Upload
lenhan
View
222
Download
6
Embed Size (px)
Citation preview
TOWN OF CASTLE ROCK CANYONS SOUTH #1 WELL FACILITY AND PIPELINE
CONTRACT DOCUMENTS
DIVISION 17: INSTRUMENTATION & CONTROLS Section Title 17000 General Requirements for Process Instrumentation and Control Systems 17030 Testing 17211 Process Taps and Primary Elements 17212 Process Transmitters 17216 Process Switches 17310 Remote Terminal Units (RTU)
Integra Engineering 17000-1 CR37 6/29/2010
SECTION 17000
GENERAL REQUIREMENTS FOR PROCESS INSTRUMENTATION AND CONTROL SYSTEMS
PART 1 GENERAL 1.1 RELATED DOCUMENTS A. Drawings and General Provisions of Contract, including General and Supplementary
Conditions and Division 1 Specification Sections, apply to Work of this Section. Should there be any conflict between provisions or requirements elsewhere indicated and the provisions of this division, request written clarification by addendum prior to submission of bid or abide by the interpretation of the Engineer.
B. Instrument Index, Attachment 17000-A, appended to the end of this Section. C. Raceways and requirements for control and signal cables are specified in Division 16. 1.2 SUMMARY A. General: This section specifies general requirements which are applicable to all process
instrumentation and control systems. B Scope: The process instrumentation and control system shall include field-mounted
process variable transmitters and primary elements, control devices, programmable logic controllers, control panel assemblies, local control panels, signal conditioning equipment, and utility and support systems. The process instrumentation and control system shall be configured as specified herein and as indicated on the Drawings.
Work of this Specification shall include engineering, programming, furnishing, installing,
start-up, calibrating, and testing of all new hardware and software systems required for the construction, integration and commissioning of a complete process instrumentation and control system. Total integration of field-mounted instrumentation, control devices, and process equipment furnished and installed as work of this section of the Specifications, and of similar equipment furnished and installed as work of other sections shall be the responsibility of this section of the Specifications.
Radio data transmission, coordination with repeater station, and data download at the Ray
Waterman control facility shall be performed as part of the work of this contract. C. Work by Others: 1. Human Machine Interface: All computer hardware and software required for the
process control system human machine interface at the Ray Waterman control
Integra Engineering 17000-2 CR37 6/29/2010
center shall be provided by others and is not work of this contract. Human machine interface programming shall be performed by others and is not work of this contract.
D. Training and Documentation: Comprehensive training and system documentation shall
be provided for all systems furnished as work of this section of the Specifications. E. Drawings: Examine all Drawings relating to the project. Include all work, materials, and
equipment mentioned or shown as being provided under this division. Refer to all contract Drawings and details in coordinating and completing the work. Report any discrepancies, conflicts, or omissions; accomplish work required for conformance and/or completion. The Contractor shall examine the mechanical Drawings and specifications to determine actual locations, sizes, materials and ratings of process connections.
F. Specifications: Examine all specification divisions relating to the project. Include all
work, materials, and equipment mentioned as being provided under this division. Report any discrepancies, conflicts, or omissions; accomplish work require for conformance and/or completion.
1.3 SYSTEMS RESPONSIBILITY A. Systems Integrator: All instrumentation and control systems shall be provided under the
supervision of a single systems integrator, chosen by the Contractor, which is regularly engaged in the design and installation of such systems of similar scope and complexity. Contractor is responsible to the Owner for performance of all systems as specified.
The systems integrator, responsible for the integration of the process control and
instrumentation systems, shall bear the responsibility for configuration and documentation of the specified related systems in an effort to enhance complete system integration and facilitate system installation, startup, and commissioning. Construction drawings for these related systems shall be the product of the systems integrator.
System responsibility shall not be construed as to force equipment specified in Division 11
or Division 16 to be supplied by the Division 17 Contractor. Instead, system responsibility shall require the Division 17 Contractor to bear responsibility for the overall system coordination including but not limited to documentation, design, integration, and startup.
B. Acceptable Systems Integrators: The following companies are considered acceptable
systems integrators for performance of the work of Division 17 of these specifications. These systems integrators comply with the qualification requirements of this specification.
1. AmWest Control, Inc. 10175 E. 106th
Brighton, CO 80601 Avenue
Contact: Tom Majors
Integra Engineering 17000-3 CR37 6/29/2010
(303) 298-2115 [email protected] 2. Electrical Systems Consultants (ESC) 212 W. Mulberry
Fort Collins, CO 80521 Contact: Gene Whitney (970) 212-1491 [email protected] 3. RSI Company
385 North County Road 59 Livermore, CO 80536 Contact: Russ Ropken (970)221-0405 (970)420-0978 Cell [email protected]
1.4 QUALITY ASSURANCE, STANDARDS, DEFINITIONS, AND SYMBOLS A. General: Refer to Division 1 for general administrative/procedural requirements related
to compliance with codes and standards. Materials and workmanship shall comply with all applicable codes, specifications, local ordinances, industry standards, and utility company regulations. In case of difference between codes, state laws, local ordinances, industry standards, utility company regulations, and the contract documents, the most stringent shall govern.
B. Codes and Standards:
1. Electrical Code Compliance: Comply with applicable local code requirements of the authority having jurisdiction and the National Electrical Code, NFPA 70.
2. NEMA Compliance: Provide components which comply with the following
standards:
NEMA 250 Enclosures for Electrical Equipment (1000 Volts Maximum)
3. ISA Compliance: Provide methods and components which comply with the
following standards:
ISA RP-60.11 Crating, Shipping and Handling for Control Centers ISA S5.4 Instrument Loop Diagrams
Integra Engineering 17000-4 CR37 6/29/2010
ISA S20 Specification Forms for Process Measurement and Control Instrumentation, Primary Elements, and Control Valves
SA S51.1 Process Instrumentation Terminology
4. ANSI Compliance: Provide methods and components which comply with the following standards:
ANSI B16.5 Pipe Flanges and Flanged Fittings
5. API Compliance: Provide methods and components which comply with the
following standards:
API RP550 Manual on Installation of Refinery Instruments and Control Systems, Part I - Process Instrumentation and Control Sections 1 Through 13
6. ASTM Compliance: Provide methods and components which comply with the
following standards:
ASTM A269 Seamless and Welded Austenitic Stainless Steel Tubing for General Service
C. Definitions:
1. General: The definitions of terminology used in these Specifications shall be defined in ISA Standard S51.1 unless otherwise specified.
2. Solid State: Circuitry or components of the type which convey electrons by
means of solid material such as crystals or which work on magnetic principles such as ferrite cores. Vacuum tubes, gas tubes, slide wires, stepping motors, or other devices are not acceptable substitutes for solid state components or circuitry.
3. Integrated Circuit: A number of circuit elements inseparably associated on or
within a continuous body to perform the function of a circuit. 4. Two-Wire Transmitter: A transducer which derives operating power supply from
the signal transmission circuit and therefore requires no separate power supply connections. As used in this Specification, two-wire transmitter refers to a transmitter which produces a 4 to 20 milliampere current regulated signal in a series circuit with a 24 volt direct current driving potential and a maximum circuit resistance of 600 ohms.
5. Galvanic Isolation: Pertaining to an electrical node having no direct current path
to another electrical node. As used in this Specification, galvanic isolation refers
Integra Engineering 17000-5 CR37 6/29/2010
to a device with electrical inputs and/or outputs which are galvanically isolated from ground, the device case, the process fluid, and any separate power supply terminals, but such inputs and/or outputs are capable of being externally grounded without affecting the characteristics of the devices or providing path for circulation of ground currents.
6. Panel: An instrument support system which may be either a flat surface, a partial
enclosure, or a complete enclosure for instruments and other devices used in process control systems. Panels may provide mechanical protection, electrical isolation, and protection from dust, dirt, and chemical contaminants which may be present in the atmosphere. Panel shall include consoles, cabinets and racks.
7. Data Sheets: Data sheets as used in this Specification shall refer to ISA S20. 8. Signal Types: The following types of signals are used in systems specified in this
division.
a. Low Level Analog: A signal that has a full output level of 100 millivolts or less. This group includes thermocouples and resistance temperature detectors.
b. Digital Code: Coded information such as that derived from the output of
an analog to digital converter or the coded output from a digital computer or other digital transmission terminal. This type includes those cases where direct line driving is utilized and not those cases where the signal is modulated.
c. Pulse Frequency: Counting pulses such as those emitted from speed
transmitters. d. High Level Analog: Signals with full output level greater than 100
millivolts but less than 30 volts, including 4-20 mA transmission. e. Modulated Signals: Signals emanating from modems or low level audio
signals. Normal signal level is plus 4 dBm to minus 22 dBm. Frequency range is 300 to 10,000 hertz.
f. Discrete Events: Dry contact closures monitored by solid state equipment.
If the conductors connecting to dry contacts enter enclosures containing power or control circuits and cannot be isolated from such circuits in accordance with NEC Article 725, this signal shall be treated as low voltage control.
g. Low Voltage Control: Contact closures monitored by relays, or control
circuits operating at less than 30 volts and 250 milliamperes.
Integra Engineering 17000-6 CR37 6/29/2010
h. High Level Audio: Audio signals exceeding plus 4 dBm, including loudspeaker circuits.
i. Radio Frequency: Continuous wave alternating current signals with
fundamental frequency greater than 10 kilohertz.
9. Outdoors: Any instrument or equipment electrically connected to a power, control, or signal circuit that is installed in an underground raceway system that extends beyond the perimeter of the structure that either houses the instrument or equipment or houses the circuit termination point opposite the instrument or equipment shall be considered outdoors and provided the environmental and electrical protective features specified for the particular instrument or equipment.
D. Identification of Listed Products: Process instrumentation and control system components shall be listed for the purpose for which they are to be used, by an independent testing laboratory. Three such organizations are Underwriters Laboratories (UL), Canadian Standards Association (CSA), and Electrical Testing Laboratories (ETL). Independent testing laboratory shall be acceptable to the inspection authority having jurisdiction.
When a product is not available with a testing laboratory listing for the purpose for which
it is to serve, the product may be required by the inspection authority, to undergo a special inspection at the manufacturer's place of assembly. All costs and expenses incurred for such inspections shall be included in the original contract price.
E. Symbols: Except as otherwise indicated, refer to the symbols legend on the Drawings for
definitions of symbols used on the Drawings to show process instrumentation and control work.
F. Drawings: The Drawings included in this project manual are functional in nature and do
not show exact locations of equipment or interconnections between equipment. The Contractor, as part of his work, shall prepare detailed construction drawings as specified below. Drawings shall be prepared on a computer-aided drafting system as specified in paragraph 17000-1.6 B.
1. General: Drawings shall be prepared on 11-inch by 17-inch drafting media.
Drawings shall have borders and title blocks identifying the project, system, revisions to the drawing, and type of drawing. Each revision of a drawing shall carry a date and brief description of the revisions. Diagrams shall carry a uniform and coordinated set of wire numbers and terminal block numbers in compliance with panelwork wiring, Section 17110, to permit cross-referencing between contract documents and the drawings prepared by the Contractor.
2. Elementary and Loop Diagrams: The Contractor shall provide elementary
diagrams for all discrete loops. Loop diagrams shall be prepared in compliance with ISA S5.4 and shall be provided for all analog loops. Elementary diagrams
Integra Engineering 17000-7 CR37 6/29/2010
and loop diagrams shall show circuits and devices of a system. These diagrams shall be arranged to emphasize device elements and their functions as an aid to understanding the operation of a system and maintaining or troubleshooting that system. Elementary and loop diagrams shall also show wire numbers, wire color codes, signal polarities, and terminal block numbers.
Elementary and loop diagrams shall be completely and accurately documented and
cross-referenced to similar drawings for other related system such as motor control centers, equipment control panels, local control panels, field-mounted instruments, etc. All interfaces to remote systems shall include panel and /or equipment designations, wire numbers, and terminal designations.
3. Connection Diagrams: Connection diagrams for panels shall be provided by the
Contractor. Connection diagrams shall show components of a control panel in an arrangement similar to the actual layout of the panel. Internal wiring between devices within the panel shall be shown on these diagrams. Connection diagrams shall show all terminal blocks whether used for internal or field wiring. Those used for field wiring shall be clearly identified as such. Wiring diagrams shall indicate insulation color code, signal polarities, and shall show wire numbers and terminal block numbers.
4. Interconnection Diagrams: Interconnection diagrams shall be provided by the
Contractor for field wiring. Interconnection diagrams shall show each panel and field devices. Wire numbers, cable numbers, raceway numbers, terminal box numbers, terminal block numbers, panel numbers, and field device tag numbers shall be shown.
5. Panel Layout and Assembly Drawings: Panel layout and assembly drawings shall
provide dimensioned front and backpanel equipment layouts and sections showing clearances between face and rear mounted equipment. Drawings shall include a bill of materials, PLC layout and configuration, individual PLC module configuration switch settings, jumper positions, and final addressing of all communication network nodes.
1.5 SUBMITTALS A. General: The types of submittals required for process instrumentation and control work
are defined herein and are specified in each section of process instrumentation and control systems work. Administrative submittals are specified elsewhere in the contract documents. Submit the following in accordance with Conditions of Contract and Division 1 Specification Sections.
B. A copy of the respective specification section, with addendum updates included, and all
referenced and applicable sections, with addendum updates included, with each paragraph check-marked to indicate specification compliance or marked to indicate requested deviations from specification requirements. Check marks (in the margin adjacent to the
Integra Engineering 17000-8 CR37 6/29/2010
beginning of the paragraph) shall denote full compliance with a paragraph as a whole. If deviations from the specifications are indicated and, therefore requested by the Contractor, each deviation shall be underlined and denoted by a number in the margin to the right of the identified paragraph. The remaining portions of the paragraph not underlined will signify compliance on the part of the Contractor with the specifications. The submittal shall be accompanied by a detailed, written justification for each deviation. Failure to include a copy of the marked-up specification sections, along with justification(s) for any requested deviations to the specification requirements, with the submittal shall be sufficient cause for rejection of the entire submittal with no further consideration.
C. Elementary and loop diagrams specified in paragraph 17000-1.4. D. Connection and interconnection diagrams specified in paragraphs 17000-1.4. E. Instrument data sheets in accordance with ISA S20, together with a complete list of
instruments provided. F. Manufacturer’s product data for all specified equipment. Product data shall include
catalog cuts, technical specifications and application information. Product data shall be edited to indicate only those items, model, or series of equipment which are being proposed. All extraneous materials shall be crossed out or otherwise obliterated.
Product data shall be assembled in folders or three-ring binders. Each folder or binder
shall contain a cover sheet, indexed by item and cross-referenced to the appropriate specification paragraph.
G. Sizing calculations or power budgets for all power supply and conditioning equipment.
Calculations shall address both watt and volt-ampere components of the demand load. All assumptions made regarding load size or demand factor shall be clearly stated.
1.6 RECORD DRAWINGS AND SCHEDULES A. General: Drawings submitted in accordance with the requirements of paragraph 17000-
1.5 and all schedules included in Division 17 shall be provided as record drawings and submitted with the final Owner’s Manuals. Drawings shall reflect the final constructed state of the instrumentation and control systems.
B. Format: Computer-aided drafting (CAD) drawing files shall be converted .DXF file
format and submitted on CD-ROM media. All CAD drawing files shall be updated to reflect final as-constructed state of the process instrumentation and control system.
1.7 OWNER’S MANUALS A. General: Submittals shall be in accordance with Conditions of Contract and Division 1
Specification Sections and the requirements of this specification section. Owner’s
Integra Engineering 17000-9 CR37 6/29/2010
Manuals shall be submitted complete prior to commencing any startup or training activities; partial or incomplete data shall not be accepted.
B. Electronic Media: In addition to the specified hard copies of the O&M information, the
Contractor shall submit two (2) copies of the manufacturer’s instruction, operation, and maintenance manuals in portable document format (.pdf) if available from the manufacturer. The electronic manuals shall be submitted on CD-ROM.
C. Contact Information: Owner’s Manuals information shall include the names, addresses,
and telephone numbers of the manufacturer, the nearest representative of the manufacturer, and the nearest supplier of the manufacturer’s equipment and parts.
D. As-Built Control Wiring Diagrams and Assembly Drawings: As-built control diagrams
and assembly drawings as specified in paragraph 17000-1.6. E. Manufacturer’s Literature: Manufacturer’s literature shall include instructions for
installation, startup, calibration, operation, and troubleshooting of the equipment as published by the original equipment manufacturer. Literature shall include full specification of each item in the system with associated equipment serial numbers, operating ranges, and pertinent data.
F. User Manuals: User manuals shall include a detailed description of how each equipment
item operates and the procedures for installation, setup, programming, calibration and tuning of the equipment. A functional description of each operator control device, display, and indicator associated with the equipment shall be provided.
G. Setup, Configuration, and Nameplate Information: 1. General: A written record of the following information shall be provided in its
entirety. a. Setup and configuration parameters. b. Configuration switch/jumper positions. c. Nameplate information. 2. Applicable Equipment: Setup, configuration, and nameplate information shall be
provided for the following equipment types. The specified information shall be consolidated and organized by equipment item.
a. Process variable transmitters. b. Process analyzers. c. Process switches.
Integra Engineering 17000-10 CR37 6/29/2010
d. Signal conditioners. e. Solid state motor starters and overload relays. f. Reduced voltage starters. g. Adjustable frequency drives. H. Organization: Owner’s manuals shall be organized as individual volumes as described
below. Each volume shall be assembled in a slant D-ring binder sized to provide twenty percent spare binder capacity. Each volume shall include a table of contents with tabbed dividers.
1. Drawings: Binders for drawings shall be sized to accommodate the drawings in
their original size as specified in paragraph 17000-1.4. Drawings shall not be folded or otherwise reduced in size for assembly in the binder. Individual volumes shall be provided for each process facility with individual tabbed sections for each control panel, motor control center, or adjustable frequency drive located in the facility.
2. Process Instrumentation: Volumes for process instrumentation shall have major
sections organized by instrument type. Each major section shall have subsections that include the contact information, manufacturer’s literature, and user manuals for each instrument type followed by the setup, configuration, and nameplate information for each instrument of the associated type.
3. Motor Control Centers: Volumes shall include contact information,
manufacturer’s literature, and user manuals for all major equipment installed in the motor control centers including motor controllers, overload relays, circuit breakers, transient voltage suppression systems, and power monitoring systems. A separate section shall be provided in this volume that includes the applicable setup, configuration, and nameplate information in subsections organized by motor control center.
4. Adjustable Frequency Drives: Volumes shall include contact information,
manufacturer’s literature, and user manuals for adjustable frequency drives, both individual and those mounted in motor control centers. A separate section shall be provided in this volume that includes the applicable setup, configuration, and nameplate information in subsections organized by adjustable frequency drive.
5. Control Panel Hardware: Volumes shall include contact information,
manufacturer’s literature, and user manuals for all hardware systems mounted in control panels including power conditioning equipment, power distribution equipment, active and passive network hardware, and environmental control systems.
Integra Engineering 17000-11 CR37 6/29/2010
6. Programmable Logic Controllers: Volumes shall include contact information,
manufacturer’s literature, and user manuals in accordance with this specification and specification 17310. User manuals for this volume shall be printed copies of the electronic versions of the manuals specified in paragraph 17000-1.7 G.
PART 2 PRODUCTS 2.1 EQUIPMENT AND MATERIALS A. General: Equipment and material shall be new, free from defects, and of the quality
specified. Each type of instrument, instrument accessory, and device shall be by the same manufacturer throughout the work. Standard production materials shall be used wherever possible.
2.2 INSTRUMENT INDEX A. General: The Instrument Index, Table 17000-A, lists major instruments. The Contractor
shall provide all instrument functions specified on this list. Additional instruments may be required to complete the instrument loops because of certain characteristics of the particular equipment selected by the Contractor. Such additional instruments shall be provided at no additional cost even though not specified in the Instrument Index or on the Drawings.
B. Standard instruments shall be modified as necessary to meet the specified application
requirements. C. The Instrument Index does not identify process control and instrumentation equipment
considered incidental to the total integrated system such as enclosures, power supply and conditioning equipment, relays, signal isolators and surge protection, terminal blocks, electrical protective devices, etc. All such equipment shall be provided as specified in these Specifications for a complete, fully functional process instrumentation and control system.
2.3 SYSTEM RESOURCE CONFIGURATION A. General: The process instrumentation and control system shall be the total integration of
field-mounted instruments and control devices, equipment control panels, local control panels, and programmable logic controllers. The process instrumentation and control system configuration, architecture and functional requirements are defined by these Specifications, the Drawings, and the Instrument Index. The Specifications, Drawings, and the Instrument Index shall each be considered complementary to the other for complete definition of the system requirements. All work indicated by one but not the other and vice versa, shall be considered work of this Specification and shall be provided.
2.4 INSTRUMENT IDENTIFICATION
Integra Engineering 17000-12 CR37 6/29/2010
A. Identification Tags: All instruments, including process variable transmitters, analyzers,
and switches, shall be provided with a 316 stainless steel identification tag attached to the instrument with 316 stainless steel wire. The instrument tag number shall be stamped in the identification tag in 1/8-inch minimum height characters.
B. Instrument Labeling: Where space is provided on the instrument faceplate for user
labeling, an adhesive, machine-printed label with black lettering on white background shall be provided. The label shall identify the instrument tag number, description, and operating range with engineering units.
PART 3 EXECUTION 3.1 INSTALLATION A. General: Equipment shall be located so that it is readily accessible for operation and
maintenance. Where installation procedures are not specified herein, API RP550 shall be used as a guide.
B. Sensitive electronic equipment shall not be installed until all construction activities which
result in the production of any air borne matter such as dust, dirt, paint, etc., are completed. Such equipment includes, but not by way of limitation, programmable logic controllers, DC power supplies, uninterruptible power supplies, and network hardware.
C. Field Equipment: Equipment shall be provided as specified on the Drawings such that
ports and adjustments are accessible for in-place testing and calibration. Where possible, equipment shall be located between 48 inches and 60 inches above the floor or a permanent work platform. Instrumentation equipment shall be mounted for unobstructed access, but mounting shall not obstruct walkways. Equipment shall not be mounted where shock or vibration will impair its operation. Support systems shall not be attached to handrails, process piping or mechanical equipment except for measuring elements and valve positioners. Instruments and cabinets supported directly by concrete or concrete block walls shall be spaced out not less than 5/8 inch by framing channel between instrument and wall.
D. Support Systems: Support systems shall be constructed of materials complying with
Specification 16000-1.8. Support systems, including panels, shall be designed in accordance with Uniform Building Code for the applicable seismic zone and to prevent deformation greater than 1/8 inch under the attached equipment load and an external load of 200 pounds in any direction.
E. Electrical Connections:
1. General: Electric power wiring and equipment shall be in compliance with Division 16. Process instrumentation requiring a 120 volt AC power source shall be provided with a disconnect switch in accordance with Specification 16140-2.4.
Integra Engineering 17000-13 CR37 6/29/2010
2. Surge Suppression: Provide a surge arrestor downstream of each 120-volt AC
disconnect switch serving instrumentation equipment located outdoors. The surge suppressor shall be mounted in a conduit fitting or box in accordance with the requirements of Specification 16000-1.8. Surge arrester and associated wiring shall be installed to permit the protected conductors to be routed out of the opposite end of the conduit fitting or box from the unprotected conductors. Surge arrestors shall be in accordance with Specification 17130.
3. Signal Connections: Electric signal connections to equipment shall be made on
terminal blocks or by locking plug and receptacle assemblies. 4. Conduit Connections: Liquidtight flexible conduit shall be used between
equipment and rigid raceway systems except that flexible cable assemblies may be used where plug and receptacle assemblies are provided and the installation is not subject to mechanical damage in normal use. The length of flexible conduit or cord assemblies shall not exceed 2 feet. Flexible cable, receptacle and plug assemblies shall be used only where specified.
F. Signal Transmission:
1. Analog Signals: Signal transmission between electric or electronic instruments shall be 4 to 20 milliamperes and shall operate at 24 volts DC unless otherwise specified. Milliampere signals shall be current regulated and shall not be affected by changes in load resistance within the unit's rating. Measurement loops shall be grounded at external terminals by bonding to the instrument panel signal ground bus. The Contractor shall provide isolating amplifiers for field equipment possessing a grounded input or output.
2. Discrete Signals: Relay or switch contact configurations shall be as follows:
a. Alarms: Contact outputs used for alarm initiation shall be normally closed
and shall open to initiate the alarm. b. Control: Contact outputs used to control equipment shall be normally
open and shall close to initiate equipment operation. c. Status: Contact outputs used to indicate equipment operating status shall
be normally open and shall close to indicate the active (run, ready, etc.) status.
3. Platinum resistance temperature detector (RTD) outputs shall be converted to
milliampere transmission signals at the RTD; or, where specified, the RTD output may be carried to the panel and converted to a DC voltage signal.
Integra Engineering 17000-14 CR37 6/29/2010
4. All other transmission systems, such as impulse duration, low frequency pulse rate, and voltage regulated, will not be permitted except where specifically noted in the Instrument Index. When transmitters with nonstandard outputs are specified, their output shall be converted to 4 to 20 milliamperes at the field instrument.
5. Two-wire equipment located in hazardous areas shall be made safe for the
specified conditions by use of intrinsic safety barriers approved by Underwriters Laboratories Inc. (UL), Canadian Standards Association (CSA), or Factory Mutual (FM).
3.2 DELIVERY, STORAGE, AND HANDLING A. Deliver materials and equipment properly packaged. Utilize factory fabricated containers
or wrappings for materials and equipment which protect materials and equipment from damage. All process control and instrumentation systems and equipment shall be stored in a clean, dry, temperature-controlled location. Inspect materials and equipment to ensure that no damage has occurred during shipment.
B. Store materials and equipment in original packaging and protect from weather and
construction traffic. Wherever possible, store indoors; where necessary to store outdoors, store above grade and enclose with watertight wrapping.
C. Handle materials and equipment carefully to prevent physical damage to materials and
equipment. Remove packaging, including the opening of crates and containers, avoiding the use of excessive hammering and jarring which could damage the materials and equipment contained therein. Do not install damaged materials or equipment; remove from site and replace damaged materials and equipment with new.
3.3 HOUSEKEEPING A. Process instrumentation and control systems shall be protected from dust, water and
damage during the construction period. B. Upon completion of the work, remove all litter, waste material, unused materials, and
Contractor’s tools and equipment from the job site. C. Thoroughly clean and remove all residue from interior surfaces. D. Clean exterior surfaces of all materials and equipment and leave in an unblemished
condition. 3.4 TESTING A. Testing shall be performed by the Contractor in accordance with Specification 17030.
Integra Engineering 17000-15 CR37 6/29/2010
3.5 INSTRUMENT INDEX
END OF SECTION
Integra Engineering 17000-16 CR37 6/29/2010
INSTRUMENT INDEX (Appended to Specification Section 17000) The following is an index of the instrumentation equipment and devices to the provided as work of this Contract. Clarification of Headings:
1. TAG NUMBER: The instrument tag number consists of a two- or three-letter prefix (indicating the instrument function) followed by a number identifying the process loop with which the instrument is associated.
2. DESCRIPTION: Provides an abbreviated functional description of the instrument
or device. 3. SPECIFICATION: Identifies the specification section in which the instrument is
specified. 4. RANGE: Provides the calibrated instrument range for each application. 5. SETPOINT: Provides the final calibrated switch setpoint. 6. DRAWING: Identifies the process and instrumentation drawing which indicate
the location of the instrument. 7. DETAIL: References the installation detail applicable to the instrument. 8. NOTES: Additional data pertinent to the application of the instrument.
Instrument IndexTag Number Description Specification Range Setpoint Drawings Detail Notes
FE 101 Flow Tube/Denver Well Discharge 17212-FM FIT 101 Flow Transmitter/Denver Well Discharge 17212-FM
FE/FI 101 Flow Indicator/Denver Well Blowoff 17212-FPPI 101 Pressure Gauge/Denver Well Discharge 17211-PG 0-150 PSIG N/A
PSH 101 Pressure Switch/Denver Well Discharge 17216-PS
FE 117 Flow Tube/Arapahoe Well Discharge 17212-FMFIT 117 Flow Transmitter/Arapahoe Well Discharge 17212-FM
FE/FI 117 Flow Indicator/Arapahoe Well Blowoff 17212-FPPI 101 Pressure Gauge/Arapahoe Well Discharge 17211-PG 0-150 PSIG N/A
PSH 117 Pressure Switch/Arapahoe Well Discharge 17216-PS
HC 01 Entry Keypad/Electrical RoomHC 02 Entry Keypad/Piping Room
LSH CS1 Level Switch/Piping Room Flood Detection 17216-LVSPIT CS1 Pressure Transmitter/Canyons South #1
Discharge17212-PGT
TS 03 Temperature Switch/Ventilation Control Panel
17216-TS
TSH CS1 Temperature Switch/Electrical Room 17216-TSTSL CS1 Temperature Switch/Piping Room 17216-TS
ZS1A 01 Intrusion Switch/Electrical RoomZS1A 02 Intrusion Switch/Piping RoomZS1A 03 Intrusion Switch/Denver Well Pitless Adapter
ZS1A 04 Intrusion Switch/Arapahoe Well Pitless Adapter
17000Attachment A
Page 1 of 1
Integra Engineering 17030-1 CR37 6/29/2010
SECTION 17030
TESTING PART 1 GENERAL 1.1 RELATED DOCUMENTS A. Drawings and General Provisions of Contract, including General and Supplementary
Conditions and Division 1 Specification Sections, apply to Work of this Section. Should there be any conflict between provisions or requirements elsewhere indicated and the provisions of this division, request written clarification by addendum prior to submission of bid or abide by the interpretation of the Engineer.
1.2 SUMMARY A. This section specifies the acceptance testing of the process control and instrumentation
systems including the graphical operator interface, programmable logic controllers, process instrumentation and ancillary support equipment and systems. Contractor shall provide all labor, tools, material, power and other services necessary to provide the specified tests.
B. Requirements for testing in accordance with this section are specified in this and other
sections of Division 17. Where testing in accordance with this section is required, the required tests, including correction of defects where found, and subsequent retesting, shall be completed prior to commissioning any equipment or systems.
1.3 SUBMITTALS A. General: Submit the following in accordance with the requirements of Specification
17000. 1. Test procedure documentation report.
2. Examples of test report forms for all specified tests.
3. Sample inspection deficiency report.
4. Listing of instruments to be factory calibrated.
5. Final test report.
6. Instrument technician certification.
7. A copy of this specification section, with addendum updates included, and all referenced and applicable sections, with addendum updates included, with each paragraph check-marked to indicate specification compliance or marked to indicate requested deviations from specification requirements. Check marks (in
Integra Engineering 17030-2 CR37 6/29/2010
the margin adjacent to the beginning of the paragraph) shall denote full compliance with a paragraph as a whole. If deviations from the specifications are indicated and, therefore requested by the Contractor, each deviation shall be underlined and denoted by a number in the margin to the right of the identified paragraph. The remaining portions of the paragraph not underlined will signify compliance on the part of the Contractor with the specifications. The submittal shall be accompanied by a detailed, written justification for each deviation. Failure to include a copy of the marked-up specification sections, along with justification(s) for any requested deviations to the specification requirements, with the submittal shall be sufficient cause for rejection of the entire submittal with no further consideration.
PART 2 PRODUCTS 2.1 TEST EQUIPMENT AND MATERIALS A. General: Test instruments shall be calibrated to references traceable to the National
Institute of Standards and Technology and shall have a current sticker showing date of calibration, deviation from standard, name of calibration laboratory and technician, and date recalibration is required.
PART 3 EXECUTION 3.1 GENERAL A. All process instrumentation and control system testing shall be conducted by the
installing contractor and shall be performed in strict conformance with the process instrumentation and control systems test procedures. The process instrumentation and control test procedures shall be developed by the installing contractor in accordance with the requirements of this specification and approved by the Construction Manager. The types of equipment and/or systems to be inspected and tested shall be as specified herein.
B. Materials, equipment, and systems included as work of the Division 17 specifications
shall be inspected and tested by the Contractor as specified herein. 3.2 TECHNICIAN QUALIFICATIONS A. Each instrument shall be calibrated and tested on site by an instrument technician who, by
virtue of attendance at an acceptable control systems technician certification program is qualified to calibrate that instrument. Acceptable training shall include successful completion of the instrument manufacturer's training course or certification through The Instrumentation, Systems, and Automation Society Certified Control Systems Technician program. Evidence of certification shall be submitted as specified in paragraph 17030-1.3.
Integra Engineering 17030-3 CR37 6/29/2010
3.3 DOCUMENTATION A. Test Procedures: 1. Test procedures shall be fully developed by the Contractor and submitted to the
Construction Manager for approval no later than 180 days from the date of Notice to Proceed. A written report shall be prepared which details the test procedures for each analog and discrete loop in the process control system. The test procedure documentation report shall be organized and assembled in separate volumes for each process area or facility.
2. Test procedure documentation shall include a detailed, step-by-step description of
the required test procedure, panel and terminal block numbers for point(s) of measurement, input test values, expected resultant values, test equipment required, process setup requirements, and safety precautions. Test report forms for each loop, including forms for wiring, piping, and individual component tests, shall be included with the test procedure documentation. The actual test results shall be recorded on these forms and a final test report assembled as specified in paragraph 17030-3.11.
B. Test Report Forms: Test report forms which appropriately and completely address field
test procedures shall include, but not by way of limitation, the following information. Test report forms shall be preprinted and completed to the extent possible prior to commencing testing.
1. Project name.
2. Process area or facility associated with the equipment under test.
3. Instrument/loop description.
4. Instrument/loop identification number.
5. Instrument nameplate data.
6. Instrument setup and configuration parameters.
7. Time and date of test.
8. Inspection checklist and results.
9. Reference to applicable test procedure.
10. Expected and actual test results for each test point in the loop including programmable controller data table or register values.
11. Test equipment used.
12. Space for remarks regarding test procedure or results, unusual or noteworthy observations, etc.
13. Name and signature of testing personnel.
Integra Engineering 17030-4 CR37 6/29/2010
14. Name and signature of test witness. 3.4 PERFORMANCE DEVIATION TOLERANCES A. Tolerances shall be determined from applicable contract requirements. Where tolerances
are not specified, they shall be determined from manufacturer's published performance specifications. Overall accuracy requirements for loops consisting of two or more components shall be the root-summation-square (RSS) of the individual component accuracy specifications. Tolerances for each required calibration point shall be calculated and recorded on the associated test report form.
3.5 FACTORY-CERTIFIED TEST REPORTS A. Where field calibration is not feasible, certified instrumentation calibration reports may
be submitted for field calibration reports subject to the prior written approval of the Construction Manager. A request to submit certified calibration reports in lieu of field calibration reports shall include the name and address of the laboratory selected to conduct the calibration testing and a detailed description of the field test and inspection activities which will be performed to supplement off-site calibration activities in order to insure proper installation and freedom from damage subsequent to the off-site calibration. Field test and inspection activities shall include verification of instrument parameter setup, verification of instrument zero, and verification of operation at three operating points within the instrument range.
B. Certified test reports may be submitted for the following instrument types in lieu of field
calibration:
Instrument Type Description FM (Section 17212) Magnetic flow metering system
C. No further range adjustments (zero and span) or parameter adjustment shall be permitted
on instruments accepted as off-site calibrated. Any instrument which fails to demonstrate proper performance or is adjusted in the field shall be returned for re-calibration.
3.6 TEST EQUIPMENT AND MATERIALS A. General: Contractor shall provide all test equipment required to conduct the specified
tests. Test equipment used to simulate inputs and read outputs shall have a rated accuracy at the point of measurement at least three times greater than the component under test. Each test instrument shall have a current calibration sticker showing date of calibration, deviation from standard, name of calibration laboratory and technician, and date recalibration is required. Certified calibration reports traceable to the National Institute of Standards and Technology shall be included with the final test report.
Integra Engineering 17030-5 CR37 6/29/2010
B. Buffer/Reference Solutions: The Contractor shall provide buffer solutions and reference fluids required for all tests of analytical equipment.
3.7 FIELD TESTS AND INSPECTION PROCEDURES A. Inspection and Test Sequence: Inspection and test procedures shall be conducted in the
following sequence. Successful completion of each activity shall be required prior to proceeding to the subsequent activity. Each instrument loop shall be tested in the following sequence:
1. Wiring and piping tests
2. Inspection
3. Individual component test
4. Loop test
5. Functional checkout B. Piping Testing: Pneumatic and instrument piping systems shall be tested for leaks in
compliance with ISA RP7.1, except that the test shall be performed at ten times the normal system operating pressure.
C. Wiring Testing: Wiring tests shall be conducted in accordance with specification 16030.
Wiring tests shall not be conducted until cables have been properly terminated, tagged and inspected.
D. Inspection: Each component of the process control and instrumentation system shall be
inspected for conformance with this specification and applicable industry standards. All instruments and system components shall be inspected including instruments approved for off-site calibration. Inspection activities shall include the following:
1. Compare and validate instrument type and nameplate data with the drawings,
specifications, and data sheet.
2. Validate instrument identification tag.
3. Confirm instrument installation conforms to the drawings and specifications and manufacturers instructions.
4. Verify proper conductor termination and tagging.
5. Visually inspect for signs of physical damage, dirt accumulation and corrosion.
6. Verify that all applicable ancillary devices including isolation amplifiers, surge protection, and safety barriers have been provided and properly installed.
7. All deficiencies identified as a result of the inspection procedures shall be recorded on the inspection deficiency form and reported to the Construction
Integra Engineering 17030-6 CR37 6/29/2010
Manager within 24 hours of discovery. No instrument or system component shall be tested until all deficiencies are addressed.
E. Individual Component Calibration and Test: 1. Each receiving and transmitting instrument including programmable logic
controller input/output subsystems and final elements shall be field calibrated in accordance with the manufacturer's recommended procedure. Instruments shall then be tested in compliance with ISA S51.1 and the data entered on the applicable test form. Alarm trips, control trips, and switches shall be set to initial values specified in the Instrument Index, Table 17000-A. Final elements shall be checked for range and deadband.
2. Each analog instrument shall be calibrated at 0, 10, 50, 90, and 100 percent of its
specified full scale range. Each signal sensing trip and process sensing switch shall be adjusted to the required setting. All test data shall be recorded on test forms in compliance with this specification.
3. Final element alignment shall be tested and adjusted to verify that each final
element operates smoothly over its range in response to the specified process control signals.
4. The output configuration of process switches and similar digital signal devices
shall be verified to comply with the requirements of specification 17000-3.1 F.2. 5. Any component which fails to meet the specified tolerances shall be repaired by
the manufacturer or replaced, and the above tests repeated until the component is within tolerance.
6. A calibration sticker shall be placed on each instrument following successful
calibration. The calibration sticker shall indicate the date of calibration and the name of the testing company and personnel who calibrated the instrument.
F. Loop Test: 1. Each instrument and control loop shall be tested as an integrated system. This test
shall check operation from the field device or signal source to all receiving components or final elements within the loop and verification of the data handling functions through the process control system programmable logic controllers. Signals shall be injected at the signal connection to primary measuring elements or signal source.
2. Testing of loops which include an interface to a programmable logic controller
shall include verification of the programmable logic controller input/output assignment and verification of operation of the input/output system and processor.
Integra Engineering 17030-7 CR37 6/29/2010
The appropriate data table or register in the programmable logic controller memory shall be inspected and manipulated (in the case of output functions) to verify proper operation of these systems.
3. The normal operating state of all programmable logic controller digital input
circuits shall be verified to comply with the configuration requirements specified. 4. If any output device fails to indicate properly, corrections to the loop circuitry
shall be made as necessary and the test repeated until all instruments operate properly
G. Functional Checkout: Functional testing shall be conducted to verify the operation of the
process control system including the operator interface, programmable logic controller control logic, and hardwire interlocks and control circuits. Checkout shall consist of exercising all operator interface functions including the field control stations and energizing each control circuit and operating each control, alarm or malfunction device and each interlock in turn to verify that the specified action occurs.
3.8 NOT USED 3.9 POWER CONDITIONING EQUIPMENT TESTS A. General: Power conditioning systems shall be tested in accordance with the
manufacturer’s instructions to demonstrate proper operation. In addition, power conditioning system tests shall include a functional checkout of the equipment to verify the operational integrity of all system controls, indicators, and input/output signals. The input and output voltages shall be measured both unloaded and under system load.
B. Uninterruptible Power Supply (UPS) Systems: UPS systems shall be tested in both the
line and battery mode. UPS system output voltage and current shall be recorded in the battery mode of operation at 10-minute intervals for the duration that the UPS system supports the connected load or one hour (maximum). All test results shall comply with manufacturer’s specifications.
C. Test Results: The test results shall be recorded and submitted with the final test report. 3.10 EQUIPMENT TESTING A. General: The inspection and test procedures described herein shall establish the
minimum requirements for process instrumentation and control system equipment and component inspection and testing. Additional testing required by the equipment manufacturer for proper installation and commissioning of the process control and instrumentation system shall be conducted by the contractor at no additional cost to the Owner.
Integra Engineering 17030-8 CR37 6/29/2010
B. Equipment Tests: The following types of equipment and/or systems shall be inspected and tested by the Contractor:
1. Process variable transmitters.
2. Process switches.
3. Signal conditioning modules.
4. Power conditioning equipment.
5. Programmable logic controllers including all input/output subsystems. 3.11 FINAL TEST REPORT A. General: A final test report shall be assembled in a 3-ring binder and submitted to the
Construction Manager at the completion of the inspection and testing activities for a process area or facility. Binder cover and spline shall be labeled to identify the project name and process area or facility. Test report shall include all applicable test procedures for the process area, the completed inspection and test report forms associated with the equipment and systems of that area, and the final instrument setup and configuration parameter listing. Test results shall be organized by equipment item or system with individual, labeled tab dividers to identify each. All system deficiencies and non-compliant test results identified in the final test report shall be acknowledged by the responsible testing entity as corrected. All electronic calibration files shall be submitted with the final test report on CD-ROM media.
END OF SECTION
Integra Engineering 17211-1 CR37 6/29/2010
SECTION 17211
PROCESS TAPS AND PRIMARY ELEMENTS PART 1 GENERAL 1.1 RELATED DOCUMENTS A. Drawings and General Provisions of Contract, including General and Supplementary
Conditions and Division 1 Specification Sections, apply to Work of this Section. Should there be any conflict between provisions or requirements elsewhere indicated and the provisions of this division, request written clarification by addendum prior to submission of bid or abide by the interpretation of the Engineer.
1.2 SUMMARY A. This section specifies requirements for instrumentation elements that quantitatively
convert the measured variable energy into a form suitable for measurement and process measurement accessories.
1.3 SUBMITTALS A. Submittals shall be provided in accordance with the requirements of Specification 17000. 1.4 QUALITY ASSURANCE A. Manufacturer’s Qualifications: Firms regularly engaged in the manufacture of primary
elements and process taps and accessories of types, sizes, and ratings required, whose products have in satisfactory use in similar service for not less than 5 years.
B. Installer’s Qualifications: Firms with at least 3 years of successful installation experience
on projects utilizing primary elements and process taps and accessories similar to those required for this project.
PART 2 PRODUCTS 2.1 VALVES A. Isolation Valves: Valves shall be full port ball valves with 316 stainless steel trim and
body and with Teflon seats and packing. Valves shall be Parker CPI, Whitey, Hoke, or approved equivalent.
B. Gage Valves: Gage valves shall be machined from 316 stainless steel bar stock and shall
be provided with a metal seat, 1/2-inch NPT connections, and an integral bleed valve.
Integra Engineering 17211-2 CR37 6/29/2010
Valves shall be Anderson Greenwood Instrumentation Products Model M9 or approved equivalent.
C. Root Valves: Root valves shall be type 316 stainless steel bar stock with 1/2-inch NPT
male process connection and three 1/2-inch NPT female instrument connections. One instrument connection shall be provided with a type 316 stainless steel bleed valve. 316 stainless steel plugs shall be provided for unused ports. Lagging type units shall be provided for insulated vessels and pipes. Root valves shall be Anderson Greenwood Instrumentation Products Model M5 or approved equivalent.
D. Manifolds: Manifolds shall be multi-valve bar-stock type. Manifold body shall be
machined from ASTM, type 316 stainless steel bar stock. Instrument process connections shall be flanged. Valves shall be globe configuration with 316 stainless steel ball seats and Teflon stem packing. Fabricated manifolds or manifolds employing needle or soft seat valves are not acceptable. Manifolds shall be designed for mounting on an instrument pipe stand. Associated pressure instrumentation shall be directly mounted to and supported from the valve manifold.
1. Three-Valve Manifolds: Manifolds shall be designed for direct mounting to
differential pressure transmitters. Manifold shall be provided with an integral test port. Manifolds shall be Anderson Greenwood Instrumentation Products M4A or approved equivalent.
2. Two-Valve Manifolds: Manifolds shall be designed for block and bleed, test and
calibration, and zeroing of gauge pressure instruments. Vent/calibration port shall be fitted with a bleed valve. Manifolds shall be Anderson Greenwood Instrumentation Products Model MP1 or approved equivalent.
2.2 TUBING AND TUBING FITTINGS A. Tubing: Instrument tubing shall be ASTM A-269 type 316 seamless stainless steel.
Tubing shall be 1/4-inch outside diameter by 0.03 inch wall thickness or 1/2-inch outside diameter by 0.035-inch wall thickness as indicated on the Drawings.
B. Fittings: Tubing fittings shall be type 316 stainless steel. Fittings shall be of the swage
ferrule design and shall have components (nut, body and ferrule system) interchangeable with those of at least one other manufacturer. Flare and ball sleeve compression type are not acceptable. Fittings shall be Parker CPI, Crawford Swagelok, Hoke Gyrolok, or approved equivalent.
C. Flexible Coupling: Flexible coupling shall be 1/2-inch type 316 stainless steel braided
hose with integral tube end adapters. Minimum coupling length shall be 12 inches. D. Tubing Support Systems: Tubing support system shall consist of a two-piece support
body, cover plate with hex head bolts, rail nuts, and mounting rail. Cover plate, hex head
Integra Engineering 17211-3 CR37 6/29/2010
bolts, rail nuts and mounting rail shall be of stainless steel construction. Support body shall be of polypropylene construction. Support body size shall be selected to match the outside diameter of the tubing for each application. Tubing support system shall be as manufactured by Swagelok or approved equivalent.
2.3 CHEMICAL SEALS A. Diaphragm: Seal shall be the diaphragm type with flushing connection, type 316 stainless
steel body and type 316L diaphragm unless otherwise specified. Seal shall be Mansfield and Green Type SG, Ashcroft Type 101, or approved equivalent.
B. Annular: Seal shall be the in-line full stream captive sensing liquid type. Metallic wetted
parts shall be 316 stainless steel. Flexible cylinder shall be Buna-N unless otherwise specified. Seals shall be rated 200 PSIG with not more than 5-inch WC hysteresis. Seals shall be Ronningen-Petter Iso-Ring, Red Valve series 40, or approved equivalent.
Annular seals for sodium hypochlorite service shall have Hastelloy-C lower housings and
Teflon diaphragms. Seals shall be threaded NPT type and shall be Ashcroft, 204, or approved equivalent.
C. Fill Fluid: Chemical seals and associated instruments shall be factory filled as follows: 1. Instrument side of seal, capillary tubing, and instrument shall be evacuated to an
absolute pressure of 1.0 Torr or less; filled; and sealed. Unless otherwise specified, fill fluid shall be silicone oil, Dow Corning DC200, Syltherm 800, or approved equivalent.
2.4 INSTRUMENT STANDS A. Floor Stand: Floor stand shall be vertical mount, 2-inch diameter, 52-inch high, Schedule
40, steel pipe with 1/4-inch x 10-inch x 10-inch carbon steel baseplate. Instrument stand shall be full-perimeter welded at baseplate and shall have two ¼-inch gussets welded 90 degrees apart. Baseplate shall have 1.5 inch by 0.62 inch slotted openings in each corner to accommodate mounting hardware. Instrument stand shall be metallized with pure zinc. Instrument stand shall be as manufactured by O’brien Corporation Saddlepak System, Model FP52 or approved equivalent.
B. Wall Stand: Wall stand shall be vertical mount, 2-inch diameter, 16-inch high, Schedule
40, steel pipe with 1/4-inch x 6.5-inch x 6.5-inch carbon steel baseplate. Instrument stand shall be full-perimeter welded at baseplate. Baseplate shall have 0.88 inch by 0.44 inch slotted openings in each corner to accommodate mounting hardware. Instrument stand shall be metallized with pure zinc. Instrument stand shall be as manufactured by O’brien Corporation Saddlepak System, Model WE16M or approved equivalent.
2.5 PRIMARY ELEMENT SPECIFICATION SHEETS
Integra Engineering 17211-4 CR37 6/29/2010
A. General: General requirements for primary elements specified in this section are listed on
Primary Element Specification Sheets in paragraph 17211-3.6. Application requirements are specified in the Instrument Index, Table 17000-A and/or on the Drawings.
PART 3 EXECUTION 3.1 INSPECTION A. General: Examine areas and conditions under which primary elements and process taps
are to be installed. Notify Contractor in writing of conditions detrimental to proper completion of the work. Do not proceed with work until unsatisfactory conditions have been corrected in a manner acceptable to the Installer.
3.2 PROTECTION A. General: Protect installed components from damage. Replace damaged items prior to
final acceptance. 3.3 INSTALLATION OF PRIMARY ELEMENTS A. Unless otherwise specified, process taps shall comply with API RP550. Root valves shall
be provided at taps, except temperature taps and pump discharge pressure taps. Process connections shall be arranged, where possible, such that instruments may be readily removed for maintenance without disruption of process units or draining of large tanks or vessels. Unions or flange connections shall be provided as necessary to permit removal without rotating equipment. Where process taps are not readily accessible from instrument locations, an isolation valve shall be provided at the instrument. Isolation valves shall also be provided for each instrument where multiple instruments are connected to one process tap.
B. Primary elements shall be provided as specified on the Drawings such that ports and
adjustments are accessible for in-place testing and calibration. C. Tubing supports shall be provided at 3-foot intervals for ¼-inch tubing and 4-foot
intervals for ½-inch tubing. Mounting rail length shall be 6-inches, minimum. 3.4 FIELD ADJUSTMENTS AND TESTING A. Calibration and Testing: Primary elements shall be calibrated and tested in accordance
with the manufacturer’s instructions and Specification Section 17030. B. Cleaning: Touch-up scratched or marred enclosure surfaces to match original finishes.
Remove all dust, debris, paint, and other foreign material from the primary element and associated components.
Integra Engineering 17211-5 CR37 6/29/2010
3.5 TRAINING A. General: The Contractor shall provide services of a factory-trained instructor for the
purpose of training the Owner's personnel in the proper operation and maintenance of primary elements where specified on the respective Primary Elements Specification Sheet.
3.6 PRIMARY ELEMENTS SPECIFICATION SHEETS A. The following Primary Elements Specification Sheets are included in this section:
Primary Element Type Primary Element Description
PG
Primary Element Function
Pressure Gauge Pressure measurement
Integra Engineering 17211-6 CR37 6/29/2010
PRIMARY ELEMENT SPECIFICATION SHEET – PG Primary Element Identification: PG Primary Element Function: Pressure measurement Primary Element Description: Pressure gage Power Supply: N/A Signal Input: N/A Signal Output: N/A Process Connection: 1/2-inch male NPT Product Requirements: General: Pressure gages shall be 4-1/2-inch premium grade,
glycerin filled units with bourdon tube element, 270-degree milled stainless steel movement, phenolic case, and shatterproof glass window. Bourdon tube material of construction shall be 316L stainless steel. Accuracy shall be one percent of span or better. All exposed metal parts shall be stainless steel.
Acceptable Manufacturers: Ashcroft Duragauge Figure 1279, Ametek 1981L, or
approved equivalent. Execution: Installation: Install in accordance with manufacturer's instructions and
the recommendations of API RP550 to the specified requirements.
Root valves shall be provided at all process pressure taps
except taps made for safety instruments. Gage valves shall be provided at the instrument where the instrument is not within sight of the root valve or where two or more instruments are connected to a single tap. Safety instruments shall not be connected to the same process tap as instruments used for control, indication, or recording.
Integra Engineering 17211-7 CR37 6/29/2010
PRIMARY ELEMENT SPECIFICATION SHEET – PG (continued)
Unless otherwise specified, pressure instruments shall be located as close as practical to the process tap but shall be positioned to permit observation and maintenance. Pressure gages may be supported from the process tap if this location permits observation from the floor or a permanent work platform. Pressure instruments shall be
installed in such a manner that blowout discs are not obstructed.
Application: Application and ranges shall be in accordance with
manufacturer’s recommendations and as specified in the Instrument Index.
Test and Calibration: In accordance with Section 17030.
END OF SECTION
Integra Engineering 17212-1 CR37 6/29/2010
SECTION 17212
PROCESS TRANSMITTERS PART 1 GENERAL 1.1 RELATED DOCUMENTS A. Drawings and General Provisions of Contract, including General and Supplementary
Conditions and Division 1 Specification Sections, apply to Work of this Section. Should there be any conflict between provisions or requirements elsewhere indicated and the provisions of this division, request written clarification by addendum prior to submission of bid or abide by the interpretation of the Engineer.
B. Section 17211, Process Taps and Primary Elements, applies to Work of this Section. 1.2 SUMMARY A. This section specifies requirements for process variable transmitters. B. Application requirements for each transmitter are specified in the Instrument Index, Table
17000-A, appended to the end of Section 17000. 1.3 SUBMITTALS A. Submittals shall be provided in accordance with the requirements of Specification 17000. 1.4 QUALITY ASSURANCE A. Manufacturer’s Qualifications: Firms regularly engaged in the manufacture of process
variable transmitters of types, sizes, and ratings required, whose products have in satisfactory use in similar service for not less than 5 years.
B. Installer’s Qualifications: Firms with at least 3 years of successful installation experience
on projects utilizing process variable transmitters similar to those required for this project.
Integra Engineering 17212-2 CR37 6/29/2010
PART 2 PRODUCTS 2.1 GENERAL A. Unless otherwise specified, measuring elements and transmitters shall comply with the
following requirements: 1. Transmitters shall be provided with integral indicators. Indicators shall be
calibrated in process units, and said units shall be engraved on the indicator scale plate.
2. Transmitters shall be two-wire type with operating power derived from the signal
transmission circuit. 3. Transmitter output shall be 4 to 20 milliamperes, current regulated and shall drive
any load between 0 and 550 ohms with the power supply at 23 volts DC. 4. Transmitters shall meet specified performance requirements with load variations
within the range of 0 to 600 with the power supply at 24 volts DC. 5. Transmitter output shall be galvanically isolated. 6. Transmitter output shall increase with increasing measurement. 7. Transmitter enclosures shall be rated NEMA 250, Type 4, unless otherwise
specified. 8. Transmitters located outdoors shall be provided with surge arresters on the output
signal circuit. Surge arresters shall be in accordance with Specification 17130. 9. Where two-wire transmitter is located in an area classified as hazardous, it shall
be made safe by means of an intrinsic safety barrier as specified in paragraph 17212-2.2.
10. Where four-wire transmitters are permitted and located outdoors, they shall be
provided with surge protectors on both the signal circuit and the power circuit. Surge arresters shall be in accordance with Specification 17130.
2.2 INTRINSIC SAFETY BARRIERS A. General: Intrinsic safety barriers for two-wire transmitters shall be of the active, isolating,
loop powered type. Barrier shall be Measurement Technology LTD. type MT3042, Stahl 9005/01-252/100/00, or approved equivalent.
2.3 TRANSMITTER SPECIFICATION SHEETS
Integra Engineering 17212-3 CR37 6/29/2010
A. General requirements for instruments specified in this section are listed on Transmitter
Specification Sheets in paragraph 17212-3.6. Application requirements are specified in the Instrument Index, Table 17000-A, and/or on the Drawings.
PART 3 EXECUTION 3.1 INSPECTION A. Examine areas and conditions under which process transmitters are to be installed, and
process connections to which transmitters are to be interfaced. Notify Contractor in writing of conditions detrimental to proper completion of the work. Do not proceed with work until unsatisfactory conditions have been corrected in a manner acceptable to the Installer.
3.2 PROTECTION A. Protect installed components from damage. Replace damaged items prior to final
acceptance. 3.3 INSTALLATION OF PROCESS TRANSMITTERS A. Specific instrument installation requirements are specified on the respective Transmitter
Specification Sheets in paragraph 17212-3.6. B. Raceway Connections: Final connections between rigid raceway systems and instruments
shall be made with jacketed flexible conduit with a maximum length of 2 feet. C. Transmitters shall be shall be provided as specified on the Drawings such that ports and
adjustments are accessible for in-place testing and calibration. Where possible, equipment shall be located between 48 inches and 60 inches above the floor or a permanent work platform.
D. Transmitters shall be mounted for unobstructed access, but mounting shall not obstruct
walkways. E. Transmitters shall not be mounted where shock or vibration will impair its operation. F. Support systems shall not be attached to handrails, process piping or mechanical
equipment except for measuring elements. G. Instrument stands shall be provided for supporting transmitters as detailed on the
Drawings.
Integra Engineering 17212-4 CR37 6/29/2010
H. Transmitters supported directly by concrete or concrete block walls shall be spaced out not less than 5/8 inch by framing channel between instrument and wall.
I. Four-Wire transmitters served by 120VAC shall be provided with a toggle type
disconnect switch in accordance with paragraph 16140-2.4. Switch plate/operating mechanism shall be Crouse-Hinds DS185 or approved equivalent.
3.4 FIELD ADJUSTMENTS AND TESTING A. Calibration and Testing: Transmitters shall be calibrated and tested in accordance with
the manufacturer’s instructions and Specification Section 17030. B. Cleaning: Touch-up scratched or marred enclosure surfaces to match original finishes.
Remove all dust, debris, paint, and other foreign material from the transmitter enclosure. 3.5 TRAINING A. The Contractor shall provide the services of a factory-trained instructor for the purpose of
training the Owner's personnel in the proper operation and maintenance of process transmitters where specified on the respective Transmitter Specification Sheet. Training shall address instrument theory of operation and installation and application guidelines. Instruments shall be provided for hands-on demonstration and exercises. Training instructors shall be in the direct employment of the instrument manufacturer or manufacturer-authorized representative.
3.6 TRANSMITTER SPECIFICATION SHEETS A. The following Transmitter Specification Sheets are included in this section:
Transmitter Designation Transmitter Description
FM
Transmitter Function
Magnetic flow metering system Flow measurement
FP Propeller flow metering system Flow measurement
PGT Gage pressure transmitter Pressure measurement
Integra Engineering 17212-5 CR37 6/29/2010
TRANSMITTER SPECIFICATION SHEET – FM Transmitter Type: FM Transmitter Function: Flow measurement Transmitter Description: Magnetic flow metering system Power Supply: 120 volt, 60 hertz nominal Signal Input: Process Signal Output: Modbus signal and scaled pulse frequency User-configurable contact closure output configured
to indicate reverse flow, where specified Process Connection: Flange, ANSI B16.5 Class 150, raised face Product Requirements: General: Magnetic flow meter shall be provided as a system
consisting of a flow tube and integral or remote converter/transmitter (as indicated on the drawings). Converter/ transmitter shall be suitable for full-scale flow rates from 1 to 33 feet per second. System error shall not exceed the greater of 0.5 percent of rate ± 0.01 percent of maximum full scale. Flow metering system repeatability shall be ± 0.1 percent of rate ± 0.005 percent of maximum full scale. Flow metering system shall be bi-directional and shall provide a contact closure signal to indicate flow in the reverse direction.
Flow tubes shall be provided with 0.125 inch thick
grounding rings. Grounding rings shall be fabricated from ASTM A312, Type 316 stainless steel. Grounding ring inside diameter shall be 1/16 inch smaller than flow tube inside diameter. Flow tube flanges shall be drilled and tapped for termination of ground conductors.
Standard meter shall be FM approved Class 1, Div 2
Groups A-D.
Integra Engineering 17212-6 CR37 6/29/2010
TRANSMITTER SPECIFICATION SHEET – FM (continued) Where pipe run size is different from specified flow
tube size, uniformly diverging swages with a total angle between walls not exceeding 15 degrees shall be provided.
Flow Tube (< 14 inch): Flow shall be 316 stainless steel full-body flanged
construction with carbon steel flanges and a powder-coated die-cast aluminum sensor housing. Flow tube shall have an Al/Zn protective coating. Flow tube liner shall be hard rubber or polyurethane.
Flow tube (≥ 14 inch): Flow tubes shall be stainless steel full-body flanged
construction with steel flanges and a painted steel sensor housing. Flow tube shall have painted protective finish. Unless otherwise specified, liner shall be hard rubber or polyurethane.
Electrodes: Flow tube measuring, ground, and empty pipe
detection electrodes shall be of 316L stainless steel construction unless specified otherwise.
Transmitter: The transmitter shall contain all electronics
associated with the magnetic flow meter system. Enclosure shall be NEMA 4X cast aluminum compartment for power, field connections and calibration adjustments separate from digital circuitry. Transmitter shall be provided with 3 optical keys to permit non-intrusive setup and calibration. The transmitter shall contain self diagnostics and shall be interchangeable with other units of the same type without special re-calibration. Transmitter shall include an integral 4 line, 16-digit illuminated LCD display. Features shall include current signal output simulation, empty pipe detection, and galvanically isolated active/passive pulse outputs. A relay contact output shall be provided to indicate flow in the reverse direction when specified.
Transmitter dampening shall be programmable from
0.01 to 100 seconds. All setup parameters shall be stored in non-volatile EEPROM memory.
Integra Engineering 17212-7 CR37 6/29/2010
TRANSMITTER SPECIFICATION SHEET – FM (continued) Submersible Service: Where scheduled in the Instrument Index as NEMA
6P Construction, the flow metering system shall be suitable for submersible applications (permanent immersion in water to a depth of 3 meters) including the following features:
a. Remote-mounted transmitter suitable for
wall mounting. b. Integral potted cable furnished with the flow
tube. Cable length shall be as required to be installed in the specified raceway system from the flow tube to the transmitter location.
Acceptable Manufacturers: Endress+Hauser Promag 53W, or approved
equivalent. Execution: Installation: Install in accordance with manufacturer's instruc-
tions, API RP550, and the specified functional requirements.
Flange bolts shall be tightened to tube
manufacturer's specified torque. Application: Application and setup shall be in accordance with
manufacturer’s recommendations and as specified in Instrument Index.
Test and Calibration: In accordance with specification 17030. Meter shall be provided with NBS certified or
equivalent flow certification to a minimum of 3 calibration points.
The unit shall include a Field Check certification from the manufacturer’s calibration facility to be used for long term verification of meter stability in application. A duplicate certification test shall be
Integra Engineering 17212-8 CR37 6/29/2010
TRANSMITTER SPECIFICATION SHEET – FM (continued) performed one year from the date of instrument commissioning to ensure that the meter sensor and electronics are within the original manufacturer’s tolerances for electrode integrity, coil rise time, zero point stability, and output linearity for analog current, frequency, and pulse values.
Training: 2-hour training session covering the setup,
calibration, maintenance, and troubleshooting of the flow measurement system.
Integra Engineering 17212-9 CR37 6/29/2010
TRANSMITTER SPECIFICATION SHEET – FP Transmitter Type: FP Transmitter Function: Flow measurement Transmitter Description: Propeller flow metering system Power Supply: As specified in paragraph 17212-2.1 Signal Input: Process Signal Output: None Process Connection: Steel flanged end tube, pressure rating 150 PSI, 4-
inch diameter. Product Requirements: General: Propeller flow meter shall be provided as a system
consisting of a flow tube, propeller assembly, and indicator-totalizer. Indicator-totalizer shall be furnished with GPM indication.
Acceptable Manufacturers: Water Specialties, Model ML04, or approved
equivalent. Execution: Installation: Install in accordance with manufacturer's instruc-
tions, API RP550, and the specified functional requirements.
Flange bolts shall be tightened to tube
manufacturer's specified torque. Application: Application and setup shall be in accordance with
manufacturer’s recommendations and as specified in Instrument Index.
Test and Calibration: In accordance with specification 17030.
Integra Engineering 17212-10 CR37 6/29/2010
Training: 1 hour training session covering the setup, calibration, maintenance, and troubleshooting of the flow measurement system.
Integra Engineering 17212-11 CR37 6/29/2010
TRANSMITTER SPECIFICATION SHEET – PGT Transmitter Type: PGT Transmitter Function: Pressure measurement Transmitter Description: Gage pressure transmitter Power Supply: As specified in paragraph 17212-2.1 Signal Input: Process Signal Output: Analog transmission signal as specified in
paragraph 17212-2.1 with HART communication protocol.
Process Connection: Pressure Tap: 1/2-inch male NPT, 316Ti stainless
steel, with inline two valve stainless steel manifold. Flange: 150 lb ANSI flange, 316 stainless steel size
as scheduled. Flush Mount: 316L stainless steel weld spud fitting
with Teflon seal mounted to a flanged, carbon steel pipe spool. Pipe diameter shall be as indicated in the Instrument Index. Flanges shall be ANSI B16.5 Class 150. Pipe spool lay length shall be 12 inches.
Product Requirements: Pressure transmitter shall have a stainless steel
pressure sensing diaphragm. Span shall be adjustable over a 200:1 or greater range. Accuracy shall be ± 0.025 up to 4000 psi range limit.
Adjustable dampening shall be provided. External
operating keys shall be provided for instrument configuration and calibration.
Transmitter housing shall be aluminum, rated
NEMA 4X. Transmitter shall be provided with an integral LCD display.
Integra Engineering 17212-12 CR37 6/29/2010
TRANSMITTER SPECIFICATION SHEET – PGT (continued) Acceptable Manufacturers: Rosemount 3051S, with 304 manifold and bracket
for 2-inch pipe mounting, or approved equivalent. Execution: Installation: General: Install in accordance with manufacturer's
instructions and as specified herein. Pressure Tap Process Connection: A root valve shall be provided at the process
pressure tap on the associated process piping. All unused openings on the manifold valve shall be provided with plugs of the same material as the root valve. Safety instruments shall not be connected to the same process tap as instruments used for control, indication, or recording.
Stainless steel instrument tubing shall be provided
from the process pressure tap to the pressure instrument. Unless otherwise specified, pressure instruments shall be located as close as practical to the process tap but shall be positioned to permit observation and maintenance from the process floor.
A two-valve manifold shall be provided at the
instrument. The valve manifold shall be mounted on an instrument stand adjacent to the pressure tap. The pressure transmitter shall be located 48 inches above the finished floor or work platform, where possible.
Integra Engineering 17212-13 CR37 6/29/2010
TRANSMITTER SPECIFICATION SHEET – PGT (continued) In liquid applications, the instrument tubing shall
slope down from the process tap to the pressure transmitter and the pressure tap shall be made in the side of the process pipe. In gas applications the instrument tubing shall slope up from the process tap to the pressure transmitter and the pressure tap shall be made in the top of the process pipe.
Flange Process Connection: Pressure transmitter shall be mounted to the flanged
process opening where indicated on the Drawings. Flush Mount Process Connection: Flanged pipe spool shall be installed in the process
piping in accordance with applicable process piping specifications and details.
Application: Application and setup shall be in accordance with
manufacturer’s recommendations and as specified in the Instrument Index.
Test and Calibration: In accordance with specification 17030. Training: 1 hour training session covering the setup,
calibration, maintenance, and troubleshooting of the pressure measurement system.
END OF SECTION
Integra Engineering 17216-1 CR37 6/29/2010
SECTION 17216
PROCESS SWITCHES PART 1 GENERAL 1.1 RELATED DOCUMENTS A. Drawings and General Provisions of Contract, including General and Supplementary
Conditions and Division 1 Specification Sections, apply to Work of this Section. Should there be any conflict between provisions or requirements elsewhere indicated and the provisions of this division, request written clarification by addendum prior to submission of bid or abide by the interpretation of the Engineer.
B. Section 17211, Process Taps and Primary Elements, applies to Work of this Section.
1.2 SUMMARY A. This section specifies requirements for process activated switches. B. Application requirements for process switches are specified in the Instrument Index,
Table 17000-A, appended to the end of Section 17000. 1.3 SUBMITTALS A. Submittals shall be provided in accordance with the requirements of Specification 17000. 1.4 QUALITY ASSURANCE A. Manufacturer’s Qualifications: Firms regularly engaged in the manufacture of process
switches of types, sizes, and ratings required, whose products have in satisfactory use in similar service for not less than 5 years.
B. Installer’s Qualifications: Firms with at least 3 years of successful installation experience
on projects utilizing process switches similar to those required for this project.
Integra Engineering 17216-2 CR37 6/29/2010
PART 2 PRODUCTS 2.1 GENERAL A. Unless otherwise specified, process switches shall comply with the following
requirements: 1. Contact outputs used for alarm actuation shall be ordinarily closed and shall open
to initiate the alarm. 2. Contact outputs used to control equipment shall be ordinarily open and shall close
to start the equipment. 3. Contacts monitored by solid state equipment such as programmable controllers or
annunciators shall be hermetically sealed and designed for switching currents from 20 to 100 mA at 24 volts DC.
4. Contacts monitored by electromagnetic devices such as mechanical relays shall be
rated NEMA ICS 2, designation B300. 5. Double barriers shall be provided between switch elements and process fluids
such that failure of one barrier will not permit process fluids into electrical enclosures.
6. Switch electrical enclosures shall be rated NEMA 250, type 4 minimum. 7. Contacts in Class 1, Division 1 areas and monitored by solid-state circuits shall be
made safe by suitable intrinsic safety barriers. Intrinsic safety barrier shall be dual type to prevent grounding alarm circuit at the barrier. Barriers shall be MTL 787, or approved equivalent.
2.2 PROCESS SWITCH SPECIFICATION SHEETS A. General requirements for instruments specified in this section are listed on Process
Switch Specification Sheets in paragraph 17216-3.6. Application requirements are specified in the Instrument Index, Table 17000-A, and/or on the Drawings.
PART 3 EXECUTION 3.1 INSPECTION A. General: Examine areas and conditions under which process switches are to be installed,
and process connections to which switches will be interfaced. Notify Contractor in writing of conditions detrimental to proper completion of the work. Do not proceed with
Integra Engineering 17216-3 CR37 6/29/2010
work until unsatisfactory conditions have been corrected in a manner acceptable to the Installer.
3.2 PROTECTION A. General: Protect installed components from damage. Replace damaged items prior to
final acceptance. 3.3 INSTALLATION OF PROCESS SWITCHES A. Specific switch installation requirements are specified on the respective Process Switch
Specification Sheets in paragraph 17216-3.6. B. Raceway Connections: Final connections between rigid raceway systems and instruments
shall be made with jacketed flexible conduit with a maximum length of 2 feet. C. Process switches shall be shall be provided as specified on the Drawings such that ports
and adjustments are accessible for in-place testing and calibration. Where possible, equipment shall be located between 48 inches and 60 inches above the floor or a permanent work platform.
D. Process switches shall be mounted for unobstructed access, but mounting shall not
obstruct walkways. E. Process switches shall not be mounted where shock or vibration will impair its operation. F. Support systems shall not be attached to handrails, process piping or mechanical
equipment except for measuring elements. G. Process switches supported directly by concrete or concrete block walls shall be spaced
out not less than 5/8 inch by framing channel between instrument and wall. H. Process switches served by 120VAC shall be provided with a toggle type disconnect
switch in accordance with paragraph 16140-2.4. Switch plate/operating mechanism shall be Crouse-Hinds DS185 or approved equivalent.
3.4 FIELD ADJUSTMENTS AND TESTING A. Calibration and Testing: Process switches shall be calibrated and tested in accordance
with the manufacturer’s instructions and Specification Section 17030. B. Cleaning: Touch-up scratched or marred enclosure surfaces to match original finishes.
Remove all dust, debris, paint, and other foreign material from the switch enclosure.
Integra Engineering 17216-4 CR37 6/29/2010
3.5 TRAINING A. General: The Contractor shall provide services of a factory-trained instructor for the
purpose of training the Owner's personnel in the proper operation and maintenance of process switches where specified on the respective Process Switch Specification Sheet.
3.6 PROCESS SWITCH SPECIFICATION SHEETS A. General: The following Process Switch Specification Sheets are included in this section:
Process Switch Type Process Switch Description
LVS
Process Switch Function
Vibratory Level Switch Level Detection
PS Pressure Switch Pressure Detection
TS Temperature Switch Temperature Detection
Integra Engineering 17216-5 CR37 6/29/2010
PROCESS SWITCH SPECIFICATION SHEET– LVS Switch Type: LVS Switch Function: Level Detection Switch Description: Frequency shift tuning fork vibratory level switch Power Supply: 120 volts AC, 60 hertz, nominal Signal Input: N/A Signal Output: Contacts as specified in paragraph 17216-2.1 Process Connection: 1-inch male NPT Product Requirements: Switch assembly shall consist of a tuning fork type
probe and electronics enclosure. Switch shall continuously vibrate the tuning fork probe and monitor the frequency of vibration. The switch electronics shall detect a frequency shift as the probe is immersed in the measured media and generate the specified output signal. Probe shall be constructed of 316 stainless steel. Probe length shall be as scheduled in the Instrument Index, Electronics housing shall be of aluminum construction with an epoxy resin coating.
Level switch shall employ continuous self-testing
and shall initiate alarm annunciation upon detection of tuning fork corrosion/damage, piezo drive short or open, and power failure.
Frequency shift tuning fork vibratory level switch
shall be suitable for installation in Class 1 and Class 2 hazardous locations, where indicated on the drawings.
Acceptable Manufacturers: Endress+Hauser Liquiphant M FTL 50/51, or
approved equivalent. Execution: Installation: Install in accordance with manufacturer's
instructions and as indicated on the Drawings.
Integra Engineering 17216-6 CR37 6/29/2010
PROCESS SWITCH SPECIFICATION SHEET– LVS (continued) Application: Application and setup shall be in accordance with
manufacturer’s recommendations and as specified in the Instrument Index.
Test and Calibration: In accordance with specification 17030. Training None required.
Integra Engineering 17216-7 CR37 6/29/2010
PROCESS SWITCH SPECIFICATION SHEET– PS Switch Type: PS Switch Function: Pressure detection Switch Description: Gauge pressure switch Power Supply: N/A Signal Input: Process Signal Output: Two SPDT contacts as specified in paragraph
17216-2.1 Process Connection: 1/2-inch male NPT Product Requirements: Pressure switch shall consist of a pressure
transducer and a precision switch. Pressure switch wetted materials shall be as recommended by the switch manufacturer for each application. Switch assembly housing shall be weatherproof. Contractor shall select pressure transducer so that set points fall between 30 and 70 percent of maximum range. Repeatability and sensitivity shall be 2.0 percent of operating range or better. Unless otherwise specified, switches shall be adjustable deadband type.
Acceptable Manufacturers: Mercoid, D Series, snap action switch, or approved
equivalent. Execution: Installation: Install in accordance with manufacturer's
instructions and the recommendations of API RP550 to the specified requirements.
Integra Engineering 17216-8 CR37 6/29/2010
PROCESS SWITCH SPECIFICATION SHEET– PS (continued) Root valves shall be provided at all process pressure
taps. Gage valves shall be provided at the instrument where the instrument is not within sight of the root valve or where two or more instruments are connected to a single tap. Safety instruments shall not be connected to the same process tap as instruments used for control, indication, or recording. Unless otherwise specified, pressure instruments shall be located as close as practical to the process tap but shall be positioned to permit observation and maintenance.
Unless otherwise specified, pressure switches shall
be located as close as practical to the process tap but shall be positioned to permit access for observation and maintenance. The instrument tubing shall slope down from the process tap to the pressure switch.
Application: Application and setpoints shall be as specified in the
Instrument Index. Test and Calibration: In accordance with specification 17030. Training None required.
Integra Engineering 17216-9 CR37 6/29/2010
PROCESS SWITCH SPECIFICATION SHEET– TS Switch Type: TS Switch Function: Temperature Detection Switch Description: Room Thermostat with snap-action switch Power Supply: N/A Signal Input: N/A Signal Output: Contacts as specified in paragraph 17216-2.1 Process Connection: N/A Product Requirements: Thermostat shall be suitable for wall mounting and
shall have a NEMA 4X enclosure. Acceptable Manufacturers: Chromalox, Catalog Number WCRT-100, or
approved equivalent. Execution: Installation: Install in accordance with manufacturer's
instructions and as indicated on the Drawings. Application: Application and setup shall be in accordance with
manufacturer’s recommendations and as specified in the Instrument Index.
Test and Calibration: In accordance with specification 17030. Training None required.
END OF SECTION
Integra Engineering 17310-1 CR37 6/29/2010
SECTION 17310
REMOTE TERMINAL UNITS (RTU) PART 1 GENERAL 1.1 RELATED DOCUMENTS A. Drawings and General Provisions of Contract, including General and Supplementary
Conditions and Division 1 Specification Sections, apply to Work of this Section. Should there be any conflict between provisions or requirements elsewhere indicated and the provisions of this division, request written clarification by addendum prior to submission of bid or abide by the interpretation of the ENGINEER.
B. PLC Input/Output Summary, Table 17310-A, appended to the end of this specification
section. C. Control Strategies, Attachment 17310-B, appended to the end of this specification
section. 1.2 SUMMARY A. This section specifies RTUs for the following applications: 1. Canyons South #1, Telemetry Control Panel. B. PLC and operator interface programming shall be performed as part of the work of this
contract. C. Radio data transmission, coordination with repeater station, and data download at the Ray
Waterman control facility shall be performed as part of the work of this contract. HMI programming at the Ray Waterman control facility shall be performed by the Owner.
1.3 SUBMITTALS A. Submittals shall be provided in accordance with the requirements of Specification 17000. 1.4 QUALITY ASSURANCE, STANDARDS, AND DRAWINGS A. Manufacturer’s Qualifications: Firms regularly engaged in the manufacture of RTU
equipment of types, sizes, and ratings required, whose products have in satisfactory use in similar service for not less than 5 years.
Integra Engineering 17310-2 CR37 6/29/2010
B. Installer’s Qualifications: Firms with at least 3 years of successful installation experience on projects utilizing RTUs and associated equipment similar to those required for this project.
C. Codes and Standards: 1. Electrical Code Compliance: Comply with applicable local code requirements of
the authority having jurisdiction and the National Electrical Code, NFPA 70. 2. ISA Compliance: Provide components that comply with the following standards: ISA RP60.11 Guide to the Available Methods for Control Center
Crating, Shipping and Handling 3. NEMA Compliance: Provide components that comply with the following
standards: NEMA 250 Enclosures for Electrical Equipment 4. UL Compliance: Comply with requirements of UL and UL standards pertaining
to control panels and consoles. Provide products that have been UL listed and labeled.
UL 508 Standard for Safety Industrial Control Equipment D. Identification of Listed Products: RTU system components shall be listed for the purpose
for which they are to be used, by an independent testing laboratory. Three such organizations are Underwriters Laboratories (UL), Canadian Standards Association (CSA), and Electrical Testing Laboratories (ETL). Independent testing laboratory shall be acceptable to the inspection authority having jurisdiction.
1.5 DELIVERY, STORAGE, AND HANDLING A. General: RTU panels shall be shipped, protected, and stored in accordance with the
requirements of this specification and the applicable requirements of ISA RP60.11. B. Shipping: RTU panels shall be shipped in Type 2S general purpose, humidity protected
crates as defined by ISA RP60.11. Panels shall be prepared for shipment in accordance with ISA RP60.11, paragraphs 5.2 and 5.3. All sensitive electronic components, including programmable logic controller components, with the exception of input/output chassis, shall be removed from panels and shipped separately in accordance with manufacturer’s instructions.
Integra Engineering 17310-3 CR37 6/29/2010
PART 2 PRODUCTS 2.1 REMOTE TERMINAL UNIT (RTU) PANELS A. General: RTU panels shall be complete pre-wired integrated assemblies with the required
operator interface functions as detailed on the Drawings and ancillary equipment as specified herein. Panel size and equipment layout requirements shall be as specified herein and as indicated on the Drawings.
B. Power Distribution: 1. AC Power: Each remote terminal unit, or control panel shall be provided with
DIN rail mounted circuit breakers on each incoming branch circuit serving the cabinet. DIN rail mounted circuit breakers shall also be provided for each 120-volt AC power branch circuit derived from the cabinet power distribution system and serving equipment either within the cabinet or external to the cabinet. Circuit breakers shall be sized in accordance with the National Electrical Code and shall be 3 ampere minimum for instrument loads and 15 ampere minimum for receptacle, ventilation and lighting loads. Individual branch breakers shall be provided for the following types of equipment:
a. DC power supplies b. Internal and external receptacle circuits c. Panel lighting circuits d. Internal and external process variable transmitters
2. DC Power: Each remote terminal unit, or control panel shall be provided with a DC power supply power supply system as detailed on the Drawings. DC power supply circuits shall be individually fused. Individually fused circuits shall be provided for the following types of equipment:
a. Programmable logic controllers b. Radio telemetry systems c. Wetting voltage for individual input/output modules
d. Process variable transmitters 3. Power Receptacles: 120 volt AC duplex receptacles for installation in control
panels shall be suitable for DIN rail mounting and provided with an integral terminal strip. Receptacles shall have integral surge protection. Receptacles shall be Phoenix Contact, EM-DUO or approved equivalent. Receptacles for utility power shall be ivory color; receptacles for UPS service shall be orange color.
Integra Engineering 17310-4 CR37 6/29/2010
C. Enclosures: 1. Enclosure shall be 90”H x 36”W x 20”D, NEMA 12, free-standing, 12 gauge
steel, single door, with white polyester paint inside and ANSI 61 gray polyester powder paint outside over phosphatized surfaces, as manufactured by Hoffman, or approved equivalent. Enclosure shall have the following features:
a. Full height equipment mounting back panel. b. 3-point latch with key-locking handle..
c. Data pocket on inside of door. d. Fluorescent light with door activated switch D. Nameplates: 1. Panel Exterior: Machine engraved laminated black phenolic nameplates with
white lettering shall be provided. Nameplate engraving shall include the site name and RTU designation, in 1/8-inch minimum size lettering. Nameplates shall be attached to the panel with adhesive.
2. Panel Interior: Machine engraved laminated black phenolic nameplates with
white lettering shall be applied on the interior of panels to identify tag number of equipment mounted inside panels. Nameplates shall be attached to panel surfaces, not to instruments.
E. Interconnection Wiring and Associated Equipment: 1. Interconnection Wiring: a. Power and control wiring shall be single conductor stranded copper NFPA
No. 70 Type MTW No. 16 AWG minimum. Wiring for analog signals shall be No. 22 AWG stranded copper NFPA No. 70 Type MTW.
b. Wiring shall be supported independently of terminations by lacing to panel
support structure or by slotted flame retardant plastic wiring channels. Wiring channels shall comply with UL 94, Type V and shall be 4” deep (minimum). Wiring channel fill shall not exceed 40 percent.
c. Wiring shall be tagged at terminations. Wire identification system shall be
as specified in paragraph 16120-2.6. Wire numbers shall consist of three parts. The prefix of the wire number shall be the instrument loop number. If an instrument loop number is not available, the lowest mechanical equipment number of all final devices in the circuit shall be used. Following the prefix shall be a code letter. The third part of the wire number shall be the terminal number within the control panel. Code letters and wire colors are given in the following tables:
Integra Engineering 17310-5 CR37 6/29/2010
120 Volt AC Wire Color Codes
Code Description L
Color Power Black
C Control Red N Neutral White G Ground Green
24 Volt DC Wire Color Codes Code Description SP+
Color Power Supply - Positive Blue
SP- Power Supply – Common White/Blue SPU+ UPS Power Supply – Positive Orange SPU- UPS Power Supply – Common White/Orange
C Control Violet S Signal (positive) Black
SG Signal ground White PG Equipment ground Green
d. All conductors carrying a foreign voltage within a cabinet shall be yellow e. Wiring shall comply with the requirements of NFPA No. 70 as a
minimum. Power and control wiring shall be carried in covered channels separate from low voltage signal circuits. An interior steel barrier shall be provided between AC control devices and the electronic equipment.
f. All field wiring terminating within a panel shall be terminated on terminal
blocks. Conductor termination preparation shall be as required to interface with the specified terminal block. Conductors terminating on compression-type terminals shall have the insulation removed to the wire strip length recommended by the terminal block manufacturer. Conductors terminating on strap/screw type terminal blocks shall be terminated with locking spade-type insulated, crimp-on lugs.
g. Field connections shall be to separate, designated terminal blocks.
Terminal blocks for field terminations shall be in a separate part of the panel close to where the field cables enter the panel.
h. Circuits shall be fused. Fuses shall be 1/4 x 1-1/4 inch. Fuses on 120 volt
AC circuits shall be ceramic tube type with 25,000 amperes interrupting capacity at 125 volts and neon blown fuse indicator lamps. Fuses for 24V DC circuits shall be fast acting glass tube type rated 1/8 or 1/10 amp for 4-20 mA loops. Fuse holders for 120V AC shall be drawout type and molded from melamine plastic.
Integra Engineering 17310-6 CR37 6/29/2010
2. Terminal Blocks: Unless otherwise shown or specified, terminal blocks shall be
screw type rated 600 volts AC and suitable for DIN rail mounting. Terminal block type and application shall be as specified in the following table. Terminal blocks shall be Entrelec, or approved equivalent. Terminal block assemblies shall be complete including end caps, markers, insertion bridges, mounting hardware, etc.
Description
Fused disconnect type terminal block Type
115-657.25 Grounding terminal block 0105-001.27 Terminal block 115-116.07 End stop 206-351.16
a. Mounting Rail: Terminal blocks shall be assembled on aluminum “high
rise” mounting rail. Mounting rail shall be 2.25 inches tall and of the lengths required. Terminal blocks shall be organized by function and provided with group markers to identify function or input/output module reference.
b. Marking: Each terminal block and logical/functional groups of terminal
blocks shall be provided with machine printed labels. c. Bridging: Insulated insertion bridges shall be utilized where indicated on
the Drawings and to bridge common terminal blocks together without the use of jumper wiring. Insertion bridges shall be manufactured by the manufacturer of the terminal block.
d. Multiple Conductor Termination: Multiple conductors shall not be
terminated in a single clamping space on a terminal block. Utilize insertion bridges or factory-fabricated jumpers to extend circuits for multiple conductor terminations.
3. Panel Grounding: Each panel shall be provided with two copper ground bars.
One bar shall be bonded to the panel frame or sheet metal and to the station ground system. The second (signal) ground bar shall be mounted on insulated stand-offs and shall be bonded to the frame ground bar at one point only. Signal circuits, signal cable shields, and low-voltage DC power supply commons shall be bonded to the signal ground bar. Ground bars shall be tin-plated copper with pre-tapped termination holes and insulated mounting brackets suitable for back panel mounting. Ground bars shall have fifty (50) percent spare termination holes and shall be provided with screws for each hole.
Integra Engineering 17310-7 CR37 6/29/2010
2.2 POWER SUPPLY AND CONDITIONING EQUIPMENT A. The following power supply and conditioning equipment shall be provided and
configured as detailed on the Drawings:
1. Alternating Current Power Filter: AC power filters shall provide transient voltage surge suppression and noise attenuation and shall be designed for protection of microprocessor-based industrial control equipment and shall be in compliance with ANSI/IEEE C62.41-1991. AC power filter shall be Transtector, ACP Hardwire Model 100BWN3, or approved equivalent.
2. 24 Volt DC Power Supply for Bulk Power: Power supply shall be suitable for
operation on input voltage of 110-240V AC and shall provide a minimum of 5A at 24V DC output. DC power supply for bulk power shall be suitable for DIN-rail mounting and shall be ABB, Part Number 1SVR 427 014 R0000, or approved equivalent.
3. Alternating current uninterruptible power supply (UPS): The UPS system shall
consist of a tower style UPS with alarm relay card, and distribution module. The uninterruptible power supply shall power all equipment in the panel operating at 120VAC, all field mounted instruments served from the panel, the 24 Volt DC bulk power supply, and the 13.8VDC power supply serving the radio. The bypass/surge protector shall enable the UPS to be upgraded or replaced while continuously providing power to equipment. The UPS system shall be sized for 150 percent of initial system load, with a minimum rating of 1250VA/875Watt. The uninterruptible power supply shall be Powerware, Model PW9125 1250 with relay card 1018460, or approved equivalent. PowerPass distribution module shall be Powerware 9125 PowerPass, Part Number 05146519-001, or approved equivalent.
4. 13.8 Volt DC power supply: A 13.8 Volt DC, 100W, single output switching
power supply shall be provided to serve the telemetry radio system. The 13.8 Volt DC power supply shall be Samlex, Model S-100F-12, or approved equivalent.
5. Surge Protection: a. Transmitter Signal Circuits (at panel field terminals): Analog signal
circuits from instruments located outdoors shall be provided with DIN-rail mounted surge protection where the signal circuit enters the control panel or cabinet. Surge protection shall be Transtector, Model DRDC24, or approved equivalent.
Integra Engineering 17310-8 CR37 6/29/2010
2.3 CONTROL RELAYS AND TIMERS A. Control relays shall be provided where required for I/O interface and control functions.
Control relays have indicator lights, and Din-rail style sockets. Control relays for 120V AC, 60Hz, and 24V DC service shall be Idec, RH Series, or approved equivalent.
B. Timers shall be provided where required for control functions. Timers shall have dial
type adjustment, LED ON and timing OUT indicators, 2 Form C 10amp output contacts, pin style terminals, and Din-rail style sockets. Timers shall be Idec, RTE Series, or approved equivalent.
2.4 TELEMETRY RADIO SYSTEMS A. 800-960 MHz transceiver: Transceiver shall communicate with the PLC via 4 wire
analog, 9600 bps (rf) connected to an RS-232 port. Transceiver shall be MDS 9710, Model 9710A, no substitutions.
B. Lightning Protection: RTU shall be equipped with bulkhead type coaxial lightning surge
protectors for each antenna system. Lightning protectors shall be as manufactured by Polyphaser, IS-B50LN-C2.
C. Antenna: Antenna shall be 900 MHz, Yagi, seamless aluminum construction, with
stainless steel hardware, and mounting bracket. Yagi antenna shall be Maxrad, Model MYA 9309, or approved equivalent.
D. Antenna Cable: Cable between antenna and RTU cabinet shall be Andrew, Heliax LDF4-
50A, or approved equivalent. E. Configuration: 1. 800-960 MHz transceiver: One (1) 800-960 MHz transceiver system with
antenna, lightning protector, superflexible antenna adapter cable, and data cable. Radio shall be backpanel mounted in RTU Panel enclosure and shall be interfaced with the PLC system through the RS-232 serial communication module.
2.5 RTU/PROGRAMMABLE LOGIC CONTROLLER SYSTEMS A. General: RTU/Programmable logic controllers systems shall be Bristol Babcock,
ControlWave Micro. PLC system components shall be as manufactured by Bristol Babcock unless indicated otherwise. The following system components shall be provided:
1. Processor, with 2-RS-232, 1-RS-485, and 1 Ethernet communication port:
Catalog Number 396563-06-6.
2. Power Supply: Catalog Number 396657-01-10.
Integra Engineering 17310-9 CR37 6/29/2010
3. Rack, 8 Slot: Catalog Number 396560-01-6.
4. Expansion Base, 2 slot: Catalog Number 396559-03-4.
5. Analog Input Module, 8 point: Catalog Number 396604-01-3.
6. Analog Output Module, 4 point: Catalog Number 396603-01-7.
7. Digital Input Module, 16 point: Catalog Number 396571-02-6.
8. Digital Output Module, 16 point: Catalog Number 396572-02-2. B. Configuration: The PLC system shall be mounted in the RTU Panel. One (1) of each
specified component shall be provided with the exception of the input/output modules. Input/output modules shall be provided in the quantities required to address the input/output requirements defined by Table 17310-A, PLC Input/Output Summary.
2.7 DIGITAL INDICATOR A. Digital indicator shall 4 digit red LED display, with front accessible setup and navigation
buttons, suitable for through panel mounting. Digital indicator shall be Newport, Model IDP-O.
2.8 ELAPSED TIME METER A. Elapsed time meter shall be self powered, and shall have 7-segment LCD backlit display
with selectable time range, suitable for through panel mounting. Elapsed time meter shall be Omron, H7ET-N1-B, or approved equivalent.
2.9 CYCLE COUNTER A. Cycle counter shall be self powered, and shall have 7-segment LCD backlit display with
selectable input speed, suitable for through panel mounting. Cycle counter shall be Omron, H7EC-N1-B, or approved equivalent.
2.10 CONTROL DEVICES A. General: Control devices shall be 30.5 mm, heavy-duty, corrosion resistant with NEMA
rating to match enclosure type. Device escutcheon legend shall be as specified on the Drawings. Control devices shall be Eaton, 10250T Series, or approved equivalent.
B. Pushbuttons: Pushbuttons shall be flush head type; red for stop functions and black for
all other functions. The escutcheon legend shall be as specified on the Drawings. Unless otherwise specified, pushbuttons shall be momentary contact type.
C. Selector Switches: Selector switches shall be provided with standard knob operators and
unless otherwise specified selector switches shall be maintained position. Switches shall
Integra Engineering 17310-10 CR37 6/29/2010
be provided with contact blocks and number of positions as required to perform the specified operations. The escutcheon legend shall be as specified on the Drawings.
E. Indicating Lights: Indicating lights shall be 120 volt AC, incandescent, transformer,
push-to-test type. The escutcheon legend shall be as specified on the Drawings. 1. Colors: Indicating light lens colors shall be as scheduled below:
Color Function Green
Example Run, open valve Equipment operating, motor running
Red Stopped, closed valve, fail Equipment "OFF" and in ready condition, or failure when indicated on escutcheon
F. Contact Blocks: Contact blocks shall be NEMA ICS-2 designation A600 except when
switching circuits monitored by programmable controllers or other solid state circuits, contact blocks shall be hermetically sealed, logic-reed type as manufactured by Eaton, or approved equivalent.
2.11 INTRUSION DETECTION SYSTEM A. Control panel: Control panel shall monitor 6 hardwired zones and communicate with
entry keypads and provide intrusion alarm output for remote monitoring. Intrusion control panel shall be Honeywell, Model VISTA-10P, no substitutions.
B. Entry keypad: Entry keypad shall have a 32-character display, easily accessible function
keys, and be programmable for fire, burglary, personal emergencies and other operations. Entry keypad shall be Honeywell, Model 6160, no substitutions.
C. Intrusion switch: Intrusion switch shall be magnetic surface mount type, with 3 foot
length of armored cable. Intrusion switch shall be Ademco, Model 960, no substitutions. D. Configuration: Control panel shall be mounted in the Telemetry Control Panel (TCP).
Entry keypads and intrusion switches shall be field mounted as indicated on the drawings. PART 3 EXECUTION 3.1 INSPECTION A. General: Examine areas and conditions under which radio telemetry equipment, systems,
and accessories are to be installed. Notify the ENGINEER in writing of conditions detrimental to proper completion of the work. Do not proceed with work until unsatisfactory conditions have been corrected in a manner acceptable to the Installer.
Integra Engineering 17310-11 CR37 6/29/2010
3.2 PANEL ASSEMBLY AND CONFIGURATION A. General: RTU panel assemblies shall be configured as specified below and as indicated
on the Drawings. B. Equipment Layout: Equipment layout within panel assemblies shall be in accordance
with the following: 1. Equipment of similar function shall be grouped together in common areas of the
panel. Equipment arrangement shall permit ready access to terminals, ports, adjustments, and indicators to facilitate programming, setup, inspection, troubleshooting, and operation of the equipment without disassembly.
2. Control panels interior layout shall include areas designated for conduit entry.
Conduit entry locations shall be in the bottom of the enclosure. 3. Field terminals shall be arranged in an area of the control panel separate from the
fixed equipment. Provide 25 percent spare DIN rail mounting space for future input/output field terminal blocks.
4. All terminal blocks shall be mounted on high rise DIN rail. All equipment with
conductor terminals that would be less than 2.25 inches from the enclosure back mounting panel when mounted directly to the back panel, shall be mounted high rise DIN rail.
C. Spare I/O Channels: All spare or otherwise unused programmable logic controller
input/output channels shall be provided with interconnecting cabling to field terminal blocks.
3.3 INSTALLATION OF PANELS A. RTU panels shall be installed at the locations indicated on the Drawings. B. Coordinate panel installation work with electrical raceway and wire/cable work, as
necessary for proper interface. C. Fasten enclosures firmly to walls and structural surfaces, ensuring that they are
permanently and mechanically anchored. D Tighten connectors and terminals, including screws and bolts, in accordance with
equipment manufacturer’s published torque tightening values for equipment connectors. Where manufacturer’s torquing requirements are not indicated, tighten connectors and terminals to comply with tightening torques specified in UL Standard 486A. Use properly scaled torque indicating hand tool.
Integra Engineering 17310-12 CR37 6/29/2010
3.4 GROUNDING A. General: Provide equipment grounding connections to panels, enclosures, and consoles as
indicated. Tighten connections to comply with tightening torques specified in UL Standard 486A to assure permanent and effective grounding.
3.5 ADJUSTING AND CLEANING A. Adjust operating mechanisms and doors for free mechanical movement. B. Touch-up scratched or marred surfaces to match original finish. 3.6 TESTING A. I/O Signal Circuits: All I/O signal circuits shall be functionally tested to confirm the
proper connection of the signal circuit and the functionality of the associated I/O module. B. Power Distribution and Conditioning Systems: Power distribution and conditioning
systems shall be functionally tested to confirm proper connection and operation of the equipment.
3.7 PLC INPUT/OUTPUT SUMMARY A. The PLC Input/Output Summary, Table 17310-A, is appended to the end of this
specification. B. Table Entries: The entries in the PLC Input/Output Summary, Table 17310-A, are
defined as follows: 1. Signal: Tag number for the input/output signal.
2. Description: Description of the input/output signal.
3. Source - Device: Identifies the device from which the signal is derived. This entry is blank if the signal source is a PLC output module.
4. Source - Location: Identifies the location of the device from which the signal is derived. Location is designated as the associated PLC if the signal type is an output.
5. Signal Type: Identifies the type of signal.
6. Notes: Provides additional reference information as necessary. 3.7 CONTROL STRATEGIES A. The Control Strategies, Attachment 17310-B, is appended to the end of this specification.
Integra Engineering 17310-13 CR37 6/29/2010
END OF SECTION
PLC Input/Output Summary
Device LocationJY 101 Denver Well kW/kWH VFD 101 Elect. Room Analog InputLY 101 Denver Well Level LT 101 Denver Well Analog InputSY 101 Denver Well Speed VFD 101 Elect. Room Analog InputJY 117 Arapahoe Well kW/kWH VFD 117 Elect. Room Analog InputLY 117 Arapahoe Well Level LT 117 Arapahoe Well Analog InputSY 117 Arapahoe Well Speed VFD 117 Elect. Room Analog InputPY CS1 Well Facility Discharge Pressure PIT CS1 Piping Room Analog Input
FI 101 Denver Well Flow Indication TCP Analog OutputFI 117 Arapahoe Well Flow Indication TCP Analog OutputSC 101 Denver Well Speed Control TCP Analog OutputSC 117 Arapahoe Well Speed Control TCP Analog Output
JA CS1 Well Facility Power Failure Phase Monitor MTS Discrete InputLAH CS1 Piping Room Flood Detection LSH CS1 Piping Room Discrete InputPAH 101 Denver Well Discharge Pressure High PSH 101 Piping Room Discrete InputPAH 117 Arapahoe Well Discharge Pressure High PSH 117 Piping Room Discrete InputTAH CS1 Electrical Room High Temperature TSH CS1 Elect. Room Discrete InputTAL CS1 Piping Room Low Temperature TSL CS1 Piping Room Discrete InputYA 101 Denver Well VFD Fault VFD 101 Elect. Room Discrete InputYA UPS UPS Low Battery UPS TCP Discrete InputYY UPS UPS Inverter On UPS TCP Discrete InputYY 101A Denver Well VFD in Hand Mode VFD 101 Elect. Room Discrete InputYY 101B Denver Well VFD in Remote Mode VFD 101 Elect. Room Discrete InputYY 101C Denver Well VFD Running VFD 101 Elect. Room Discrete InputYY 101D Denver Well System Control Valve in Remote CSCV 101 Piping Room Discrete InputYA 117 Arapahoe Well VFD Fault VFD 117 Elect. Room Discrete Input
YY 117A Arapahoe Well VFD in Hand Mode VFD 117 Elect. Room Discrete InputYY 117B Arapahoe Well VFD in Remote Mode VFD 117 Elect. Room Discrete InputYY 117C Arapahoe Well VFD Running VFD 117 Elect. Room Discrete InputYY 117D Arapahoe Well System Control Valve in Remote CSCV 117 Piping Room Discrete Input
ZA 1 Facility Intrusion Intrusion Controller TCP Discrete InputZA1A-01 Electrical Room Intrusion ZS1A-01 Elect. Room Discrete InputZA1A-02 Piping Room Intrusion ZS1A-02 Piping Room Discrete InputZA1A-03 Denver Well Intrusion ZS1A-03 Denver Well Discrete Input
NotesSignal Description Source Signal Type
Table 17310 A-1
PLC Input/Output Summary
Device LocationNotesSignal Description Source Signal Type
ZA1A-04 Arapahoe Well Intrusion ZS1A-04 Arapahoe Well Discrete InputZYH 101 Denver Well System Control Valve Open Position ZSH 101 CV 101 Discrete InputZYL101 Denver Well System Control Valve Closed Position ZSL 101 CV 101 Discrete Input
ZYH 101A Denver Well Pressure Relief Valve Open Position ZSH 101A Piping Room Discrete InputZYH 117 Arapahoe Well System Control Valve Open Position ZSH 117 CV 117 Discrete InputZYL117 Arapahoe Well System Control Valve Closed Position ZSL 117 CV 117 Discrete Input
ZYH 117A Arapahoe Well Pressure Relief Valve Open Position ZSH 117A Piping Room Discrete InputZYH CS1 Well Facility Pressure Relief Valve Open Position ZSH CS1 Piping Room Discrete InputZYL CS1 Well Facility Pressure Relief Valve Closed Position ZSH CS1 Piping Room Discrete Input
YC 101 Denver Well Call to Run TCP Discrete OutputYC 117 Arapahoe Well Call to Run TCP Discrete OutputYL CS1 Processor Fail TCP Discrete Output
FY 101 Denver Well Flow FIT 101 Piping Room ModbusYY 101E Denver Well VFD Communications VFD 101 Elect. Room ModbusFY 117 Arapahoe Well Flow FIT 117 Piping Room Modbus
YY 117E Arapahoe Well VFD Communications VFD 117 Elect. Room Modbus
Table 17310 A-2
ATTACHMENT 17310-B
CONTROL STRATEGIES
TABLE OF CONTENTS Page Standard Control Strategies Hand-Off-Auto Control (Field)....................................................................................17310B-1 Hand-Off-Auto Control (HMI) ....................................................................................17310B-2 Speed Control...............................................................................................................17310B-3 Position Control ...........................................................................................................17310B-4 Flow Totalization .........................................................................................................17310B-5 Runtime Accumulator ..................................................................................................17310B-6 Fail to Operate..............................................................................................................17310B-7 Time Based Control .....................................................................................................17310B-8 Process Control Strategies Well Pumping System..................................................................................................17310B-9 Intrusion Detection System ........................................................................................17310B-15
Integra Engineering 17310B-1 CR37 6/29/2010
STANDARD
HAND-OFF-AUTO (FIELD)
I. General Description This standard control feature provides for Hand-Off-Auto control mode selection via a three-position selector switch located at the process equipment, telemetry control panel (TCP), or motor controller.
II. Control Logic When the Hand control mode is selected, the associated equipment will operate continuously until the selector switch is returned to the Off or Auto position, or is shut down upon a hardwired safety interlock. When the Auto control mode is selected, the PLC control logic will be enabled.
III. Human Machine Interface The HMI will be located at the Ray Waterman control facility. A Hand-Off-Auto selector switch object will be included on the HMI screen. The selector switch object will indicate the current mode of control and provide a means for operator selection of the control mode.
Integra Engineering 17310B-2 CR37 6/29/2010
STANDARD
HAND-OFF-AUTO (HMI)
I. General Description This standard control feature provides for Hand-Off-Auto control mode selection via a three-state selector switch object defined in the process control system HMI.
II. PLC Control Logic The PLC control logic will respond to the selection of the Hand-Off-Auto control modes made through the HMI. When the Hand control mode is selected, manual control features will be available through the HMI. When the Auto control mode is selected, the automatic control logic will be enabled.
III. Human Machine Interface The HMI will be located at the Ray Waterman control facility. A Hand-Off-Auto selector switch object will be included on the control panel. The selector switch object will indicate the current mode of control and provide a means for operator selection of the control mode.
Integra Engineering 17310B-3 CR37 6/29/2010
STANDARD
SPEED CONTROL
I. General Description This standard control feature provides for manual adjustment of operating speed.
II. PLC Control Logic The PLC control logic will be defined to accept an operator-entered value to directly control the operating speed of process equipment. This feature will generally be available when the process equipment is being operated in the manual control mode.
III. Human Machine Interface The HMI will provide for operator adjustment of the speed parameter. The speed parameter will be ranged 0 to 100 percent of full speed.
Integra Engineering 17310B-4 CR37 6/29/2010
STANDARD
POSITION CONTROL
I. General Description This standard control feature provides for manual adjustment of operating position.
II. PLC Control Logic The PLC control logic will be defined to accept an operator-entered value to directly control the operating position of a control valve. This feature will generally be available when the valve is being operated in the manual control mode.
III. Human Machine Interface The HMI will provide for operator adjustment of the position to full open, or full closed.
Integra Engineering 17310B-5 CR37 6/29/2010
STANDARD
FLOW TOTALIZATION
I. General Description This standard control feature provides for totalization of process variables that represent flow.
II. PLC Control Logic The PLC control logic will be defined to generate a totalized value for all process variables that represent flow. A program file will accept flow values from the flow transmitter communicated through Modbus protocol. The totalized value will be reported to the HMI in units to be selected by the end user. Totalizer values will be maintained in the PLC for the current day and previous day. Totalizers will be conditioned to accumulate flow only when the pump or valve controlling the flow condition is operating or open. This will prevent the accumulation of zero-drift error.
III. Human Machine Interface Each of the daily totalizer values will be available through the HMI.
Integra Engineering 17310B-6 CR37 6/29/2010
STANDARD
RUNTIME ACCUMULATOR
I. General Description This standard control feature provides for accumulation of runtime hours for all process equipment that the run status is monitored by the process control system.
II. PLC Control Logic The PLC control logic will be defined to monitor process equipment run status and generate a runtime hour accumulator value. A program file triggered by a selectable time interrupt will monitor the process equipment run status. The selectable time interrupt will be set for one second. Each time the program executes and the process equipment run status is true a second will be added to a runtime seconds accumulator. When the seconds accumulator equals 3600, a hour will be added to the runtime hour accumulator. Four individual runtime accumulators will be maintained for each equipment item. These accumulators are defined as follows:
Current Day: Current day’s runtime. Previous Day: Previous day’s runtime. Total: Non-resettable accumulator indicating total runtime. Maintenance: Resettable accumulator indicating runtime between maintenance activities.
III. Human Machine Interface The process equipment runtime hour accumulator will be available through the HMI.
Integra Engineering 17310B-7 CR37 6/29/2010
STANDARD
FAIL TO OPERATE
I. General Description This standard control feature monitors process equipment to insure the equipment is operating properly in response to a control command.
II. PLC Control Logic The PLC control logic will be defined to monitor the operational status of the process equipment and generate an alarm condition if the operational status does not reflect the commanded state of the equipment. For example, if a pump is commanded to run and the pump run status is not proven within 5 seconds a fail to run alarm will be generated.
III. Human Machine Interface A fail to operate alarm will be defined for process equipment controlled and monitored by the process control system.
Integra Engineering 17310B-8 CR37 6/29/2010
STANDARD
TIME BASED
I. General Description This standard control feature provides for time-based control of process equipment.
II. PLC Control Logic The PLC control logic will be defined to operate the process equipment on a timed interval basis. Upon expiration of the time interval, the process equipment will be operated for a prescribed duration.
III. Human Machine Interface The HMI will provide for operator adjustment of the operating interval and duration. The HMI will also display the time expired for both the operating interval and duration.
Integra Engineering 17310B-9 CR37 6/29/2010
PROCESS EQUIPMENT
WELL PUMPING
I. General Description The Canyons South #1 Well Facility is fed from two well pumps, Denver Deep Well Pump CR-101, and Arapahoe Deep Well Pump CR-117. Water from the wells is routed through pipes fitted with pressure relief valves, pressure switches, system control valves, propeller flow meters, and magnetic flow meters. A pressure relief valve and pressure indicating transmitter are located on the well facility discharge header.
II-A. Well Pump - Process Equipment and Controls A. Well pumps, P 101, and P 117.
B. VFD controller, VFD 101 and VFD 117 to serve each well pump.
C. Individual control station (at telemetry control panel TCP) for each pump.
D. Well level transmitters, LT 101, and LT 117 for each well.
E. Well discharge pressure switch, PSH 101, and PSH 117.
F. Well discharge flow indicating transmitters, FIT 101, and FIT 117.
G. Well facility discharge pressure indicating transmitter, PIT CS1.
H. Well blowoff flow meters (local readout only) FE/FI 101, and FE/FI 117.
II-B. Control Valves - Process Equipment and Controls A. Blowoff pressure relief valves, PRV 101, and PRV 117.
B. System control valves, CV 101, and CV 117.
C. Individual control station for each system control valve, CSCV 101, and CSCV 117.
D. Well facility discharge pressure relief valve PRV CS1.
III-A. Well Pump - Process Floor Operator Interface A. Controls for each pump are located on their associated VFD, including the following
operator control devices:
1. Operator interface keypad.
III-B. Well Pump - Process Floor Operator Interface A. Controls for each pump are located on Telemetry Control Panel (TCP), including the
following operator control and monitoring devices:
1. Digital indicator, well level (feet), LI 101, and LI 117.
Integra Engineering 17310B-10 CR37 6/29/2010
PROCESS EQUIPMENT
WELL PUMPING (Continued)
2. Digital indicatior, discharge flow (MGD), FI 101, and FI 117.
3. Elapsed time meter (hours), ETM 101, and ETM 117.
4. Cycle counter, CTR 101, and CTR 117.
5. Run indicating light (green), YL 101A, and YL 117A.
6. Off indicating light (red), YL 101B, and YL 117B.
7. Reset pushbutton (black), PB 101, and PB 117B.
8. Hand-Off-Auto selector switch, HS 101, and HS 117.
B. Well facility indicators located on Telemetry Control Panel (TCP), include the following devices:
1. Digital indicator, discharge pressure (psi), PI CS1.
2. Processor failure indicating light (red), YL CS1.
III-C. System Control Valves - Process Floor Operator Interface A. Controls for each control valve are located adjacent to the valve in the piping room,
including the following operator control devices:
1. Open-Off-Close-Auto selector switch, CSCV 101, and CSCV 117.
B. Controls integral to each system control valve include:
1. None.
IV-A. Well Pump - Hardwire Control Interface A. Positioning the Hand-Off-Auto selector switch to Hand will cause the associated pump to
operate at an operator adjustable speed. Speed adjustment is made through the operator interface keypad located on the VFD.
B. Positioning the Hand-Off-Auto selector switch to Auto will cause the associated pump to respond to control from the process control system. Refer to Remote Control Description below.
C. In any mode of operation, detection of a VFD fault condition will cause the pump to shut down. A VFD fault condition will require resetting at the associated VFD.
D. In any mode of operation, detection of a high pump discharge condition (PSH) will cause the pump to shut down. A high pump discharge condition will require depressing the reset pushbutton at the Telemetry Control Panel.
Integra Engineering 17310B-11 CR37 6/29/2010
PROCESS EQUIPMENT
WELL PUMPING (Continued)
E. In any mode of operation, shutdown of a pump will require that restart is delayed for an operator-adjustable time (timing relay located in TCP) duration. A shutdown condition will require depressing the reset pushbutton at the Telemetry Control Panel.
IV-B. System Control Valve - Hardwire Control Interface A. Positioning Open-Off-Close-Auto selector switch, at the system valve to Open or Close
will cause the control valve to travel to the desired direction.
B. Positioning the Open-Off-Close-Auto selector switch, at the system valve to Auto will permit the process control system to control the valve. Refer to Remote Control Description below.
C. Positioning the Open-Off-Close-Auto selector switch, at the system valve to Off will inhibit control of the valve locally and from the process control system.
IV-C. Pressure Relief Valve – Hardwire Control Interface A. None provided.
V-A. Well Pump - Process Control System Software Functions
Control Functions
Data Development Primary Control Type
Hand/Off/Auto Flow Totalization Pump up/down
On/Off Runtime Accumulation
Time based
Speed Control Event based
Position Control
Equipment Status Feed forward
Seal Water Fail to Operate Regulatory PID
Lead Alternation
Modbus Controller Data
PV:
P SP:
CV:
Integra Engineering 17310B-12 CR37 6/29/2010
PROCESS EQUIPMENT
WELL PUMPING (Continued)
V-B. Control Valve - Process Control System Software Functions
Control Functions
Data Development Primary Control Type
Hand/Off/Auto Flow Totalization Pump up/down
On/Off Runtime Accumulation
Time based
Speed Control Event based
Position Control
Equipment Status Feed forward
Seal Water Fail to Operate Regulatory PID
Lead Alternation
Modbus Controller Data
PV:
SP:
VI-A. Well Pump - Remote Control Description A. In the Local mode of operation, the pump will operate continuously at an operator-
selected speed made through the operator interface keypad located on the VFD.
B. In the Remote mode of operation, the well pump will be operated and its speed regulated at an operator-adjustable speed setpoint through the HMI.
C. The pump shall be shut down in either mode of operation if any of the following conditions occur:
1. High discharge pressure (XXpsi, increasing) as indicated by PSH 101 or PSH 117. Indication of a high disharge pressure condition shall initiate an operator-adjustable time (timing relay located in TCP) duration.
2. VFD fault condition.
3. Pump run timer relay trip.
4. Well facility power failure.
D. The pump shall be shut down in the Auto mode of operation if the following events occur:
1. Low well level as indicated by LT 101 or LT 117.
Integra Engineering 17310B-13 CR37 6/29/2010
PROCESS EQUIPMENT
WELL PUMPING (Continued)
E. Pump run time and number of starts shall be indicated on elapsed time meters and counters on the front of Telemetry Control Panel (TCP).
VI-B. Pressure Regulating Valves (Well Pump) - Control Description A. The pressure regulating valves operate in response to the well pump discharge pressure.
There are no hardwired controls associated with the open or close control of the pressure regulating valves. The pressure regulating valve will open when the pump pressure exceeds the pressure regulating valve setting. The pressure regulating valve Open position will be monitored by limit switch ZSH 101 or ZSH 117. Indication of a pressure regulating valve Open position will initiate the waste timing sequence.
VI-C. System Control valves (Well Pump) - Remote Control Description A. In the Hand mode of operation, the valve position will be operator-selected.
B. In the Auto mode of operation, well pump startup will cause the pressure regulating valve to Open, and the system control valve (CV 101 or CV 117) shall remain closed. The pump shall pump to waste for an operator-adjustable time (timing relay located in TCP) duration. At the expiration of the pump to waste time duration, the system control valve will be called to open, and the pressure regulating valve will close in response to the drop in pressure. If the system control valve fails to obtain the commanded position within an operator-adjustable time duration (initially set at XX seconds, through the HMI), a “Well Supply Valve Problem” alarm condition shall be annunciated through the HMI. If the pressure regulating valve fails to close after an operator-adjustable time (timing relay located in TCP) duration a “Waste Valve Open to Drain” alarm condition shall be annunciated through the HMI. All waste sequence control logic shall be implemented with hardwired relay logic.
C. The system control valves shall return to the closed position when the well pump is shut down.
Integra Engineering 17310B-14 CR37 6/29/2010
PROCESS EQUIPMENT
WELL PUMPING (Continued)
VII. Process Variable, Status, and Alarm Monitoring
Process Variable Equipment Status/Alarms
1. Well level.
2. Well facility discharge pressure.
3. Well pump discharge flow.
4. VFD speed.
1. Valve Open/Closed position.
2. Hand-Off-Auto selector switch in Auto position.
3. Hand-Off-Auto selector switch in Hand position.
4. Pump running
5. VFD fault.
6. High Pressure
Integra Engineering 17310B-15 CR37 6/29/2010
PROCESS EQUIPMENT
INTRUSION DETECTION SYSTEM
I. General Description The intrusion detection system consists of magnetic switches mounted at each well pitless adapter and building entrance doors, entry keypads located in the piping and electrical rooms, and a control panel located in Telemetry Control Panel TCP.
II-A. Process Equipment and Controls A. Electrical Room Intrusion Switch, ZS1A-01.
B. Piping Room Intrusion Switch, ZS1A-02.
C. Denver Well pitless adapter Intrusion Switch, ZS1A-03.
D. Arapahoe Well pitless adapter Intrusion Switch, ZS1A-04.
E. Electrical Room Entry Keypad, HC-01.
F. Piping Room Entry Keypad, HC-02.
G. Intrusion Control Panel.
III-A. Process Floor Operator Interface A. Entry Keypads are located inside the Electrical and Piping Rooms. Personnel entering
the well facility are required to enter a code to disable an alarm upon entering the facility.
IV-A. Hardwire Control Interface A. The intrusion switches are interfaced to the intrusion control panel through relays. The
entry keypads are wired directly to the intrusion control panel.
B. The intrusion control panel provides a contact output for Facility Intrusion indication at the HMI.
END OF SECTION
Integra Engineering 1095 South Monaco Parkway
Denver, Colorado 80224 (303) 825-1802 p (303) 825-2322 f