Rosemount Manual: Oxymitter 5000 O2 Transmitter Hazardous Area with FOUNDATION Fieldbus Communications-Rev 1.2 | Rosemount Manuals & Guides

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Instruction Manual

IB-106-350C Rev. 1.2 January 2002

Oxymitter 5000

Hazardous Area Oxygen Transmitter with Foundation Fieldbus Communications

Certified to: CENELEC EEx d IIB T2/T6

CSA NRTL/C Class I, Division 1, Groups C, D T2/T6

http://www.processanalytic.com

ESSENTIAL INSTRUCTIONS

READ THIS PAGE BEFORE PROCEEDING!

Rosemount Analytical designs, manufactures and tests its products to meet many national and international standards. Because these instruments are sophisticated technical products, you MUST properly install, use, and maintain them to ensure they continue to operate within their normal specifications. The following instructions MUST be adhered to and integrated into your safety program when installing, using, and maintaining Rosemount Analytical products. Failure to follow the proper instructions may cause any one of the following situations to occur: Loss of life; personal injury; property damage; damage to this instrument; and warranty invalidation.

• Read all instructions prior to installing, operating, and servicing the product.

• If you do not understand any of the instructions, contact your Rosemount Analytical repre-

sentative for clarification.

• Follow all warnings, cautions, and instructions marked on and supplied with the product.

• Inform and educate your personnel in the proper installation, operation, and mainte-

nance of the product.

• Install your equipment as specified in the Installation Instructions of the appropriate In- struction Manual and per applicable local and national codes. Connect all products to the

proper electrical and pressure sources.

• To ensure proper performance, use qualified personnel to install, operate, update, program, and maintain the product.

• When replacement parts are required, ensure that qualified people use replacement parts specified by Rosemount. Unauthorized parts and procedures can affect the product’s performance, place the safe operation of your process at risk, and VOID YOUR WARRANTY. Look-alike substitutions may result in fire, electrical hazards, or improper operation.

• Ensure that all equipment doors are closed and protective covers are in place, except when maintenance is being performed by qualified persons, to prevent electrical shock and personal injury.

The information contained in this document is subject to change without notice.

If a Model 275 Universal HART® Communicator is used with this unit, the software within the Model 275 may require modification. If a software modification is required, please contact your local Fisher-Rosemount Service Group or National Response Center at 1800-433-6076 or 1-888-433-6829.

Emerson Process Management

Rosemount Analytical Inc. Process Analytic Division

1201 N. Main St. Orrville, OH 44667-0901 T (330) 682-9010 F (330) 684-4434 e-mail: gas.csc@EmersonProcess.com

http://www.processanalytic.com

HIGHLIGHTS OF CHANGES

Effective April, 2001 Rev. 1.0

Page Summary

Throughout Removed Warning “Consult Safety Data Sheet 1A99078…”.

Front Cover Moved “Essential Instructions” page xxiii/xxiv forward to Front Cover.

Changed National Response Center phone number to 1-800-4336076 or 1-888-433-6829.

Page 1-8 Changed Hazardous Area Certifications data. Changed Reference Air

requirement. Deleted Electronic Noise requirement.

Page 2-9 Added Note to Figure 2-7.

Page 5-2 Table 5-1; changed Heater Fault 6 Self-Clearing column data to “NO”

and Heater Fault 8 Self-Clearing column data to “YES”.

Page 5-6 Added factory assistance phone number to paragraph 5-4d1.

Back Cover Added new Warranty statement.

Effective November, 2001 Rev. 1.1

Page Summary

Page 1-12 Added new cup type diffusion elements to paragraph 1-8, “Probe

Options”, and supporting illustrations, Figures 1-15 and 1-16.

Page 1-13 thru 1-15

Page 7-2 Added new cup type diffuser part numbers to Table 7-1, Replacement

Page Summary

Page 1-7 Updated list of available diffusion elements.

Modified Tables 1-1, 1-2, and 1-3. Added Table 1-4, Single Probe Autocalibration Sequencer Coding.

Parts for Probe.

Effective January, 2002 Rev. 1.2

Oxymitter 5000

PREFACE............................................................................................................................1

Definitions ............................................................................................................................1

Safety Instructions ..............................................................................................................3

1-0 DESCRIPTION AND SPECIFICATIONS ...................................................................... 1-1

1-1 Component Checklist Of Typical System (Package Contents) .................................. 1-1

1-2 System Overview............................................................................................................ 1-1

1-3 IMPS 4000 (Optional) .................................................................................................... 1-7

1-4 SPS 4000 (Optional)...................................................................................................... 1-7

1-5 Probe Options.................................................................................................................. 1-7

1-6 Specifications................................................................................................................... 1-9

2-0 INSTALLATION .............................................................................................................. 2-1

2-1 Mechanical Installation ................................................................................................... 2-1

2-2 Electrical Installation....................................................................................................... 2-8

2-3 Pneumatic Installation .................................................................................................... 2-9

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IB-106-350C Rev. 1.2

January 2002

3-0 STARTUP AND OPERATION ...................................................................................... 3-1

3-1 General ............................................................................................................................ 3-1

3-2 Logic I/O ......................................................................................................................... 3-4

3-3 Recommended Configuration......................................................................................... 3-5

3-4 Power Up........................................................................................................................ 3-6

3-5 Start Up Oxymitter 5000 Calibration............................................................................ 3-7

3-6 IMPS 4000 Connections ................................................................................................ 3-7

3-7 SPS 4000 Connections ................................................................................................. 3-7

3-8 Operation From Local Keypad...................................................................................... 3-7

4-0 MAINTENANCE AND SERVICE .................................................................................. 4-1

4-1 Overview.......................................................................................................................... 4-1

4-2 Calibration........................................................................................................................ 4-1

4-3 LED Status Indicators .................................................................................................... 4-6

4-4 Hazardous Area Oxymitter 5000 Removal/Replacement ........................................... 4-7

4-5 Electronics Replacement................................................................................................ 4-9

4-6 Entire Probe Replacement (Excluding Electronics) .................................................. 4-12

4-7 Heater Strut Replacement ........................................................................................... 4-13

4-8 Cell Replacement ......................................................................................................... 4-14

4-9 Ceramic Diffusion Element Replacement................................................................... 4-16

4-10 Assembly Replacement ................................................................................................ 4-17

5-0 TROUBLESHOOTING .................................................................................................... 5-1

5-1 General ............................................................................................................................ 5-1

5-2 Alarm Indications ............................................................................................................ 5-1

5-3 Alarm Contacts ............................................................................................................... 5-1

5-4 Identifying And Correcting Alarm Indications .............................................................. 5-2

6-0 OPTIONAL ACCESSORIES .......................................................................................... 6-1

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Instruction Manual

IB-106-350C Rev. 1.2 January 2002

7-0 RETURN OF MATERIAL .............................................................................................. 7-1

7-1 Equipment Return Procedure .......................................................................................... 7-1

8-0 REPLACEMENT PARTS ............................................................................................... 8-1

9-0 APPENDICES ................................................................................................................. 9-1

10-0 INDEX............................................................................................................................ 10-1

Oxymitter 5000

ii Rosemount Analytical Inc. A Division of Emerson Process Management

Oxymitter 5000

Figure 1-1. Typical System Package ....................................................................................... 1-2

Figure 1-2. Hazardous Area Oxymitter 5000 Autocalibration System Options........................ 1-4

Figure 1-3. Hazardous Area Oxymitter 5000 FOUNDATION Fieldbus Connections............... 1-5

Figure 1-4. Typical System Installation .................................................................................... 1-6

Figure 1-5. Flame Arrestor Ceramic Diffusion Assembly.......................................................... 1-7

Figure 1-6. Flame Arrestor Snubber Diffusion Assembly.......................................................... 1-7

Figure 1-7. Abrasive Shield Assembly ..................................................................................... 1-8

Figure 2-1. Hazardous Area Oxymitter 5000 Installation ......................................................... 2-2

Figure 2-2. Hazardous Area Oxymitter 5000 with Abrasive Shield.......................................... 2-3

Figure 2-3. Hazardous Area Oxymitter 5000 Adaptor Plate Installation .................................. 2-4

Figure 2-4. Hazardous Area Oxymitter 5000 Mounting Flange Installation ............................. 2-5

Figure 2-5. Orienting the Optional Vee Deflector..................................................................... 2-6

Figure 2-6. Installation with Drip Loop and Insulation Removal............................................... 2-7

Figure 2-7. Terminal Block ....................................................................................................... 2-9

Figure 2-8. Air Set, Plant Air Connection ............................................................................... 2-10

Figure 2-9. Hazardous Area Oxymitter 5000 Gas Connections............................................. 2-10

Figure 3-1. Integral Electronics ................................................................................................ 3-1

Figure 3-2. Hazardous Area Oxymitter 5000 Defaults ............................................................. 3-3

Figure 3-3. Startup and Normal Operation............................................................................... 3-6

Figure 3-4. Calibration Keys..................................................................................................... 3-7

Figure 3-5. Normal Operation...................................................................................................3-8

Figure 4-1. Hazardous Area Oxymitter 5000 Exploded View .................................................. 4-2

Figure 4-2. Membrane Keypad................................................................................................. 4-3

Figure 4-3. Inside Right Cover .................................................................................................4-5

Figure 4-4. Terminal Block ....................................................................................................... 4-8

Figure 4-5. Electronic Assembly............................................................................................... 4-9

Figure 4-6. J8 Connector........................................................................................................ 4-10

Figure 4-7. Fuse Location ......................................................................................................4-12

Figure 4-8. Heater Strut Assembly ......................................................................................... 4-14

Figure 4-9. Cell Replacement Kit ........................................................................................... 4-14

Figure 4-10. Ceramic Diffusion Element Replacement ............................................................ 4-16

Figure 4-11. Contact and Thermocouple Assembly Replacement .......................................... 4-18

Figure 5-1. Fault 1, Open Thermocouple ................................................................................. 5-3

Figure 5-2. Fault 2, Shorted Thermocouple ............................................................................. 5-4

Figure 5-3. Fault 3, Reversed Thermocouple .......................................................................... 5-5

Figure 5-4. Fault 4, A/D Comm Error ....................................................................................... 5-6

Figure 5-5. Fault 5, Open Heater ............................................................................................. 5-7

Figure 5-6. Fault 6, High High Heater Temp ............................................................................ 5-8

Figure 5-7. Fault 7, High Case Temp....................................................................................... 5-9

Figure 5-8. Fault 8, Low Heater Temp ................................................................................... 5-10

Figure 5-9. Fault 9, High Heater Temp .................................................................................. 5-11

Figure 5-10. Fault 10, High Cell mV......................................................................................... 5-12

Figure 5-11. Fault 11, Bad Cell ................................................................................................5-13

Figure 5-12. Fault 12, EEPROM Corrupt ................................................................................. 5-14

Figure 5-13. Fault 13, Invalid Slope ......................................................................................... 5-15

Figure 5-14. Fault 14, Invalid Constant .................................................................................... 5-16

Figure 5-15. Fault 15, Last Calibration Failed .......................................................................... 5-17

Figure 8-1. Cell Replacement Kit ............................................................................................. 8-2

Figure 8-2. Probe Disassembly Kit........................................................................................... 8-3

Instruction Manual

IB-106-350C Rev. 1.2

January 2002

LIST OF ILLUSTRATIONS

Rosemount Analytical Inc. A Division of Emerson Process Management iii

Instruction Manual

IB-106-350C Rev. 1.2 January 2002

Table 1-1. Product Matrix......................................................................................................1-10

Table 1-2. Calibration Components ...................................................................................... 1-11

Table 1-3. Intelligent Multiprobe Test Gas Sequencer ......................................................... 1-12

Table 1-4. Single Probe Autocalibration Sequencer Coding ................................................ 1-12

Table 3-1. Logic I/O Configuration .......................................................................................... 3-4

Table 3-2. Logic I/O Parameters............................................................................................. 3-5

Table 4-1. Diagnostic/Unit Alarms .......................................................................................... 4-7

Table 5-1. Diagnostic/Unit Alarm Fault Definitions ................................................................. 5-2

Table 8-1. Replacement Parts for Probe ................................................................................ 8-1

Table 8-2. Replacement Parts for Electronics ........................................................................ 8-4

Oxymitter 5000

LIST OF TABLES

iv Rosemount Analytical Inc. A Division of Emerson Process Management

Oxymitter 5000

The purpose of this manual is to provide information concerning the components, functions, installation and maintenance of the Oxymitter 5000 Hazardous Area Oxygen Transmitter with Foundation Fieldbus Communications.

Some sections may describe equipment not used in your configuration. The user should become thoroughly familiar with the operation of this module before operating it. Read this instruction manual completely.

The following definitions apply to WARNINGS, CAUTIONS, and NOTES found throughout this publication.

Instruction Manual

IB-106-350C Rev. 1.2

January 2002

PREFACE

DEFINITIONS

Highlights an operation or maintenance procedure, practice, condition, statement, etc. If not strictly observed, could result in injury, death, or long-term health hazards of personnel.

Highlights an essential operating procedure, condition, or statement.

: EARTH (GROUND) TERMINAL

: PROTECTIVE CONDUCTOR TERMINAL

: RISK OF ELECTRICAL SHOCK

: WARNING: REFER TO INSTRUCTION BULLETIN

NOTE TO USERS

Highlights an operation or maintenance procedure, practice, condition, statement, etc. If not strictly observed, could result in damage to or destruction of equipment, or loss of effectiveness.

NOTE

The number in the lower right corner of each illustration in this publication is a manual illustration number. It is not a part number, and is not related to the illustration in any technical manner.

Rosemount Analytical Inc. A Division of Emerson Process Management P-1

Instruction Manual

IB-106-350C Rev. 1.2 January 2002

Oxymitter 5000

HAZARDOUS AREA OXYGEN TRANSMITTER WITH FOUNDATION FIELDBUS COMMUNICATIONS

NOTICE

Read this manual before working with the product. For personal and system safety, and for optimum product performance, make sure you thoroughly understand the contents before installing, using, or maintaining this product.

The products described in this document are NOT designed for nuclear-qualified applications.

Using non-nuclear-qualified products in applications that require nuclear-qualified hardware or products may cause inaccurate readings.

For information on Fisher-Rosemount nuclear-qualified products, contact your local FisherRosemount Sales Representative.

Rosemount is a registered trademark of Rosemount Inc. Delta V, the Delta V logotype, PlantWeb, and the PlantWeb logotype are trademarks of Fisher-Rosemount. F

OUNDATION

is a trademark of the Fieldbus Foundation.

Rosemount satisfies all obligations coming from legislation to harmonize the product requirements in the European Union.

P-2 Rosemount Analytical Inc. A Division of Emerson Process Management

Oxymitter 5000

FOR THE WIRING AND INSTALLATION

The following safety instructions apply specifically to all EU member states. They should be strictly adhered to in order to assure compliance with the Low Voltage Directive. NonEU states should also comply with the following unless superseded by local or National Standards.

1. Adequate earth connections should be made to all earthing points, internal and external,

where provided.

2. After installation or troubleshooting, all safety covers and safety grounds must be replaced.

The integrity of all earth terminals must be maintained at all times.

3. Mains supply cords should comply with the requirements of IEC227 or IEC245.

Instruction Manual

IB-106-350C Rev. 1.2

January 2002

IMPORTANT

SAFETY INSTRUCTIONS

OF THIS APPARATUS

4. All wiring shall be suitable for use in an ambient temperature of greater than 75°C.

5. All cable glands used should be of such internal dimensions as to provide adequate cable

anchorage.

6. To ensure safe operation of this equipment, connection to the mains supply should only be

made through a circuit breaker which will disconnect all circuits carrying conductors during a fault situation. The circuit breaker may also include a mechanically operated isolating switch. If not, then another means of disconnecting the equipment from the supply must be provided and clearly marked as such. Circuit breakers or switches must comply with a recognized standard such as IEC947. All wiring must conform with any local standards.

7. Where equipment or covers are marked with the symbol to the right, hazard-

ous voltages are likely to be present beneath. These covers should only be removed when power is removed from the equipment — and then only by trained service personnel.

8. Where equipment or covers are marked with the symbol to the right, there is a

danger from hot surfaces beneath. These covers should only be removed by trained service personnel when power is removed from the equipment. Certain surfaces may remain hot to the touch.

9. Where equipment or covers are marked with the symbol to the right, refer to

the Operator Manual for instructions.

10. All graphical symbols used in this product are from one or more of the follow-

ing standards: EN61010-1, IEC417, and ISO3864.

Rosemount Analytical Inc. A Division of Emerson Process Management P-3

Instruction Manual

IB-106-350C Rev. 1.2 January 2002

Oxymitter 5000

P-4 Rosemount Analytical Inc. A Division of Emerson Process Management

Oxymitter 5000

CERAMIC FIBER PRODUCTS

MATERIAL SAFETY DATA SHEET

JULY 1, 1996

SECTION I. IDENTIFICATION

PRODUCT NAME

Ceramic Fiber Heaters, Molded Insulation Modules and Ceramic Fiber Radiant Heater Panels.

CHEMICAL FAMILY

Vitreous Aluminosilicate Fibers with Silicon Dioxide.

CHEMICAL NAME

N.A.

Instruction Manual

IB-106-350C Rev. 1.2

January 2002

CHEMICAL FORMULA

N.A.

MANUFACTURER’S NAME AND ADDRESS

Watlow Columbia 573-474-9402 2101 Pennsylvania Drive 573-814-1300, ext. 5170 Columbia, MO 65202

HEALTH HAZARD SUMMARY

WARNING

• Possible cancer hazard based on tests with laboratory animals.

• May be irritating to skin, eyes and respiratory tract.

• May be harmful if inhaled.

• Cristobalite (crystalline silica) formed at high temperatures (above 1800ºF) can cause severe respiratory disease.

Rosemount Analytical Inc. A Division of Emerson Process Management P-5

Instruction Manual

IB-106-350C Rev. 1.2 January 2002

Oxymitter 5000

SECTION II. PHYSICAL DATA

APPEARANCE AND ODOR

Cream to white colored fiber shapes. With or without optional white to gray granular surface coating and/or

optional black surface coating.

SPECIFIC WEIGHT: 12-25 lb./cubic foot BOILING POINT: N.A.

VOLATILES (% BY WT.): N.A. WATER SOLUBILITY: N.A.

SECTION III. HAZARDOUS INGREDIENTS

MATERIAL, QUANTITY, AND THRESHOLD/EXPOSURE LIMIT VALUES

Aluminosilicate (vitreous) 99+ % 1 fiber/cc TWA CAS. No. 142844-00-06 10 fibers/cc CL Zirconium Silicate 0-10% 5 mg/cubic meter (TLV) Black Surface Coating** 0 - 1% 5 mg/cubic meter (TLV) Armorphous Silica/Silicon Dioxide 0-10% 20 mppcf (6 mg/cubic meter)

PEL (OSHA 1978) 3 gm cubic meter (Respirable dust): 10 mg/cubic meter, Intended TLV (ACGIH 1984-85)

**Composition is a trade secret.

SECTION IV. FIRE AND EXPLOSION DATA

FLASH POINT: None FLAMMABILITY LIMITS: N.A.

EXTINGUISHING MEDIA

Use extinguishing agent suitable for type of surrounding fire.

UNUSUAL FIRE AND EXPLOSION HAZARDS / SPECIAL FIRE FIGHTING PROCEDURES

N.A.

P-6 Rosemount Analytical Inc. A Division of Emerson Process Management

Instruction Manual

IB-106-350C Rev. 1.2

Oxymitter 5000

SECTION V. HEALTH HAZARD DATA

THRESHOLD LIMIT VALUE

(See Section III)

EFFECTS OF OVER EXPOSURE

EYE

Avoid contact with eyes. Slightly to moderately irritating. Abrasive action may cause damage to outer surface of eye.

INHALATION

May cause respiratory tract irritation. Repeated or prolonged breathing of particles of respirable size may cause inflammation of the lung leading to chest pain, difficult breathing, coughing and possible fibrotic change in the lung (Pneumoconiosis). Pre-existing medical conditions may be aggravated by exposure: specifically, bronchial hyper-reactivity and chronic bronchial or lung disease.

INGESTION

May cause gastrointestinal disturbances. Symptoms may include irritation and nausea, vomiting and diarrhea.

January 2002

SKIN

Slightly to moderate irritating. May cause irritation and inflammation due to mechanical reaction to sharp, broken ends of fibers.

EXPOSURE TO USED CERAMIC FIBER PRODUCT

Product which has been in service at elevated temperatures (greater than 1800ºF/982ºC) may undergo partial conversion to cristobalite, a form of crystalline silica which can cause severe respiratory disease (Pneumoconiosis). The amount of cristobalite present will depend on the temperature and length of time in service. (See Section IX for permissible exposure levels).

SPECIAL TOXIC EFFECTS

The existing toxicology and epidemiology data bases for RCF’s are still preliminary. Information will be updated as studies are completed and reviewed. The following is a review of the results to date:

EPIDEMIOLOGY

At this time there are no known published reports demonstrating negative health outcomes of workers exposed to refractory ceramic fiber (RCF). Epidemiologic investigations of RCF production workers are ongoing.

1) There is no evidence of any fibrotic lung disease (interstitial fibrosis) whatsoever on x-ray.

2) There is no evidence of any lung disease among those employees exposed to RCF that had never smoked.

3) A statistical “trend” was observed in the exposed population between the duration of exposure to RCF and a decrease in some measures of pulmonary function. These observations are clinically insignificant. In other words, if these observations were made on an individual employee, the results would be interpreted as being within the normal range.

4) Pleural plaques (thickening along the chest wall) have been observed in a small number of employees who had a long duration of employment. There are several occupational and non-occupational causes for pleural plaque. It should be noted that plaques are not “pre-cancer” nor are they associated with any measurable effect on lung function.

Rosemount Analytical Inc. A Division of Emerson Process Management P-7

Instruction Manual

IB-106-350C Rev. 1.2 January 2002

TOXICOLOGY

A number of studies on the health effects of inhalation exposure of rats and hamsters are available. Rats were exposed to RCF in a series of life-time nose-only inhalation studies. The animals were exposed to 30, 16, 9, and 3 mg/m

Animals exposed to 30 and 16 mg/m animals exposed to 9 mg/m were found to have the response typically observed any time a material is inhaled into the deep lung. While a statistically significant increase in lung tumors was observed following exposure to the highest dose, there was no excess lung cancers at the other doses. Two rats exposed to 30 mg/m veloped masotheliomas.

The International Agency for Research on Cancer (IARC) reviewed the carcinogenicity data on man-made vitreous fibers (including ceramic fiber, glasswool, rockwool, and slagwool) in 1987. IARC classified ceramic fiber, fibrous glasswool and mineral wool (rockwool and slagwool) as possible human carcinogens (Group 2B).

, which corresponds with approximately 200, 150, 75, and 25 fibers/cc.

had developed a mild parenchymal fibrosis; animals exposed to the lowest dose

were observed to have developed a pleural and parenchymal fibroses;

and one rat exposed to 9 mg/m3 de-

Oxymitter 5000

EMERGENCY FIRST AID PROCEDURES

EYE CONTACT

Flush eyes immediately with large amounts of water for approximately 15 minutes. Eye lids should be held away from the eyeball to insure thorough rinsing. Do not rub eyes. Get medical attention if irritation persists.

INHALATION

Remove person from source of exposure and move to fresh air. Some people may be sensitive to fiber induced irritation of the respiratory tract. If symptoms such as shortness of breath, coughing, wheezing or chest pain develop, seek medical attention. If person experiences continued breathing difficulties, administer oxygen until medical assistance can be rendered.

INGESTION

Do not induce vomiting. Get medical attention if irritation persists.

SKIN CONTACT

Do not rub or scratch exposed skin. Wash area of contact thoroughly with soap and water. Using a skin cream or lotion after washing may be helpful. Get medical attention if irritation persists.

SECTION VI. REACTIVITY DATA

STABILITY/CONDITIONS TO AVOID

Stable under normal conditions of use.

HAZARDOUS POLYMERIZATION/CONDITIONS TO AVOID

N.A.

INCOMPATIBILITY/MATERIALS TO AVOID

Incompatible with hydrofluoric acid and concentrated alkali.

HAZARDOUS DECOMPOSITION PRODUCTS

N.A.

P-8 Rosemount Analytical Inc. A Division of Emerson Process Management

Instruction Manual

IB-106-350C Rev. 1.2

Oxymitter 5000

SECTION VII. SPILL OR LEAK PROCEDURES

STEPS TO BE TAKEN IF MATERIAL IS RELEASED OR SPILLED

Where possible, use vacuum suction with HEPA filters to clean up spilled material. Use dust suppressant where sweeping if necessary. Avoid clean up procedure which may result in water pollution. (Observe Special Protection Information Section VIII.)

WASTE DISPOSAL METHODS

The transportation, treatment, and disposal of this waste material must be conducted in compliance with all applicable Federal, State, and Local regulations.

SECTION VIII. SPECIAL PROTECTION INFORMATION

RESPIRATORY PROTECTION

January 2002

Use NIOSH or MSHA approved equipment when airborne exposure limits may be exceeded. NIOSH/MSHA

approved breathing equipment may be required for non-routine and emergency use. (See Section IX for suitable equipment).

Pending the results of long term health effects studies, engineering control of airborne fibers to the lowest levels attainable is advised.

VENTILATION

Ventilation should be used whenever possible to control or reduce airborne concentrations of fiber and dust. Carbon monoxide, carbon dioxide, oxides of nitrogen, reactive hydrocarbons and a small amount of formaldehyde may accompany binder burn-off during first heat. Use adequate ventilation or other precautions to eliminate vapors resulting from binder burn-off. Exposure to burn-off fumes may cause respiratory tract irritation, bronchial hyper-reactivity and asthmatic response.

SKIN PROTECTION

Wear gloves, hats and full body clothing to prevent skin contact. Use separate lockers for work clothes to prevent fiber transfer to street clothes. Wash work clothes separately from other clothing and rinse washing machine thoroughly after use.

EYE PROTECTION

Wear safety glasses or chemical worker’s goggles to prevent eye contact. Do not wear contact lenses when working with this substance. Have eye baths readily available where eye contact can occur.

Rosemount Analytical Inc. A Division of Emerson Process Management P-9

Instruction Manual

IB-106-350C Rev. 1.2 January 2002

Oxymitter 5000

SECTION IX. SPECIAL PRECAUTIONS

PRECAUTIONS TO BE TAKEN IN HANDLING AND STORING

General cleanliness should be followed.

The Toxicology data indicate that ceramic fiber should be handled with caution. The handling practices de-

scribed in this MSDS must be strictly followed. In particular, when handling refractory ceramic fiber in any application, special caution should be taken to avoid unnecessary cutting and tearing of the material to minimize generation of airborne dust.

It is recommended that full body clothing be worn to reduce the potential for skin irritation. Washable or disposable clothing may be used. Do not take unwashed work clothing home. Work clothes should be washed separately from other clothing. Rinse washing machine thoroughly after use. If clothing is to be laundered by someone else, inform launderer of proper procedure. Work clothes and street clothes should be kept separate to prevent contamination.

Product which has been in service at elevated temperatures (greater than 1800ºF/982ºC) may undergo partial conversion to cristobalite, a form of crystalline silica. This reaction occurs at the furnace lining hot face. As a consequence, this material becomes more friable; special caution must be taken to minimize generation of airborne dust. The amount of cristobalite present will depend on the temperature and length in service.

IARC has recently reviewed the animal, human, and other relevant experimental data on silica in order to critically evaluate and classify the cancer causing potential. Based on its review, IARC classified crystalline silica as a group 2A carcinogen (probable human carcinogen).

The OSHA permissible exposure limit (PEL for cristobalite is 0.05 mg/m threshold limit value (TLV) for cristobalite is 0.05 mg/m MSHA approved equipment when airborne exposure limits may be exceeded. The minimum respiratory protection recommended for given airborne fiber or cristobalite concentrations are:

(respirable dust) (ACGIH 1991-92). Use NIOSH or

(respirable dust). The ACGIH

CONCENTRATION

0-1 fiber/cc or 0-0.05 mg/m3 cristobalite Optional disposable dust respirator (e.g. 3M (the OSHA PEL) 9970 or equivalent).

Up to 5 fibers/cc or up to 10 times the Half face, air-purifying respirator equipped OSHA PEL for cristobalite with high efficiency particulate air (HEPA)

filter cartridges (e.g. 3M 6000 series with 2040 filter or equivalent).

Up to 25 fibers/cc or 50 times the OSHA Full face, air-purifying respirator with high PEL for cristobalite (2.5 mg/m

) efficiency particulate air (HEPA) filter cart-

ridges (e.g. 3M 7800S with 7255 filters or equivalent) or powered air-purifying respirator (PARR) equipped with HEPA filter cartridges (e.g. 3M W3265S with W3267 filters or equivalent).

Greater than 25 fibers/cc or 50 times the Full face, positive pressure supplied air respiraOSHA PEL for cristobalite (2.5 mg/m

P-10 Rosemount Analytical Inc. A Division of Emerson Process Management

) tor (e.g. 3M 7800S with W9435 hose & W3196

low pressure regulator kit connected to clean air supply or equivalent).

Instruction Manual

IB-106-350C Rev. 1.2

Oxymitter 5000

If airborne fiber or cristobalite concentrations are not known, as minimum protection, use NIOSH/MSHA ap-

proved half face, air-purifying respirator with HEPA filter cartridges.

Insulation surface should be lightly sprayed with water before removal to suppress airborne dust. As water evaporates during removal, additional water should be sprayed on surfaces as needed. Only enough water should be sprayed to suppress dust so that water does not run onto the floor of the work area. To aid the wetting process, a surfactant can be used.

After RCF removal is completed, dust-suppressing cleaning methods, such as wet sweeping or vacuuming, should be used to clean the work area. If dry vacuuming is used, the vacuum must be equipped with HEPA filter. Air blowing or dry sweeping should not be used. Dust-suppressing components can be used to clean up light dust.

Product packaging may contain product residue. Do not reuse except to reship or return Ceramic Fiber products to the factory.

January 2002

Rosemount Analytical Inc. A Division of Emerson Process Management P-11

Instruction Manual

IB-106-350C Rev. 1.2 January 2002

Oxymitter 5000

GENERAL PRECAUTIONS FOR HANDLING AND

STORING HIGH PRESSURE GAS CYLINDERS

Edited from selected paragraphs of the Compressed Gas Association’s “Handbook of Compressed Gases” published in 1981 Compressed Gas Association 1235 Jefferson Davis Highway Arlington, Virginia 22202 Used by Permission

1. Never drop cylinders or permit them to strike each other violently.

2. Cylinders may be stored in the open, but in such cases, should be protected against extremes of weather and, to prevent

rusting, from the dampness of the ground. Cylinders should be stored in the shade when located in areas where extreme temperatures are prevalent.

3. The valve protection cap should be left on each cylinder until it has been secured against a wall or bench, or placed in a

cylinder stand, and is ready to be used.

4. Avoid dragging, rolling, or sliding cylinders, even for short distance; they should be moved by using a suitable hand-

truck.

5. Never tamper with safety devices in valves or cylinders.

6. Do not store full and empty cylinders together. Serious suckback can occur when an empty cylinder is attached to a pres-

surized system.

7. No part of cylinder should be subjected to a temperature higher than 125°F (52°C). A flame should never be permitted to

come in contact with any part of a compressed gas cylinder.

8. Do not place cylinders where they may become part of an electric circuit. When electric arc welding, precautions must

be taken to prevent striking an arc against the cylinder.

P-12 Rosemount Analytical Inc. A Division of Emerson Process Management

Oxymitter 5000

DESCRIPTION AND SPECIFICATIONS

Instruction Manual

IB-106-350C Rev. 1.2

January 2002

SECTION 1

1-1 COMPONENT CHECKLIST OF TYPICAL

SYSTEM (PACKAGE CONTENTS)

A typical Rosemount Hazardous Area Oxymitter 5000 Oxygen Transmitter should contain the items shown in Figure 1-1. Record the part number, serial number, and order number for each component of your system in the table located on the first page of this manual.

The Hazardous Area Oxymitter 5000 is offered in both hazardous and general purpose configurations. The hazardous area version has the “EX” and CSA symbols on the apparatus approval label. The general purpose version does not have an approval label. If you received the general purpose version, ensure you do not install it in a potentially explosive atmosphere.

Use the product matrix in Table 1-1 at the end of this section to compare your order number against your unit. The first part of the matrix defines the model. The last part defines the various options and features of the Hazardous Area Oxymitter 5000. Ensure the features and options specified by your order number are on or included with the unit.

1-2 SYSTEM OVERVIEW

b. FOUNDATION Fieldbus Technology

FOUNDATION fieldbus is an all digital, serial, two-way communication system that interconnects field equipment such as sensors, actuators, and controllers. Fieldbus is a Local Area Network (LAN) for instruments used in both process and manufacturing automation with built-in capacity to distribute the control application across the network. The fieldbus environment is the base level group of digital networks in the hierarchy of planet networks.

The fieldbus retains the desirable features of the 4-20 mA analog system, including a standardized physical interface to the wire, bus powered devices on a single wire, and intrinsic safety options, and enables additional capabilities, such as:

• Increased capabilities due to full

digital communications

• Reduced wiring and wire termina-

tions due to multiple devices on one set of wires

• Increased selection of suppliers

due to interoperability

• Reduced loading on control room

equipment with the distribution of some control and input/ output functions to field devices

• Speed options for process control

and manufacturing applications

a. Scope

This Instruction Bulletin is designed to supply details needed to install, start up, operate, and maintain the Hazardous Area Oxymitter 5000. Integral signal conditioning electronics outputs a digital FOUNDATION fieldbus signal representing an O provides a membrane keypad for setup, calibration, and diagnostics. This same information, plus additional details, can be accessed via fieldbus digital communications.

Rosemount Analytical Inc. A Division of Emerson Process Management Description and Specifications 1-1

value and

c. System Description

The Hazardous Area Oxymitter 5000 is designed to measure the net concentration of oxygen in an industrial process; i.e., the oxygen remaining after all fuels have been oxidized. The probe is permanently positioned within an exhaust duct or stack and performs its task without the use of a sampling system.

Instruction Manual

IB-106-350C Rev. 1.2 January 2002

Oxymitter 5000

33100001

1. Instruction Bulletin

2. IMPS 4000 Intelligent Multiprobe Test Gas Sequencer (Optional)

3. Hazardous Area Oxymitter 5000 with Integral Electronics

4. SPS 4000 Single Probe Autocalibration Sequencer (Optional) – (Shown with reference air option) (Safe area only)

5. Adaptor Plate with Mounting Hardware and Gasket

6. Reference Air Set (used if SPS 4000 without reference air option or IMPS 4000 not supplied)

Figure 1-1. Typical System Package

1-2 Description and Specifications Rosemount Analytical Inc. A Division of Emerson Process Management

Oxymitter 5000

Instruction Manual

IB-106-350C Rev. 1.2

January 2002

The equipment measures oxygen percentage by reading the voltage developed across a heated electrochemical cell, which consists of a small yttria-stabilized, zirconia disc. Both sides of the disc are coated with porous metal electrodes. When operated at the proper temperature, the millivolt output voltage of the cell is given by the following Nernst equation:

EMF = KT log10(P1/P2) + C

Where:

1. P

is the partial pressure of the oxygen

in the measured gas on one side of the cell.

2. P

is the partial pressure of the oxygen

in the reference air on the opposite side of the cell.

3. T is the absolute temperature.

4. C is the cell constant.

5. K is an arithmetic constant.

NOTE

For best results, use clean, dry, instrument air (20.95% oxygen) as the reference air.

When the cell is at operating temperature and there are unequal oxygen concentrations across the cell, oxygen ions will travel from the high oxygen partial pressure side to the low oxygen partial pressure side of the cell. The resulting logarithmic output voltage is approximately 50 mV per decade. The output is proportional to the inverse logarithm of the oxygen concentration. Therefore, the output signal increases as the oxygen concentration of the sample gas decreases. This characteristic enables the Hazardous Area Oxymitter 5000 to provide exceptional sensitivity at low oxygen concentrations.

The Hazardous Area Oxymitter 5000 measures net oxygen concentration in the presence of all the products of combustion, including water vapor. Therefore, it may be considered an analysis on a “wet” basis. In comparison with older methods, such as the portable apparatus, which provides an analysis on a “dry” gas basis, the “wet” analysis will, in general, indicate a lower percentage of oxygen. The difference will be proportional to the water content of the sampled gas stream.

d. System Configuration

Hazardous Area Oxymitter 5000 units are available in three length options, giving the user the flexibility to use an in situ penetration appropriate to the size of the stack or duct. The options on length are 457 mm (18 in.), 0.91 m (3 ft), 1.83 m (6 ft).

The integral electronics control probe temperature and provide an output that represents the measured oxygen concentration. The power supply can accept voltages of 90-250 VAC and 50/60 Hz; therefore, no setup procedures are required. The oxygen sensing cell is maintained at a constant temperature by modulating the duty cycle of the probe heater portion of the integral electronics. The integral electronics accepts millivolt signals generated by the sensing cell and produces the outputs to be used by remotely connected devices. The output is a FOUNDATION fieldbus digital communication signal.

Two calibration gas sequencers are available to the Hazardous Area Oxymitter 5000, but they must be installed in a nonhazardous, explosive-free environment: the IMPS 4000 and the SPS 4000 (Figure 1-2).

Systems with multiprobe applications may employ an optional IMPS 4000 Intelligent Multiprobe Test Gas Sequencer. The IMPS 4000 provides automatic calibration gas sequencing for up to four Hazardous Area Oxymitter 5000 units and accommodates autocalibrations based on the CALIBRATION RECOMMENDED signal from the Hazardous Area Oxymitter 5000, a timed interval set up via fieldbus or the IMPS 4000, or when a calibration request is initiated.

For systems with one or two Hazardous Area Oxymitter 5000 units per combustion process, an optional remote mounted SPS 4000 Single Probe Autocalibration Sequencer can be used with each Hazardous Area Oxymitter 5000 to provide automatic calibration gas sequencing. The sequencer performs autocalibrations based on the CALIBRATION RECOMMENDED signal from the Hazardous Area Oxymitter 5000, a timed interval set up in fieldbus, or whenever a calibration request is initiated.

Rosemount Analytical Inc. A Division of Emerson Process Management Description and Specifications 1-3

Instruction Manual

IB-106-350C Rev. 1.2 January 2002

Oxymitter 5000

HAZARDOUS AREA

OXYMITTER 5000

IMPS 4000

(1 TO 4 PROBES)

(MUST BE INSTALLED

IN A SAFE AREA

OR BE X- OR Z-PURGED

BY THE CUSTOMER)

REMOTE MOUNTED

SPS 4000

(1 PROBE)

(MUST BE INSTALLED

IN A SAFE AREA)

Figure 1-2. Hazardous Area Oxymitter 5000

Autocalibration System Options

e. System Features

1. The CALIBRATION RECOMMENDED feature detects when the sensing cell is likely out of limits. This may eliminate the need to calibrate on a “time since last cal” basis.

2. The cell output voltage and sensitivity increase as the oxygen concentration decreases.

33100002

6. Integral electronics eliminates traditional wiring between probe and electronics.

7. The integral electronics are adaptable for line voltages from 90-250 VAC; therefore, no configuration is necessary.

8. The Hazardous Area Oxymitter 5000 membrane keypad is available in five languages:

English French German Italian Spanish

9. An operator can calibrate and diagnostically troubleshoot the Hazardous Area Oxymitter 5000 in one of three ways:

Accessing the probe keypad requires opening the electronics housing. Opening the electronic housing will cause the loss of ALL hazardous permits. Opening the electronics housing in hazardous areas may cause an explosion resulting in loss of property, severe personal injury, or death. It may be required to get a hot work permit from your company safety officer before opening the electronic housing.

(a) Membrane Keypad. The mem-

brane keypad, housed within the right side of the electronics housing, provides fault indication by way of flashing LEDs. Calibration can be performed from the membrane keypad.

3. Membrane keypad and FOUNDATION fieldbus communication are standard.

(b) FOUNDATION fieldbus Interface.

The Hazardous Area Oxymitter 5000’s output carries a signal

4. Field replaceable cell, heater, thermocouple, and diffusion element.

containing the oxygen level encoded in digital format. This digital output can also be used to com-

5. The Hazardous Area Oxymitter 5000 is constructed of rugged 316 L stainless steel for all wetted parts.

1-4 Description and Specifications Rosemount Analytical Inc. A Division of Emerson Process Management

municate with the Oxymitter and access all of the Oxymitter’s status information.

Oxymitter 5000

Instruction Manual

IB-106-350C Rev. 1.2

January 2002

grammable Logic Controller (PLC) in the IMPS 4000 provides fault indications using flashing LEDs and LCD display messages. Refer to the IMPS 4000 Intelligent Multiprobe Test Gas Sequencer Instruction Bulletin for more information.

f. Handling the Hazardous Area Oxymitter

5000

It is important that printed circuit boards and integrated circuits are handled only when adequate antistatic precautions have been taken to prevent possible equipment damage.

The Hazardous Area Oxymitter 5000 is designed for industrial applications. Treat each component of the system with care to avoid physical damage. Some probe components are made from ceramics, which are susceptible to shock when mishandled.

g. System Considerations

Prior to installing your Hazardous Area Oxymitter 5000, make sure you have all the components necessary to make the system

installation. Ensure all the components are properly integrated to make the system functional.

NOTE

The integral electronics is rated NEMA 4X (IP66) and is capable of operation at temperatures up to 65°C (149°F).

Retain the packaging in which the Hazardous Area Oxymitter 5000 arrived from the factory in case any components are to be shipped to another site. This packaging has been designed to protect the product.

After verifying that you have all the components, select mounting locations and determine how each component will be placed in terms of available line voltage, ambient temperatures, environmental considerations, convenience, and serviceability. Figure 1-3 shows a typical system wiring. A typical system installation is illustrated in Figure 1-4.

A source of instrument air is optional at the Hazardous Area Oxymitter 5000 for reference air use. Since the unit is equipped with an in-place calibration feature, provisions can be made to permanently connect calibration gas tanks to the Hazardous Area Oxymitter 5000.

FIELDBUS DIGITAL

SIGNAL

HAZARDOUS AREA

OXYMITTER 5000

WITH INTEGRAL ELECTRONICS

2 CALIBRATION GAS LINES

BY CUSTOMER

[300 FT (90 M) MAX]

LINE VOLTAGE

FIELDBUS COMPUTER

TERMINAL

33100003

Figure 1-3. Hazardous Area Oxymitter 5000 FOUNDATION Fieldbus Connections

Rosemount Analytical Inc. A Division of Emerson Process Management Description and Specifications 1-5

Instruction Manual

IB-106-350C Rev. 1.2 January 2002

Oxymitter 5000

GASES

STACK

HAZARDOUS AREA

OXYMITTER

5000

LINE

VOLTAGE

LOGIC I/O

FIELDBUS

DIGITAL

SIGNAL

REMOTE MOUNTED SPS 4000* OPTION

(WITH REFERENCE AIR

GASES

STACK

ADAPTER

PLATE

HAZARDOUS AREA

OXYMITTER

5000

LINE

VOLTAGE

OPTION)

STANDARD

DUCT

ADAPTER PLATE

FLOWMETER

CALIBRATION GAS

DUCT

CALIBRATION

GAS

INSTRUMENT AIR SUPPLY (REFERENCE AIR)

PRESSURE

REGULATOR

ADAPTER

PLATE

HAZARDOUS AREA

OXYMITTER

LINE

VOLTAGE

FIELDBUS

DIGITAL

SIGNAL

REFERENCE

AIR

GASES

STACK

5000

*NOTE:

IMPS 4000* OPTION

DUCT

CALIBRATION GAS

LIB

LOGIC I/O

THE IMPS 4000 OR SPS 4000 MUST BE INSTALLED IN A NON-HAZARDOUS, EXPLOSIVE-FREE ENVIRONMENT.

REFERENCE

AIR

IMPS 4000

FIELDBUS

DIGITAL

SIGNAL

LOGIC I/O

CALIBRATION

GAS 1

INSTRUMENT AIR SUPPLY

CALIBRATION GAS 2

RELAY OUTPUTS AND REMOTE CONTACT INPUT

LINE VOLTAGE

33100004

Figure 1-4. Typical System Installation

1-6 Description and Specifications Rosemount Analytical Inc. A Division of Emerson Process Management

Oxymitter 5000

If the calibration gas bottles will be permanently connected, a check valve is required next to the calibration fittings on the integral electronics. This check valve is to prevent breathing of the calibration gas line and subsequent flue gas condensation and corrosion. The check valve is in addition to the stop valve in the calibration gas kit or the solenoid valves in the IMPS 4000 or SPS

4000.

1-3 IMPS 4000 (OPTIONAL)

If using an IMPS 4000 with a Hazardous Area Oxymitter 5000, the sequencer must be installed in a non-hazardous, explosive-free environment. For further IMPS 4000 information, refer to the IMPS 4000 Intelligent Multiprobe Test Gas Sequencer Instruction Bulletin.

1-4 SPS 4000 (OPTIONAL)

Instruction Manual

IB-106-350C Rev. 1.2

January 2002

36220005

Figure 1-5. Flame Arrestor Ceramic Diffusion

Assembly

If using an SPS 4000 with a Hazardous Area Oxymitter 5000, the sequencer must be installed in a non-hazardous, explosive-free environment. For further SPS 4000 information, refer to SPS 4000 Single Probe Autocalibration Sequencer Instruction Bulletin.

1-5 PROBE OPTIONS

a. Flame Arrestor Ceramic Diffusion

Assembly

The flame arrestor ceramic diffusion assembly, Figure 1-5, includes a set of baffles between the cell and the stack gases. This keeps 816°C (1500°F) cell temperatures from igniting unburned fuel in the stack. The ceramic diffusion assembly is also available with a dust seal for use with the abrasive shield assembly.

b. Flame Arrestor Snubber Diffusion

Assembly

The flame arrestor snubber diffusion assembly, Figure 1-6, is satisfactory for most applications. This element is also available with a dust seal for use with an abrasive shield.

36220006

Figure 1-6. Flame Arrestor Snubber Diffusion

Assembly

c. Abrasive Shield Assembly

The abrasive shield assembly, Figure 1-7, is a stainless-steel tube that surrounds the probe assembly. The shield protects against particle abrasion and condensations, provides a guide for ease of insertion, and acts as a position support, especially for longer probes. The abrasive shield assembly uses a modified diffusor and vee deflector assembly, fitted with dual dust seal packing.

Rosemount Analytical Inc. A Division of Emerson Process Management Description and Specifications 1-7

Instruction Manual

IB-106-350C Rev. 1.2 January 2002

Oxymitter 5000

.187 .187

3.584

3.554

.45 MIN

VIEW A

ON INSIDE BREAK FOR SMOOTH ROUNDED EDGE ON BOTH ENDS OF CHAMFER

125

.187

6.00

SKIN CUT FACE FOR 90

VIEW B

22.5

0.75 THRU 4 PLS,

EQ SP ON 4.75 B.C.

NOTES:

16860033

1 WELD ON BOTH SIDES WITH EXPANDING

CHILL BLOCK.

2 BEFORE WELDING, BUTT ITEM 2 OR 4 WITH

ITEM 1 AS SHOWN.

.745

DIA ON A 7.50 DIA B.C. (REF)

.755

Figure 1-7. Abrasive Shield Assembly

NOTE

In highly abrasive applications, rotate the shield 90 degrees at normal

service intervals to present a new wear surface to the abrasive flow stream.

1-8 Description and Specifications Rosemount Analytical Inc. A Division of Emerson Process Management

Instruction Manual

IB-106-350C Rev. 1.2

Oxymitter 5000

1-6 SPECIFICATIONS

Hazardous Area Oxymitter 5000

Hazardous Area Certifications CENELEC EEx d IIB T2/T6

CSA NRTL/C Class I, Division 1, Groups C,D T2

Range:

Standard............................................. 0 to 10% O

0 to 25% O 0 to 40% O2 (via F

Accuracy .................................................... ±0.75% of reading or 0.05% O

System Response to Calibration Gas........ Initial response in less than 3 seconds

T90 in less than 8 seconds

Temperature Limits:

Process .............................................. 0° to 704°C (32° to 1300°F) up to 1300°C (2400°F)

with optional accessories

Electronics.......................................... -40° to 85°C (-40° to 185°F)

Operating temperature of electronics inside of instrument housing, as measured via F mount Asset Management Solutions software.

Probe Lengths............................................ 457 mm (18 in.)

0.91 m (3 ft)

1.83 m (6 ft)

Mounting and Mounting Position ............... Vertical or horizontal

Spool pieces are available, P/N 3D39761G02, to offset transmitter housing from hot ductwork.

Materials:

Probe.................................................. Wetted or welded parts - 316L stainless steel

Non-wetted parts - 304 stainless steel, low-copper aluminum

Electronics Enclosure ........................ Low-copper aluminum

Calibration.................................................. Manual, semi-automatic, or automatic

Calibration Gas Mixtures Recommended .. 0.4% O

8% O2, Balance N

Calibration Gas Flow ................................. 2.5 l/m (5 scfh)

Reference Air ............................................. 0.25 l/hr (0.5 scfh), clean, dry, instrument-quality air

(20.95% O

Electronics ................................................. NEMA 4X, IP66 with fitting and pipe on reference exhaust

port to clear dry atmosphere

Line Voltage ............................................... 90-250 VAC, 50/60 Hz. No configuration necessary.

3/4 in.-14 NPT conduit port. Signals:

Digital Output ..................................... F

OUNDATION

Logic I/O............................................. Two-terminal logic contact configurable as either an alarm

output or as a bi-directional calibration handshake signal to

IMPS 4000 or SPS 4000.

Self-powered (+5 V), in series with 340 ohms

Conduit ports — 3/4 in.-14 NPT (one threaded hole for both

analog output and logic I/O) Power Requirements:

Probe Heater...................................... 175 W nominal

Electronics.......................................... 10 W nominal

Maximum ........................................... 500 W

, Balance N

), regulated to 34 kPa (5 psi)

OUNDATION

fieldbus)

OUNDATION

fieldbus compatible

, whichever is greater

fieldbus, or Rose-

January 2002

Fisher-Rosemount has satisfied all obligations coming from the European legislation to harmonize the product requirements in Europe.

Rosemount Analytical Inc. A Division of Emerson Process Management Description and Specifications 1-9

Instruction Manual

IB-106-350C Rev. 1.2 January 2002

Table 1-1. Product Matrix

OXT5C Hazardous Area Oxymitter 5000 Explosion Proof In Situ Oxygen Transmitter

Explosion Proof Oxygen Transmitter - Instruction Book

Code Sensing Probe Type with Flame Arrestor

1 Ceramic Diffusion Element Probe (ANSI 3 in. 150 lb) 2 Snubber Diffusion Element (ANSI 3 in. 150 lb) 3 Ceramic Diffusion Element Probe (DIN 2527) - 1/4 in. Tube Fittings 4 Snubber Diffusion Element (DIN 2527) - 1/4 in. Tube Fittings 5 Ceramic Diffusion Element Probe (JIS) 6 Snubber Diffusion Element (JIS)

Code Probe Assembly

0 18 in. (457 mm) Probe 1 18 in. (457 mm) Probe with 3 ft Bypass 2 18 in. (457 mm) Probe with Abrasive Shield 3 3 ft (0.91 m) Probe 4 3 ft (0.91 m) Probe with Abrasive Shield 5 6 ft (1.83 m) Probe 6 6 ft (1.83 m) Probe with Abrasive Shield

(1)

Oxymitter 5000

Code Mounting Adaptor - Stack Side

0 No Adaptor Plate (“0” must be chosen under “Mounting Adaptor – Probe side” below) 1 New Installation - Square weld plate with studs 2 Model 218 Mounting Plate (with Model 218 Shield Removed) 3 Competitor’s Mount

(2)

Code Mounting Adaptor - Probe Side

0 No Adaptor Plate 1 Probe Only (ANSI) 2 New Bypass or New Abrasive Shield (ANSI) 4 Probe Only (DIN) 5 New Bypass or New Abrasive Shield (DIN) 7 Probe Only (JIS) 8 New Bypass or New Abrasive Shield (JIS)

Code Electronics Housing - NEMA 4X, IP66

11 Standard Filtered Termination 12 Transient Protected Filtered Termination

Code Operator Interface

(3)

1 Membrane Keypad - fieldbus

Code Language

1 English

2German

3 French

4 Spanish

5 Italian

OXT5C33111011 Continued Example

1-10 Description and Specifications Rosemount Analytical Inc. A Division of Emerson Process Management

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Specifications and Main Features

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TABLE OF CONTENTS

SAFETY INSTRUCTIONS

DESCRIPTION AND SPECIFICATIONS

1-2 SYSTEM OVERVIEW

1-3 IMPS 4000 (OPTIONAL)

1-4 SPS 4000 (OPTIONAL)