 should be verified on a regular
basis. Verification can be as simple as performing a bump
test, which is described below in section 4.1. If the
instrument fails the fresh air test, then it must be fresh air
calibrated before use. If the instrument fails the bump test
with calibration gas, it must be successfully span calibrated
before use.

Note: The NDIR-CO2 sensor used in the PHD6 cannot be
zero calibrated in fresh air. For specific instructions on
calibrating the CO2 sensor, proceed to section 4.4.

Note: The NDIR-CH4 sensor used in the PHD6 must be
calibrated with methane calibration scale to the actual
amount of methane in the cylinder in terms of percent
volume methane. See section 4.5 for details.

* The Canadian Standards
Association (CSA) requires combustible gas sensors to
be bump tested prior to each day’s use with calibration
gas containing between 25% and 50% LEL. The
functional (bump) test procedure is covered in
section 4.1.

** The Canadian Standards
Association (CSA) requires combustible gas sensors to
undergo calibration when the displayed value during a
bump test fails to fall between 100% and 120% of the
expected value for the gas.

For Honeywell Analytics’ official recommendations
concerning calibration frequency, see Appendix B.

4.1 Functional (Bump) testing

The accuracy of the PHD6 may be verified at any time by a
simple functional (bump) test.

To perform a functional (bump) test, do the following:

1. Turn the PHD6 on and wait at least three minutes to
allow the readings to fully stabilize. If an IR or PID
sensor is in use, wait until the stabilization period
ends before proceeding. If any of the sensors have
just been replaced, the new sensor(s) must be
allowed to stabilize prior to use. See section 6.4 for
further details on sensor stabilization requirements.

2. Make sure the instrument is located in fresh air.

Figure 4.1 Bump Test / Gas calibration set up

3. Verify that the current gas readings match the
concentrations present in fresh air. The oxygen (O2)
sensor should read 20.9%/vol. (+/-0.2%/vol.). The

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readings for the LEL sensor should be 0% LEL. The
PID, NDIR-CH4 and toxic sensors should read 0
parts-per-million (PPM) in fresh air. For the NDIR­CO2 sensor, a carbon dioxide level between 0.03%
and 0.10% is considered normal in fresh air. If the
readings deviate from the expected levels in a fresh
air environment, proceed to section 4.2 and perform
the fresh air calibration adjustment then proceed to
step 4.

4. Attach the calibration adapter and connect the
calibration cylinder to the PHD6 as shown in
figure 4.1. Flow gas to the sensors.

5. Wait for the readings to stabilize. (Forty-five seconds
to one minute is usually sufficient.)

6. Note the readings. Toxic, VOC and combustible gas
sensor readings are considered accurate in a bump
test if they are between 90%* and 120% of the
expected reading as given on the calibration cylinder.
If the readings are considered accurate, then the
instrument may be used without further adjustment. If
the readings do not fall within 90%* and 120% of the
expected reading as given on the calibration cylinder,
then readings are considered inaccurate. If readings
are considered inaccurate, proceed to section 4.3 and
perform the gas calibration.

*Note: The Canadian Standards Association (CSA)
requires combustible gas sensors to undergo
calibration when the displayed value during a bump test
fails to fall between 100% and 120% of the expected
value for the gas.

Honeywell multi-calibration gas mixtures contain
approximately 18% oxygen. During the bump test the
oxygen sensor should read within +/-0.5% of the level given
on the calibration cylinder.

4.2 Fresh Air/Zero Calibration

Note: The NDIR-CO2 sensor in the PHD6 may not be
zero calibrated in fresh air. See section 4.4 for further
instructions.

only be performed in an atmosphere that is known to
contain 20.9% oxygen, 0.0% LEL and 0 PPM toxic gas.

To initiate the fresh air/zero calibration:

1. Press the MODE button three times within two
seconds to begin the fresh air/zero calibration
sequence. The PHD6 will briefly display AUTO CAL
and then begin a 5-second countdown.

2. Press the MODE button before the end of the 5­second countdown to begin the fresh air/zero
calibration. The fresh air/zero calibration is initiated
when the PHD6 shows “Calibrating” on the screen.

Fresh air/zero calibrations may

→

3. The PHD6 will indicate when the fresh air/zero
calibration is complete. It will then proceed to a
second 5-second countdown for the gas calibration.
If gas calibration is not required, allow the countdown
to reach 0 without pressing the MODE button.

For instructions on the Gas Calibration, proceed to
section 4.3.

→

4.2.1 Fresh air calibration failure

In the event of a fresh air calibration
failure, the alarms will be activated
and the instrument will display the
following screen. Note that the
sensor(s) that fail the zero calibration
are shown (in this case, CO).

After 3 seconds, the PHD6 will return
to the current gas readings screen
and the visual and audible alarms
will cease.

When calibration is due, the triangular warning symbol along
with the span bottle icon the PHD6’s status bar will show

If a successful fresh air calibration is not performed prior to
instrument shut down, the PHD6 will note that Fresh Air
Calibration is due during instrument start up.

Possible caus es an d sol utions

1. The atmosphere in which the instrument is located is
contaminated (or was contaminated at the time the
instrument was last fresh air calibrated.

2. A new sensor has just been installed.

3. Instrument has been dropped or banged since last
turned on.

4. There has been a significant change in temperature
since the instrument was last used.

Recommend ed ac tion:

Take the instrument to fresh air and allow readings to
stabilize. Perform the fresh air/zero adjustment again. If the
manual fresh air/zero procedure fails to correct the problem,
perform the manual fresh air / zero calibration procedure as
described in section 4.2.2 below.

4.2.2 Forced fresh air calibration

The PHD6 includes safeguards to prevent fresh air
calibration in contaminated environments. If the standard
fresh air calibration fails a second time, the instrument may
be “forced” to accept the fresh air calibration by performing
the manual fresh air calibration.

performed in an atmosphere that is known to contain

20.9% oxygen, 0.0% LEL and 0 PPM toxic gas.

Performing a fresh air calibration in a contaminated

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atmosphere may lead to inaccurate and potentially
dangerous readings.

1. Initiate the standard fresh air / zero calibration
sequence by pressing the MODE button three times
in rapid succession. The 5-second countdown will
begin.

2. Press and hold the down arrow key and then press
the MODE button before the end of the 5-second
countdown. Continue to hold the down arrow.

3. The fresh air/zero calibration is complete when the
instrument begins another 5-second countdown for
the gas calibration. If gas calibration is not required,
allow the countdown to reach 0 without pressing the
MODE button.

If the PHD6 still fails to calibrate after this procedure is
attempted, contact Honeywell Analytics.

4.2.3 Fresh air calibration in a

contaminated atmosphere

To fresh air calibrate the PHD6 in a contaminated
atmosphere, connect a cylinder of “zero air” containing

20.9% oxygen and no contaminants to the PHD6 and flow

gas to the instrument. Then perform the fresh air calibration.
See figure 4.1 above for setup.

4.3 Gas Calibration

Once the fresh air / zero calibration has been successfully
completed, the PHD6 will automatically proceed to the
automatic gas calibration countdown screen.

Press the MODE button before the countdown is complete to
initiate the gas calibration. The screen will immediately
show “APPLY GAS” and then list the sensors for calibration
and the expected levels of calibration gas.

Note: Honeywell Analytics
recommends the use of multi­component calibration g as for
calibrating the PHD6.

Apply calibration gas. The readout
will change to a numerical display
almost immediately and show the
current readings along with the
expected calibration gas value.

If multiple cylinders are required to
complete the calibration, the PHD6
will prompt the user to apply the next
cylinder as needed.

As sensors are calibrated, the PHD6
will briefly show the reserve values
for each sensor. The reserve values
give an indication of the remaining
sensitivity of the sensors. When the

→

reserve value for a specific sensor reaches 0%, it is time to
replace the sensor.

The oxygen sensor is tested for response to diminished
oxygen levels during gas calibration.
Honeywell multi-gas calibration
cylinders contain approximately

18.0% oxygen. In order to pass the
gas calibration, the PHD6 must
register an oxygen reading below

19.5% during gas calibration. If the
detector fails to register the reduced
oxygen levels during the gas
calibration, it will show “Check O2
Sensor Response”. Press MODE to acknowledge.

See section 4.3.2 below if the oxygen sensor does not
detect the drop in oxygen level and fails the gas
calibration.

Note: Disconnect the calibration assembly as soon as
the calibration is complete.

4.3.1 Gas calibration failure: All sensors except oxygen

When there is a gas calibration failure, the display will show
CAL Error and display the sensor whose calibration has
failed.

If the instrument fails to recognize the correct type or
concentration of calibration gas, it will show “no GAS”.

When gas calibration is due, the PHD6’s display will show
the warning symbol while intermittently displaying the
calibration bottle in the gas readings screen.

The PHD6 will also display a “Needs Cal” message for any
sensors that are currently due for calibration during
instrument start-up.

Possible causes of gas cal ibr a tion failure and

1. Empty calibration gas cylinder. Verify that there is

2. Expired calibration gas cylinder. Verify that the

3. Calibration gas setting does not correspond to

4. LEL only: Type of calibration gas (standard) has

5. Dead sensor. Replace sensor.

remedies:

calibration gas in the cylinder.

expiration date on the cylinder has not passed.

calibration gas concentration. If the values on the
calibration cylinder differ from the calibration gas
settings in the PHD6, the PHD6’s calibration gas
settings must be changed to match the new values.
Changing the calibration gas settings can be done
manually through the MODE button or through
BioTrak II using an IrDA link to the instrument.

changed significantly. LEL calibration gas may be
based on several different response standards.
Methane, propane and pentane are the most
common. If using a new cylinder of calibration gas,
make sure that the type and amount of combustible
gas is identical to that of the previous bottle.
Honeywell Analytics offers calibration gases in
Methane, Propane Equivalent and Pentane
Equivalent.

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6. Instrument problem. Return the instrument to
Honeywell Analytics. Call the phone number on the
front of this manual.

4.3.2 Gas calibration failure: Oxygen

sensors

Honeywell multi calibration gas
cylinders contains approximately

18.0% oxygen. The reduced oxygen

level in the calibration gas cylinder
allows the oxygen sensor’s response
to be tested in the same manner as
the toxic and LEL sensors.

If the O2 sensor fails to register a
reading below 19.5% during the gas
calibration, the display will show
“Check O2 Sensor Response”. Press MODE to continue.

If the oxygen sensor fails to register the drop in oxygen
during the gas calibration while being challenged with
calibration gas containing less than 19.0% oxygen, it should
be considered out of tolerance and retired from service
immediately.

See section 5.2.4 under Gas Values for more information
on the O2 sensor check.

or is found to be out of tolerance should be replaced
immediately. An instrument that fails calibration may
not be used until testing with known concentration test
gas determines that accuracy has been restored, and
the instrument is once again fit for use.

Possible causes and remedies for oxygen sensor
failure:

1. Calibration gas cylinder does not contain a reduced
level of oxygen. Verify that the cylinder contains less
than 19.0% oxygen.
To challenge the oxygen sensor without calibration
gas, hold your breath for about 10 seconds and then
slowly exhale directly onto the face of the sensor (in
the same way you would attempt to fog up a piece of
glass). If the descending oxygen alarm is set to

19.5%, the instrument should go into alarm after a
few seconds. If the oxygen sensor fails to go into
alarm during the exhalation test, the oxygen sensor
must be replaced.

2. Oxygen sensor has just been replaced and has not
had time to stabilize.

3. Oxygen sensor failure.

A sensor that cannot be calibrated

4.4 Special Calibration Instruction for

NDIR CO

The Infrared CO2 sensor requires two different gas sources
for full calibration. The reason for this is that it is effectively
impossible to zero calibrate a CO2 sensor in ambient air
because there is an unknown and varying amount of
background CO2 present in the atmosphere.

sensor

2

4.4.1 CO2 Sensor True Zero

To determine if the CO2 sensor requires zero calibration,
connect the PHD6 to a cylinder of calibration gas that

contains 0.00% CO2 while the instrument is in normal
operation.

If the reading shows 0.00% CO2, then the CO2 sensor does
not require zero calibration. Disconnect the cylinder from
the PHD6.

If the reading shows anything other than 0.00% CO2, leave
the calibration gas on and press the MODE button three
times within two seconds to initiate the zero calibration
sequence. Press MODE again when prompted to begin the
zero calibration. Instruments equipped with a CO2 sensor
will automatically show the message “Press MODE if
applying Zero Air” with another 5-second countdown. Press
MODE again to begin the true zero calibration and follow the
instructions given on the screen. Once the zero calibration
is complete, remove the zero air cylinder from the instrument
and proceed to the gas calibration (if necessary).

The gas calibration of the CO2 sensor is performed during
the standard gas calibration that is described above in
section 4.3. The PHD6 will automatically prompt the user to
apply the CO2 calibration gas during the standard gas
calibration sequence.

4.5 Special Calibration Instructions f or
NDIR-CH

In many ways, the NDIR-CH4 sensor used in the PHD6 is
similar to a hot bead LEL sensor. For the purpose of
calibration, they are very different. While LEL sensors can
be calibrated with a number of other gases when properly
configured, The NDIR-CH4 sensor must be calibrated with
methane to the exact amount shown on the calibration gas
cylinder. (This is different from LEL sensors, where
methane may be used for calibration, but is often done at a
scale that makes the readings mimic those given by a
specific amount of propane or pentane).

must be calibrated using methane (CH4) calibration gas
at the actual amount shown on the cylinder. The default
calibration gas value for the NDIR-CH4 sensor is 50%
LEL. The appropriate calibration gas level for the 50%
LEL default calibration gas setting is 2.50%/vol. CH4.
Use of inappropriate calibration gas may lead to
inaccurate and potentially dangerous readings.

Sensor

4

The NDIR CH4 sensor in the PHD6

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5. Menu Options

The PHD6 operating firmware includes two menu options:
the Basic Menu and the Main Menu.

5.1 Basic Menu

The Basic Menu is a shortened version of the Main Menu
that offers immediate access to a few key functions
including:

• PID On/Off (enable or disable the PID sensor)

• Displayed VOC (select the target compound for the

VOC sensor)

• Contrast (display’s light vs. dark setting)

• Main Menu access

5.1.1 Entering the Basic Menu

To access the Basic Menu, with the PHD6 on and the
current gas readings screen shown, hold the MODE button
down until the PHD6 beeps four times and the “Release
MODE to Shut Down” is shown. Then continue to hold the
MODE Button until the Basic Menu is shown.

To navigate through the menu options, use the up and down
navigation arrows to highlight the desired submenu and
press MODE to enter the submenu.

5.2 Main Menu

The PHD6 is fully configurable through the Main Menu. The
Main Menu contains 6 sub menus that lead toontrols for the
individual instrument functions.

To navigate through the menu options, use the up and down
navigation arrows to highlight the desired submenu and
press MODE to enter the submenu.

To navigate through the menu options, use the up and down
navigation arrows to highlight the desired submenu and
press MODE to enter the submenu.

Main Menu Options Diagram

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5.2.1 Entering the Main Menu

There are two paths into the main
menu.

If the instrument is on, press and hold
the MODE button down for three
seconds until “Shutting Down” is
shown, then release the MODE
button. The next screen will show
“shutting down…” along with two black
blocks at the bottom of the screen.
Press and hold the two arrow keys
while the two blocks are shown to enter the main menu.

If the instrument is off, press the MODE button to start the
instrument. When “Starting Session, Resetting Averages” is
shown along with two black blocks,
press and hold the two arrow keys
while the two blocks are shown to
enter the main menu.

The Main Menu is the access point to
6 submenus that control virtually every
aspect of the PHD6’s functionality.

NOTE: Changes made in the Main
Menu can have a direct affect on
the PHD6’s functionality and should only be made by
those who are trained in proper gas detection and
monitoring techniques.

5.2.2 Using the submenus

In the Main Menu and the sub-menus, use the up and down
arrows to navigate between the options and press MODE to
enter. Three buttons will appear on the display to show the
functions of the MODE button and the two navigation keys
on any screen that allows instrument setup changes.

5.2.3 Alarms Menu

The Alarms Menu contains the following 6 submenus
(options in parenthesis). Description follows (as needed).

• Current Alarms (select any sensor to view current

sensor alarm settings, then select any current sensor
alarm to make changes)

• Default Alarms (scroll to view default sensor alarms

for each recognized sensor plus option to Set Default
Alarms for all sensors

• Alarm Latch (set on or off)

The PHD6’s alarms are self-resetting unless the
alarm latch is enabled. With the PHD6’s alarm latch
enabled, the audible and visible alarms will continue
to sound after the atmospheric hazard has cleared.
Press the MODE button to reset the alarms. If the
alarm latch is disabled and the alarm condition is no
longer present, the instrument will automatically
return to normal operation, and the visible and audible
alarms cease without further input from the user.

• Temp Alarms (enable or disable high and low

temperature alarms)
If the operating temperature falls outside of the
operating range of the PHD6, the instrument will go
into alarm and the thermometer icon will be shown on
the display.

• Event History (use up and down arrows to scroll

through saved alarm events – includes time, duration

and peak and average sensor readings during the
event)

• Vibrator (if equipped) (enable or disable the vibrating

alar m)

5.2.4 Calibration Menu

• Fresh Air Cal (initiates Fresh Air Calibration

sequence)

only be performed in an atmosphere that is known to
contain 20.9% oxygen, 0.0% LEL and 0 PPM toxic gas.

• Gas Calibration (initiates Gas Calibration sequence

(calibration gas required)

• O2 Gas Cal (initiates true O2 Zero Calibration

sequence)

Note that this procedure requires a cylinder of
calibration gas that contains 0.0% oxygen.

• Gas Values (select any sensor to view or change

current calibration gas values).

Note: The selection of the calibration gas for the PID
sensor is NOT linked to the displayed substance. A
ratio is used to calculate readings for various VOCs
against the calibration standard. See section 2.7 for
more details on the PID gas values.

Note: In the case of the oxygen sensor, the O2 gas
setting can be used to enable or disable the oxygen
sensor check that takes place during gas calibration
with multi calibration gas. To disable the oxygen sensor
check, select “No”.

the oxygen sensor check may
result in the failure to recognize
an oxygen-deficient atmosphere.

Always use a multi cal gas
cylinder containing 18% oxygen
to calibrate the PHD6.

• Reminders/Lock (access to

submenus below)

• Cal on Startup (enable or disable)

When enabled, calibration is automatically initiated
whenever the instrument is turned on. The calibration
can be bypassed (unless Cal Due Lock is enabled) by
letting the clock run out and proceeding to the current
gas readings screen. Cal on Startup is usually
disabled on new instruments and must be enabled by
the user.

• Cal Reminder: (adjust between every day and every

180 days). The default setting for standard
instruments leaving the factory is 30 days.
To disable the cal reminder, set the value to 0.

• Cal Lock: (enable or disable)

Enable to require calibration when the Cal Reminder
is on. PHD6 automatically shuts down if Cal Lock is
enabled, and calibration is due but not performed.
Cal Lock is usually disabled on new instruments and
must be enabled by the user.

• Bump Reminder: (enable, disable and adjust

between every day and every 30 days)
Used exclusively with the IQ6 Dock. Reminds the

Fresh air/zero calibrations may

Disabling

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user to process the instrument in the dock. To
disable set the value to 0. The Bump Reminder is
usually disabled on new instruments and must be
enabled by the user.

• Service Interval (enable, disable and adjust between

every day and every 730 days (2 years)
The service interval is a reminder that tells the user
when the instrument is due for service. The Service
Interval is usually disabled on new instruments and
must be enabled by the user.

• Service Done (reset service date)

Used to reset the service interval following instrument
service.

• Cal History (scroll through recent calibrations,

includes span reserve listing – which allows for
predictive maintenance).

5.2.5 Configuration Menu

• Security Beep (enable or disable)

Once enabled the PHD6 will emit a short audible
beep and give a short flash on the LEDs at a user­defined interval to notify the user that the instrument
is powered up and running. The Security Beep is
usually disabled on new instruments and must be
enabled by the owner.

• Basic Passcode (enable, disable and change

passcode)
Enable to require the entry of a passcode to access
the Basic Menu. The Basic Passcode is usually
disabled on new instruments and must be enabled by
the owner. To permit access to the Basic Menu, and
restrict it from the Main Menu, the Basic Passcode
must differ from the Main Passcode.

• Main Passcode (enable, disable and change

passcode)
Enable to require the entry of a passcode to enter the
Main Menu. The Main Passcode is usually disabled
on new instruments and must be enabled by the
owner. The Main Passcode can be used to enter
both the Main Menu and the Basic Menu.

• Display Formats (contains submenus for sensor

readings, sensor clamping and temperature)

• Sensor readings (for toxic gases select PPM (XX) or

tenths-of-a-PPM (X.X) for sensors with this capability
(such as H2S). For NDIR-CH4 choose between LEL
and CH4 (the CH4 reading will display in %/Vol.)
Sensors that cannot be adjusted will show “Fixed”.

• Temperature (s elect display in Celsius or Fahrenheit)

Most PHDs leave the factory configured to read
temperature in Fahrenheit unless the customer
requests otherwise.

• Language (select English, French or Spanish). Most

PHDs leave the factory configured in English unless
the customer requests otherwise.

• Date/Time (set time and date)

5.2.6 Screen Menu

• Contrast (screen contrast setting)

• Orientation (shifts display to be viewable from top or

bottom of the instrument)

• Backlight Mode (select continuous, Timed Off or

Time Auto)
Select Continuous to have the backlight on at all
time s.
Select Timed Off to require a MODE press or an
alarm condition to activate the backlight. The default
setting for most new PHD6 instruments when leaving
the factory is to turn the backlight off after
20 seconds.
Select Time Aut o to enable the automatic backlight
for low light conditions.

• Backlight Time (set the time before the backlight

turns off in Time Off Mode).

• Enable Screens (select the screens that are

accessible by sequentially pressing the MODE button
including: Peak, Average, STEL and TWA screens.

5.2.7 Information Menu

• Versions (view instrument serial number, software

version, and time and date of instrument
manufacture)

• Service Info (view Honeywell Analytics’ phone

contact numbers).

5.2.8 Datalogger Menu

• Interval (set datalogger interval between 1 second

and 1 hour) (menu option only not available in Black
Box Datalogger versions)
The datalogger samples continuously, so the data
stream must be broken into intervals to be recorded.
The datalogging interval defines the frequency of the
breaks in the data stream. The interval may be set
anywhere between one second and one hour by
using the navigation arrows as detailed below. The
default datalogging interval is 1 minute. At a one­minute interval, the PHD6 will log a minimum of 63
hours of data before the oldest data is overwritten by
newer data.

• Sessions (view datalogger session data including

date, time, interval, temperature and sensor minimum
and maximum readings)

• Clear Datalog (clears all information from the

datalogger)

• Select User (User name will be saved in the session

data)
Users’ names must be entered in BioTrak II to appear
in the user list.

• Select Location (Location name will be saved in the

session data)
Location names must be entered in BioTrak II to
appear in the location list.

• User on Startup (enable or disable a prompt to

select user and location at startup)
User and location names must be entered into the
instrument via BioTrak II before this option can be
enabled.

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6. Maintenance

or combustible atmospheres, disconnect power before
servicing any parts in the PHD6.

6.1 Batteries

The PHD6 is powered by
interchangeable alkaline and Li-Ion
rechargeable battery packs.

To remove the battery pack first
loosen the top center screw on the
back of the instrument, then gently
pull the top of the battery away
from the instrument. The battery is
hinged from below. Remove the
battery once the top clears the
upper housing by pulling up and
away.

CAUTION Always turn the PHD6 off prior to removing
the battery pack. Removal of the battery pack with the
instrument turned on may cause corruption of stored
data in the PHD6.

Note: Center screw on ATEX / European version may be
slightly different.

6.2 Replacing alkaline batteries

The alkaline battery pack contains three AA alkaline
batteries.

non-hazardous location whenever alkaline batteries are
removed from the alkaline battery pack. Removal of the
alkaline batteries from the battery pack in a hazardous
area may impair intrinsic safety.

MX1500, Eveready Energizer E91-LR6, Eveready EN91
batteries. Substitution of batteries may impair intrinsic
safety.

To replace the alkaline batteries:

1. Remove the battery pack from the PHD6 as
discussed in above in section 6.1.

2. Loosen the two screws at the top of the battery pack
by turning each ¼ turn counterclockwise.

3. Remove the three alkaline batteries and replace
them. Be sure to align the positive and negative ends
in accordance with the
diagram under each
battery.

4. Reinstall the back
cover plate that was
removed in step 2.

5. Return the battery pack
to the PHD6 and re-tighten the top center screw. The
PHD6 will automatically turn itself on once the battery
pack is reinstalled.

To prevent ignition of flam m able

The PHD6 must be located in a

Use only Duracell MN1500 or Ultra

6.3 Maintaining Li-Ion battery packs

The PHD6 may be equipped with a rechargeable Li-Ion
(Lithium Ion) battery pack.

6.3.1 Storage guidelines for the Li-Ion battery

Never store Li-Ion -version PHD6 instruments at
temperatures above 30 degrees Celsius (86 degrees
Fahrenheit). Li-Ion batteries may suffer deterioration
resulting in damage to the internal components when stored
at high temperatures. The battery may be irretrievably
damaged resulting in reduced battery capacity and voltage.

Honeywell Analytics recommends leaving PHD6 instruments
with Li-Ion rechargeable batteries on the charger when not in
use.

6.3.2 Charging guidelines for Li-Ion battery

The Li-Ion battery in the PHD6 should never be charged at
temperatures lower than 5 degrees Celsius (40 degrees
Fahrenheit) or higher than 30 degrees Celsius (86 degrees
Fahrenheit. Charging at temperature extremes can
permanently damage the PHD6 Li-Ion battery.

non-hazardous location during the charging cycle.
Charging the PHD6 in a hazardous location may impair
intrinsic safety.

The PHD6 must be located in a

6.3.3 Charging procedure for Li-Ion battery

charger other than the appropriate PHD6 charger
manufactured by Honeywell Analytics. Standard
versions of the PHD6 must be charged with the UL/CSA­approved charger, which is part number 54-54-001.
European versions of the PHD6 must be charged with
the ATEX-approved PHD6 charger.

1. Verify that the instrument is turned off. (If it is not,

press the MODE button for three seconds until the
message "Release Button" appears.)

2. Plug the power supply in. The red LED is labeled

“Power” and will be lit whenever the charger is
plugged into a power source.

3. Insert the PHD6 into the charging cradle bottom side

down with the display facing forward. The green LED
on the charger is labeled “Charge” and will blink while
the battery is charging.

4. When the battery is fully charged, the green “Charge”

LED will be lit and not blinking.

See section 5.3.4 for battery troubleshooting guidelines.

Do not charge the PHD6 with any

6.3.4 Charging with the pump attached

The PHD6 with pump attached may be charged according to
the instruction given in section 6.3.3 above.

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Sensor

Stabilization Period

Oxygen (O2)

1 hour

LEL

none

PID

5 minutes

NDIR-CO

2

All Toxic Sensors except NO

15 minutes

NO (nitric oxide)

24 hours

6.3.5 Battery troubleshooting

If the green “Charge” LED on the charger fails to light when
the PHD6 with Li-Ion battery pack is placed in the charger,
remove the instrument from the charger and press the
MODE button to attempt to start the instrument.

If the battery has been inserted into the charger without the
instrument, return it to the instrument prior to attempting the
restart.

1. If the PHD6 starts and the battery icon if full, then the
battery is fully charged and may be used as is. In this
case, the charger has recognized that the battery is
charged and will not charge it any further.

2. If the PHD6 fails to turn on, then the battery may be
severely discharged and should be returned to the
charger. The charger will then begin a very slow
recharge in order to protect the battery. The green
“Charge” LED may not be lit during the first four hours
of the slow recharge. If the “Charge” LED has still not
been lit after four hours, the battery pack or charger is
probably damaged.

3. If the PHD6 starts and any battery level other than full
is indicated, then either the battery is damaged or the
charger is damaged. Call Honeywell Analytics for
further instructions.

6.4 Sensors

6.4.1 Sensor replacement

The sensors in the PHD6 are located in a vented
compartment at the bottom of the instrument.

To install a sensor:

1. Turn the PHD6 off.

2. Remove the battery pack as described in section 6.1.
This will automatically disconnect power from the
instrument.

3. Remove the four screws that are located below the
battery pack insertion from the back face of the
PHD6.

4. Turn the instrument over to reveal the front face and
gently remove the sensor cover.

5. Remove the sensor that is to be replaced.

6. Insert the new sensor into the appropriate location on
the sensor board.

7. Reinstall the sensor cover by aligning it properly over
the sensors and securing it with the four screws that
were removed in step 3.

8. Reattach the battery pack and re-tighten the top
center screw.

9. New sensors must be allowed to stabilize prior to use
according to the following schedule. The detector
must be powered off and a functional battery pack
must be installed for the sensor to stabilize.

NDIR-CH4 or

Note: Steps 9 and 10 assume that the sensor
stabilization period has passed.

10. Perform the Fresh Air/Zero calibration and the Gas
calibration as discussed in sections 4.2 and 4.3.

1 minute

6.4.2 Care and maintenance of PID

sensors

The two critical components of
a PID sensor are the electrode
stack and the lamp. The
electrode stack can be
replaced in the field. The lamp
can be cleaned or replaced in
the field. The frequency of
maintenance to both items will vary with the type of usage
and the nature of the contaminants to which the sensor is
exposed.

As a general rule, baseline shifts tend to be caused by the
electrode stack and losses of sensitivity tend to be caused
by the lamp.

6.4.2.1 Troubleshooting the PID

When to replace the electrode stack:

1. Baseline reading climbs following fresh air zeroing of
the sensor.

2. PID sensor becomes sensitive to humidity.

3. Baseline becomes generally unstable.

4. Baseline shifts when the instrument is in motion.

When to clean the PID lamp

Loss of sensitivity in the sensors as shown during bump­testing (reading will be low).

When to replace the PID lamp

If the cleaning of the lamp fails to correct a loss of sensitivity,
the lamp should be replaced.

6.4.2.2 Cleaning and replacing PID

To remove the lamp and stack

1. Wash your hands thoroughly.

2. On a clean surface, remove the PID sensor from the

3. Place one finger on top of the sensor and insert the

components

PHD6 as described above (section 6.4.1 steps 1-5).

stack removal tool into the two slots at the top side of
the sensor body. Squeeze gently until the spring
releases and the stack can be removed from the top
of the sensor. The lamp is spring-loaded against the
stack, so keeping a finger on top of the stack prevents
their ejection from the sensor body.

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4. Gently remove the stack and pull the lamp and spring
out of the sensor body. Do not touch the top of the
lamp window with bare fingers.

5. Set the spring aside.

To replace the stack or lamp

1. Discard the used lamp, stack or both as needed and
rebuild with replacement part(s).

2. Drop the spring into the center of the sensor body.

3. When reinserting the lamp and electrode stack, it is
essential to make sure that the lamp is fit snugly into
the o-ring slot on the electrode stack – NOTE
PICTURE BELOW. When inserting the lamp into the
o-ring slot, it is recommended that a twisting motion is
used. When properly assembled, the lamp should
then be flush against the stack, and should be fully
supported.

4. Snap the stack with lamp attached on to the sensor
body so that the sensor is whole again and the stack
cannot be removed without the removal tool.

5. The sensor should have a gasket and a filter on it. If
necessary, install a sensor filter and gasket on top of
the sensor.

6. Reinstall the sensor into the PHD6.

7. Reassemble the PHD6.

8. Calibrate the PID prior to use after the 5 minute warm
up periods ends.

To clean the lamp

1. Follow the directions above to remove the lamp from
the instrument.

2. Make sure your hands are clean.

3. Coat the cotton swab in a thin layer of lamp cleaning
powder of 0.1 to 0.25 µm α-alumina.

4. Pick up the lamp with the other hand. Do not touch
the top of the lamp window with bare fingers.

5. Using the cotton swab dipped in the cleaning powder,
polish the top of the lamp with a swirling motion.
Cleaning typically takes about 30 seconds and is
finished when the swab starts to squeak.

6. Reassemble the sensor and the PHD6. See steps 2­8 above in the directions to replace the stack or lamp.

6.5 Sample probe assembly

The PHD6’s sample draw probe is the standard probe
assembly from Honeywell Analytics. The illustration below
gives a breakdown of all parts in the sample draw probe with
part numbers. The sample probe handle contains moisture
barrier and particulate filters designed to remove
contaminants that might otherwise harm the instrument.

Sample probe filters should be replaced whenever
visibly discolored due to contamination.

CAUTION: Never perform remote sampling without the
sample probe and hose assembly. The sample probe
handle contains replaceable filters designed to block
moisture and remove particulate contaminants. If the
pump is operated without the probe assembly in place,
contaminants may cause damage to the pump, sensors
and internal components of the PHD6.

Particulate contaminants are removed by means of a
cellulose filter. The hydrophobic filter includes a Teflon
barrier which blocks the flow of moisture as well as any
remaining particulate contaminants.

6.5.1 Changing sample probe filters

The threaded sample probe handle is accesses the filters.
The particulate filter is held in place by means of a clear filter
cup. To replace the particulate filter, remove the old filter
and cup, insert a new filter into the cup, and slide the cup
back into place in the probe handle. The hydrophobic
barrier filter fits into a socket in the rear section of the probe
handle. (The narrow end of the hydrophobic barrier filter is
inserted towards the rear of the handle.)

To avoid accidentally introducing particulate contaminants
into the system, turn the sample probe upside-down prior to
removing either the hydrophobic filter or the particulate filter.

The following replacement filter kits are currently available
from Honeywell Analytics:

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culate

phobic

54-05-K0401

Standard

10

3

54-05-K0402

Economy

10

0

54-05-K0403

Economy

30

10

54-05-K0404

Bulk 0 25

54-05-K0405

Bulk

100

0

Part No. Kit

#Parti-

#Hydro-

6.5.2 Changing sample probe tubes

(wands)

The standard 11.5” long butyrate probe tube is held in place
with a hex-nut compression fitting and compression sleeve.
The standard probe tube can be interchanged with other
custom length sections of 1/4” OD tubing, or probe tubes
made of other materials (such as stainless steel).

Probe tubes are exchanged by loosening the hex-nut
compression fitting, removing the old tube, sliding the
compression sleeve into place around the new tube,
inserting the new tube into the probe handle, then replacing
and tightening the hex-nut.

Note: The sample probe must be checked for leakage
(as discussed in Section 3.1.1) whenever filters or probe
tubes are exchanged or replaced before being returned
to service.

6.6 PHD6 Pump Maintenance

PHD6 pumps are fairly maintenance free with the exception
of the replacement of the pump filters on a regular basis.

6.6.1 Replacing pump filters

1. Remove the two screws that hold the inlet port to the
pump.

2. Gently pull the dust filter holder free of the pump.

3. Remove and replace the dust filter that is located in
the holder.

4. The hydrophobic filter is located beneath the inlet port
in the pump housing. Use a small screwdriver or
other object to punch through the filter and remove it.
The gasket that sits between the inlet port and the
filter should come out with the filter.

5. Place the new hydrophobic filter with the filter side
down in place of the one removed in step 4. The
gasket should be located on top of the filter and
should sit against the dust filter holder, which will be
reinstalled in step 6.

6. Replace the dust filter holder (which now has a new
filter in it) and secure it with the two screws removed
in step 1.

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Time History Graph

Ceiling

Time History Graph

Ceiling

TWA

(8 hour)

Time History Graph

Ceiling

STEL

TWA

15 Minutes

Appendices

Appendix A Toxic gas measurement – Warning, Danger, STEL and TWA alarms

Many toxic substances are commonly encountered in
industry. The presence of toxic substances may be due to
materials being stored or used, the work being performed,
or may be generated by natural processes. Exposure to
toxic substances can produce disease, bodily injury, or death
in unprotected workers.

It is important to determine the amounts of any toxic
materials potentially present in the workplace. The amounts
of toxic materials potentially present will affect the
procedures and personal protective equipment that must be
used. The safest course of action is to eliminate or
permanently control hazards through engineering, workplace
controls, ventilation, or other safety procedures.
Unprotected workers may not be exposed to levels of toxic
contaminants that exceed Permissible Exposure Limit (PEL)
concentrations. Ongoing monitoring is necessary to insure
that exposure levels have not changed in a way that requires
the use of different or more rigorous procedures or
equipment.

Airborne toxic substances are typically classified on the
basis of their ability to produce physiological effects on
exposed workers. Toxic substances tend to produce
symptoms in two time frames.

Higher levels of exposure tend to produce immediate (acute)
effects, while lower levels of long-term (chronic) exposure
may not produce physiological symptoms for years.

Hydrogen sulfide (H2S) is a good example of an acutely toxic
substance which is immediately lethal at relatively low
concentrations. Exposure to a 1,000 ppm (parts per million)
concentration of H2S in air produces rapid paralysis of the
respiratory system, cardiac arrest, and death within minutes.

Carbon monoxide (CO) is a good example of a chronically
toxic gas. Carbon monoxide bonds to the hemoglobin
molecules in red blood cells. Red blood cells contaminated
with CO are unable to transport oxygen. Although very high
concentrations of carbon monoxide may be acutely toxic,
and lead to immediate respiratory arrest or death, it is the
long term physiological effects due to chronic exposure at
lower levels that take the greatest toll of affected workers.
This is the situation with regards to smokers, parking garage
attendants, or others chronically exposed to carbon
monoxide in the workplace. Exposure levels are too low to
produce immediate symptoms, but small repeated doses
reduce the oxygen carrying capacity of the blood over time
to dangerously low levels. This partial impairment of the
blood supply may lead over time to serious physiological
consequences.

Because prudent monitoring programs must take both time
frames into account, there are two independent exposure
measurements and alarm types built into the PHD6 design.

1. Warning and Danger Alarms

OSHA has assigned some, but not all, toxic substances with
a ceiling level which represents the highest concentration of
a toxic substance to which an unprotected worker should
ever be exposed, even for a very short time. The default
Warning and Danger alarm levels in the PHD6 are less than

or equal to the OSHA-assigned ceiling levels for both CO
and H2S.

Never enter an environment even momentarily when
concentrations of toxic substances exceed the level of
either the Warning or the Danger Alarm.

2. Time Weighted Average (TWA)

The maximum average concentration to which an
unprotected worker may be exposed over an eight hour
working day is called the Time Weighted Average or TWA
value. TWA values are calculated by taking the sum of
exposure to a particular toxic gas in the current operating
session in terms of parts-per-million-hours and dividing by an
eight-hour period.

3. Short Term Exposure Limits (STEL)

Toxic substances may have short term exposure limits which
are higher than the eight hour TWA. The STEL is the
maximum average concentration to which an unprotected
worker may be exposed in any fifteen minute interval during
the day. During this time, neither the eight hour TWA or the
ceiling concentration may be exceeded.

Any fifteen minute periods in which the average STEL
concentration exceeds the permissible eight hour TWA must
be separated from each other by at least one hour. A
maximum of four of these periods are allowed per eight hour
shift.

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Verify accuracy frequently!

Appendix B Calibration Frequency Recommendation

One of the most common questions
that we are asked at Honeywell
Analytics is: “How often should I

calibrate my gas detector?”

Sensor Reliability and Accuracy

Today’s sensors are designed to
provide years of reliable service. In
fact, many sensors are designed so
that with normal use they will only lose
5% of their sensitivity per year or 10%
over a two-year period. Given this, it
should be possible to use a sensor for
up to two full years without significant
loss of sensitivity.

Verification of Accuracy

With so many reasons why a sensor
can lose sensitivity and given the fact
that dependable sensors can be key to
survival in a hazardous environment,
frequent verification of sensor
performance is paramount.

There is only one sure way to verify
that a sensor can respond to the gas
for which it is designed. That is to
expose it to a known concentration of
target gas and compare the reading
with the concentration of the gas. This
is referred to as a “bump” test. This
test is very simple and takes only a few
seconds to accomplish. The safest

course of action is to do a “bump”
test prior to each day’s use. It is not

necessary to make a calibration
adjustment if the readings fall between
90%* and 120% of the expected value.
As an example, if a CO sensor is
checked using a gas concentration of
50 PPM it is not necessary to perform
a calibration unless the readings are
either below 45 PPM or above 60
PPM.

*The Canadian Standards
Association (CSA) requires the
instrument to undergo calibration
when the displayed value during a
bump test fails to fall between 100%
and 120% of the expected value for
the gas.

Lengthening the Intervals between
Verification of Accuracy

We are often asked whether there are
any circumstances in which the period
between accuracy checks may be
lengthened.

Honeywell Analytics is not the only
manufacturer to be asked this
question! One of the professional
organizations to which Honeywell

Analytics belongs is the Industrial
Safety Equipment Association (ISEA).
The “Instrument Products” group of this
organization has been very active in
developing a protocol to clarify the
minimum conditions under which the
interval between accuracy checks may
be lengthened.

A number of leading gas detection
equipment manufacturers have
participated in the development of the
ISEA guidelines concerning calibration
frequency. Honeywell Analytics
procedures closely follow these
guidelines.

If your operating procedures do not
permit daily checking of the sensors,
Honeywell Analytics recommends the
following procedure to establish a safe
and prudent accuracy check schedule
for your Honeywell instruments:

1. During a period of initial use of
at least 10 days in the intended
atmosphere, check the sensor
response daily to be sure there
is nothing in the atmosphere
that is poisoning the sensor(s).
The period of initial use must be
of sufficient duration to ensure
that the sensors are exposed to
all conditions that might have an
adverse effect on the sensors.

2. If these tests demonstrate that it
is not necessary to make
adjustments, the time between
checks may be lengthened. The
interval between accuracy
checking should not exceed 30
days.

3. When the interval has been
extended the toxic and
combustible gas sensors should
be replaced immediately upon
warranty expiration. This will
minimize the risk of failure
during the interval between
sensor checks.

4. The history of the instrument
response between verifications
should be kept. Any conditions,
incidents, experiences, or
exposure to contaminants that
might have an adverse effect on
the calibration state of the
sensors should trigger
immediate re-verification of
accuracy before further use.

5. Any changes in the environment
in which the instrument is being
used, or changes in the work

that is being performed, should
trigger a resumption of daily
checking.

6. If there is any doubt at any time
as to the accuracy of the
sensors, verify the accuracy of
the sensors by exposing them to
known concentration test gas
before further use.

Gas detectors used for the detection of
oxygen deficiencies, flammable gases
and vapors, or toxic contaminants must
be maintained and operated properly
to do the job they were designed to do.
Always follow the guidelines provided
by the manufacturer for any gas
detection equipment you use!

If there is any doubt regarding your gas
detector's accuracy, do an accuracy
check! All it takes is a few moments to
verify whether or not your instruments
are safe to use.

One Button Auto Calibration

While it is only necessary to do a
“bump” test to ensure that the sensors
are working properly, all current gas
detectors offer a one-button auto
calibration feature. This feature allows
you to calibrate a Honeywell gas
detector in about the same time as it
takes to complete a “bump” test. The
use of automatic bump test and
calibration stations can further simplify
the tasks, while automatically
maintaining records.

Don't take a chance with your life.

Please read also Honeywell Analytics’
application note: AN20010808 “Use of
‘equivalent’ calibration gas mixtures”.
This application note provides
procedures to ensure safe calibration
of LEL sensors that are subject to
silicone poisoning.

31

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Part No.

Description

Range

Resolution

54-54-80

LEL Combustible Gas

0 – 100% LEL

1% LEL

54-54-90

O

2

Oxygen

0 – 30% by Volume

0.1%

54-54-01

CO Carbon Monoxide

0 – 1000 PPM

1 PPM

54-54-19

CO-H CO Minus, reduced sensitivity to H

2

0 – 1000 PPM

1 PPM

H2S)

54-54-02

H2S Hydrogen Sulfide

0 – 200 PPM

1 PPM

H2S

54-54-03

SO2 Sulfur dioxide

0 – 25 PPM

0.1 PPM

54-54-21

NH3 Ammonia

0 – 100 PPM

1 PPM

54-54-18

Cl

2

Chlorine (specific)

0 – 50 PPM

0.1 PPM

54-54-20

ClO

2

Chlorine dioxide (specific)

0 – 5 PPM

0.01 PPM

54-54-06

NO

Nitric oxide

0 – 350 PPM

1 PPM

54-54-09

NO

2

Nitrogen dioxide

0 – 50 PPM

0.1 PPM

54-54-23

HCN Hydrogen cyanide

0 – 100 PPM

0.2 PPM

54-54-13

PH

3

Phosphine

0 – 20 PPM

0.1 PPM

54-54-50

NDIR CO2 Carbon dioxide

0 – 5.00%/vol.

0.025%*

54-54-51

NDIR CH4 Methane

0 – 5.00%/vol.

0.05%

54-54-52

PID

Volatile Organic Compound (VOCs)

0 – 3000 PPM

0.1 PPM

Appendix C PHD6 Sensor Information

54-54-05

54-54-14

*The CO2 sensor has an internal resolution of 0.025% but displays readings rounded to the nearest 0.01%. It will, therefore,
display steps of 0.03%, 0.05%, 0.08%, 0.10%, etc.

CO+ CO Plus dual purpose CO / H2S

Duo-Tox Dual Channel CO/H2S

(Provides a non-specific readout for CO and

Provides substance specific readouts for CO &

CO: 0 – 1000 PPM

H2S: 0 – 200 PPM

CO: 0 – 1000 PPM

H2S: 0 – 200 PPM

1 PPM

1 PPM

1 PPM

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SENSOR

CO

H2S

SO2

NO

NO2

Cl2

ClO2

H2

HCN

HCl

NH3

C2H4

C2H2

(CO)

(CO+)

(CO-H)

(H2S)

(SO2)

(NO2)

Nitric Oxide (NO)

0.1

≤15

≤10

100

≤30

15

n/d

0.1

n/d

n/d

n/d

n/d

n/d

(specific)

(non-specific)

(ClO2) (specific)

specific)

Ammonia (NH3)

<1

<10 2 n/d 0 0

n/d 0 0 0 100 0 0

Phosphine (PH3)

0.5

25

20

n/d

(-)

(-)

(-)

0.1

n/d

n/d

n/d 1 0.5

54-54-10)

54-54-23)

Appendix D Electrochemical Toxic Sensor Cross-Sensitivity

The table below provides the cross-sensitivity response of the PHD6 electrochemical toxic gas sensors to common interference
gases. The values are expressed as a percentage of the primary sensitivity, or the reading of the sensor when exposed to
100ppm of the interfering gas at 20ºC. These values are approximate. The actual values depend on the age and condition of the
sensor. Sensors should always be calibrated to the primary gas type. Cross-sensitive gases should not be used as sensor
calibration surrogates without the express written consent of Honeywell Analytics.

Carbon Monoxide

Carbon Monoxide

Carbon Monoxide

Hydrogen Sulfide

Sulfur Dioxide

Nitrogen Dioxide

Chlorine (Cl2)

Chlorine (Cl2)

Chlorine Dioxide

Chlorine Dioxide
(ClO

) (non-

2

Hydrogen Cyanide
(HCN) (old style

Hydrogen Cyanide
(HCN) (new style

** Sensor manufacturer rates Cross Sensitivity for (54-54-23) HCN sensor to H2S as follows for 20 PPM exposure at 20°C:
“Short gas exposure in minute range; after filter saturation: ca. 40 PPM reading”.

n/d = no data

100 10 5 10 -15 -5 -15 50 15 3 0 75 250

100 350 50 30 -60 -60 -120 50 n/d n/d 0 75 250

100 2 0.5 3 -0.5 -0.5 -1.5 5 n/d n/d 0.1 35 (+)

0.5 100 20 2 -20 -20 -60 0.2 0 0 0 n/d n/d

1 0 100 <8 -100 -70 -150 0.2 n/d n/d <0.1 15 100

<0.1 -40 -2.5 <0.5 100 100 270 <0.1 n/d n/d <0.1 n/d 0.1

0 -3 <1 n/d 12 100 20 0 0 0 0 0 0

0 -20 <5 0 120 100 300 0 n/d n/d 0 n/d n/d

0 -25 -5 n/d n/d 60 100 0 0 0 n/ d 0 0

0 -7 <2 0 40 <35 100 0 n/d n/d 0 n/d n/d

0.5 200 100 -5 -70 -50 -150 0 100 65 -5 0 n/d

0 0** n/d n/d -70 n/d n/d 0 100 n/d n/d n/d n/d

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PHD6

2 years from date of purchase

ToxiPr o®, MultiPro

replacement

Duo-Tox

All Other Sensors

1 Year

All Others

All Sensors

1 Year

Honeywell Analytics Warranty Gas Detection Products

General

Honeywell Analytics warrants gas detectors, sensors and accessories manufactured and sold by Honeywell Analytics, to be free
from defects in materials and workmanship for the periods listed in the tables below.

Damages to any Honeywell Analytics products that result from abuse, alteration, power fluctuations including surges and
lightning strikes, incorrect voltage settings, incorrect batteries, or repair procedures not made in accordance with the Instrument’s
Reference Manual are not covered by the Honeywell Analytics warranty.

The obligation of Honeywell Analytics under this warranty is limited to the repair or replacement of components deemed by the
Honeywell Analytics Instrument Service Department to have been defective under the scope of this standard warranty. To
receive consideration for warranty repair or replacement procedures, products must be returned with transportation and shipping
charges prepaid to Honeywell Analytics, or to a Honeywell Analytics Authorized Warranty Service Center. It is necessary to
obtain a return authorization number from Honeywell Analytics prior to shipment.

THIS WARRANTY IS EXPRE SSLY IN LIEU OF ANY AND ALL OTHER WARRANTIES AND REPRESENTATI ONS, EXPRESS
OR IMPLIED, INCLUDING BUT NOT LIMITED TO, THE WARRANTY OF FITNESS FOR A PARTICULAR PURPOSE.
HONEYWELL ANALYTICS WILL NOT BE LIABLE FOR LOSS OR DAMAGE OF ANY KIND CONNECTED TO THE USE OF
ITS PRODUCTS OR FAILURE OF ITS PRODUCTS TO FUNCTION OR OPERATE PROPE RLY.

Instrument & Accessory Warranty Periods

Battery packs and chargers, sampling pumps and other
components, which by their design are consumed or depleted
during normal operation, or which may require periodic



2 years from date of purchase

One year from the date of purchase

Sensor Warranty Periods

PHD6, Cannonball3, Multi Vision, MultiPro, Toxi Vision,

®

ToxiPr o

** Damage to combustible gas sensors by acute or chronic exposure to known sensor poisons such as volatile lead
(aviation gasoline additive), hydride gases such as phosphine, and volatile silicone gases emitted from silicone
caulks/sealants, silicone rubber molded products, laboratory glassware greases, spray lubricants, heat transfer fluids,
waxes & polishing compounds (neat or spray aerosols), mold release agents for plastics injection molding operations,
waterproofing formulations, vinyl & leather preservatives, and hand lotions which may contain ingredients listed as
cyclomethicone, dimethicone and polymethicone (at the discretion of Honeywell Analytics’ Instrument Service
department) void Honeywell Analytics’ Standard Warranty as it applies to the replacement of combustible gas sensors.

O2, LEL**, CO, CO+, H2S &

2 Years

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