BMS

Christchurch International Airport Limited CIAL Facilities Services

Policy & Procedures Manual BMS Methodology

Authorised By: Compiled By:

Manager Airport Facilities HVAC Engineer

Date Issued: 10 March 2010 Index: G205

s:\operations and infrastructure\facilities services\general\standards\bms policy & methodology.doc Page 1 of 44

BMS METHODOLOGY

1 PURPOSE

This document identifies the methodology used for programming the Christchurch International

Airport Limited (CIAL) BMS.

2 SCOPE

Intended for use by Facilities Services Staff and for use by Consulting Engineers and Contractors to

assist with the design of BMS controlled systems. Included in this document is a detailed

description of how BMS points are designated, and the control philosophy behind this. Also

included in the appendices are examples of actual systems.

3 CONTINUOUS IMPROVEMENT

It is the policy of CIAL Facilities Services to continually improve (for example as needs or

technology changes). This then creates an ongoing need to make alterations to this document. The

reader must ensure that the current version is being used.

To assist CIAL Facilities Services to continually improve, please advise the Manager Airport

Facilities if there is something in this document that is missing or that can be improved upon.

4 COPYRIGHT

Please feel free to copy this document, however before doing so, ensure:

Approval is obtained from the Manager Airport Facilities.

The document is copied in its entirety.

CIAL Facilities Services are acknowledged as the original source.

5 INFORMATION CONTACTS

CIAL Facilities Services staff and the Manager Airport Facilities may be contacted by telephoning

CIAL Facilities Services (ph: 353-7080). The fax number is 353-7090 and the E-mail address is

[email protected]. CIAL Facilities Services is located at 818 Wairakei Rd.

6 ASSOCIATED DOCUMENTS

CIAL Facilities Services Procedure - “Requirements for Contractors” document.

CIAL Facilities Services Procedure - “Requirements for Contractors”

CIAL Facilities Services Procedure - “CIAL Asset Numbering Protocol”

CIAL Facilities Services Procedure - “Electrical and Electrical for Mechanical”

CIAL Facilities Services Procedure - “Mechanical Installation”

CIAL Facilities Services Procedure - “Preferred Mechanical and Electrical Materials”

CIAL Facilities Services Procedure - “Split System heat Pump Installation”







Appendices - Examples of actual systems

Appendix A - CIAL - IP Address for BMS

Appendix B - Generators Priority Alarm Message Types

Appendix C - CIAL - Apron Expansion Acronyms for Plants Controllers and Devices

Appendix D - B1 Chillers 1 & 2 Condenser Pumps & R4 Cooling Towers CT 1 & 2 Controls

Appendix E - Apogee Graphics

7 CIAL - BUILDING MANAGEMENT SYSTEM (BMS)

7.1 INTRODUCTION

There have been continuous developments over the years to the existing airport terminal, resulting

in a number of control systems being installed. These systems have had numerous extensions,

changes and ongoing alterations occurring, along with changes in technology and manufacturer.

This has left the site, at present, operational but disjointed with respect to the building

management system.

CIAL BMS currently consists of four systems, namely:-

a) Siemens ‘Staefa MS2000’ (DOS based). - This manages systems in the International Terminal Building, the Antarctic Admin Building, parts of the Domestic Terminal building, Yard Maintenance Office, Power Centre 5, Western Grass and some other remote parts of the Terminal.

b) Siemens ‘Staefa MS1800’ (Windows based). – As a backup to the ‘MS2000’ system, this is used as an alternative for downloading data to the Staefa system.

c) Honeywell ‘XFI’ / ‘EBI’ (Windows based). - This manages systems in the Domestic Terminal Building, and Antarctic Visitors Centre.

d) Siemens ‘APOGEE’ (Windows based). - This manages systems in the International Terminal Apron Expansion Building, some parts of the Terminal, and potentially any new building such as the new Carpark building. Together with the Staefa ‘MS1800’ (Windows based), it will virtually replace the above Siemens ‘Staefa MS2000’.

The objective is to move towards a system with the capability of an open architecture/protocol that

will provide a fully integrated system with open protocol communications between equipment and

controllers and facilitates flexible use of systems.

This will:-

a) enable the selection, installation and use of products with the best capabilities to be chosen for the task rather than being “locked” into certain vendor’s proprietary products, maintenance and processes,

b) enable alternative suppliers of compatible products if the single vendor platform becomes unsustainable,

c) ideally allow a single front end, capable of interfacing, receiving alarms, controlling and integrating systems on all the existing and any new control platforms.







For integration of different control systems, the following will be required:-

a) All necessary engineering data from manufacturers is desirable for a successful interface.

b) Training of any new software packages from manufacturers and/or vendors.

c) Manufacturers to provide all necessary engineering software tools and/or workstations for the open protocol implementation; (such as BACnet) and (LONworks).

d) Vendors with local and experienced qualified support staff 24/7, is desirable.

e) In the unlikely unavailability of local qualified support during emergency, access to next level of support (such as overseas or equivalent manufacturer support) is desirable.

7.2 SYSTEM DESIGN REQUIREMENTS

It is essential that any investment enhances the benefit of having the entire campus as an

integrated system. TCP/IP is the network solution as this presents an opportunity for closer

integration based on a common building automation standard.

The integrated system will incorporate other specialist 3rd party building systems and will be

applicable to not only the HVAC, but also the fire, security, access control, maintenance, lighting,

power management, electrical systems monitoring etc, providing a seamless control of the building

management. This will require an open relationship between the 3rd parties and the BMS vendor.

The communications platform will be via the existing CIAL site ethernet network, enabling TCP/IP

access and distributed architecture for real-time access, automation and control of devices.

Control systems must have the capability to use Building control industry standard communication

protocols such as BACnet, LONworks, Modbus, etc to enable a truly open system architecture.

7.3 WORKSTATIONS

There shall be two types of workstations; - Operator and Engineering Workstations.

Operator Workstation

a) Will have the facility to access all systems ie: fire alarm (monitoring only), security (with authority), HVAC, lighting, power management etc.

b) Will be easy to use for non-technical operators; using standard windows type commands and keystrokes.

c) Will have simple and easy navigation via site plans and simple graphics that tunnel down to specific areas.

d) Will not require special software or software license keys (dongles). to facilitate access to graphics, set point and time schedule adjustment and historical trend data.

e) Will be web based enabling all of the above to be accessed via a standard web browser.

f) Will have User Login, providing access that is appropriate for the user type eliminating tampering and miss-use of the system.







Engineering Workstations

a) Will be centrally located within the BMS/Maintenance control room

b) Will have all the facilities as in Operator Workstation and

a) Will provide full engineering functions as well as a centralised data base back up, storage and restore facility.

7.4 SITE ARCHITECTURE

The BMS shall have client/server architecture, with capability of an extended system with multiple

servers and stations connected across LANs or WANs.

The internal TCP/IP network will be available and used to link all locations and system types

together around the site.

Control system hardware will require either onboard ethernet connection or be connected by an

ethernet gateway to provide connection into the existing site network at each major plant room

location. Each ethernet connection must be able to 100% support the UDP and TCP/IP protocol

suite.

System Configuration

The BMS shall be configured as a fully distributed intelligent system that includes

Management Level Network (MLN) that supports

o BACnet and OPC over TCP/IP,

o ODBC database access and AdvanceDDE,

o Web access,

o Minimum of 40 simultaneous workstations per BMS server,

o Other building systems of different third-party suppliers with standard open protocol

o Devices and controllers directly utilizing TCP/IP as Automation Level Network (ALN),

or as peer-to-peer Building Level Network (BLN)

o Integration with subsystems including

− HVAC monitoring and control

− Lighting control

− Power Metering and management

− Energy Usage monitoring and management

− Maintenance Management Systems

− Fire monitoring

− Security monitoring

− Access controllers and access card readers

− CCTV systems

− Photo ID integration

− Programmable Logic Controllers (PLC)

− Life safety







− Industrial Control

− Digital video management

− Email, Mobile Phone, paging, and SMS notification

− Other BMS

Building Level Network (BLN) that supports

o Standalone controllers that connects to the MLN via TCP/IP,

o Standalone controllers that connects via RS485 to BMS Server on the MLN,

o Standalone controllers that supports Lonworks, Modbus, BACnet, and other vendor

specific protocols,

o Unlimited Workstations

Floor Level Network (FLN) that supports

o Lonworks, Modbus, BACnet, and other vendor specific protocols,

o Standalone specific controllers such as VAV, FCU, HTP, and other DDC controllers

o Other third-party controllers with standard open protocols,

o PDAs

Response Times

The controls system Specialist Controls Sub Contractor (SCSC) will engineer the control systems to

ensure the following maximum response times between update of data at the operator workstation

Alarm or Critical points – 1 sec.

Digital points – 3 secs.

Non-critical points – 5 secs.

Responsibility of SCSC and CIAL IT Engineer

a) Not withstanding the above, it is the responsibility of the SCSC to ensure that all response times shall be appropriate for the system being controlled. For example, a ‘DO’ for environmental lighting should operate within 0.5 sec of ‘DI’ status change.

b) If data points take longer than this, the SCSC must prove their system performance at the location of the network connection (without using the existing network).

c) The SCSC will work closely with the CIAL IT engineers to communicate their network requirements to ensure maximum performance of their system including response time.

d) If CIAL traffic network is too congested, slowing down the response time, CIAL IT engineers will work to improve this.

e) Responsibility to manage the network and provide the performance required will be by CIAL IT engineers, but will require collaboration between both parties, even though there is a line of demarcation and accountability.

f) It is essential for the SCSC to be competent and conversant with ethernet networks and IT systems.

Integration with CIAL Maintenance Management System (MMS)







The BMS must be able to integrate with CIAL MMS using standard IT protocols such as ODBC, OPC,

etc., for shared database.

Information from the BMS such as ‘Filter dirty’, ‘Fuel tank low’, ‘Run times of systems’, etc shall be

communicated to the MMS in order that automated work orders can be generated.

Equipment shall be identified in the BMS and MMS in accordance with the CIAL asset register

naming protocol.

The Specialist Controls Sub Contractor will adopt the nomenclature and comply with open

architecture protocols to take maximum advantage of the open system architecture.

7.5 REMOTE ACCESS

The CIAL IT department will manage the existing network, with access given only in accordance

with the CIAL IT protocol.

Remote access will provide all of the functions that are available when onsite, without the need for

special software or dongles.

Remote engineering should also be provided via the network connection, though specific software

and dongles maybe required to provide this level of management.

Generally a facility will be provided for tenancies to access the system with restricted control via

on/off push buttons for after hour’s operation, where appropriate. Certain tenants or CIAL staff,

with higher but restricted access shall be able to use the web browser (using their logins) to access

their zones of interest and even change set points or their own schedule of operations instead of

on/off push buttons.

7.6 ENGINEERING

Internal/technical staff will be trained to manage and modify the site wide building control systems.

Not all of the control systems engineering functions may be available through the standard web

browser, where this is applicable vendor specific engineering tools will be provided.

Where these are required for full management and modification of the system, then these tools will

be made available and included in the contract whenever a new type of control system is

introduced to the site. Technical staff training will be included to enable sufficient use of the new

engineering tools by the internal technical staff.

Engineering tools will be supplied with no ongoing maintenance or license fees.

The engineering tools will provide the ability to easily carry out the following functions from any

network connection, without the requirement to connect to each controller locally):

Create / modify / delete physical and virtual points.

Create / modify / delete system function such as alarms, trends, control loops, time schedules,

optimum start/stop etc.

Create / modify / delete programmable control logic, text or graphical based.







Modify programmable control logic on line without the need to download for the changes to

take effect.

Download controller databases.

Upload controller databases.

View dynamic plots of trend data

Run a full compliment of data and history reports (and save to .csv)

Display a full system profile for adding new devices to the network and also controller

diagnostics

7.7 CONTROLLER HARDWARE

All Controllers will have the capability to communicate via standard protocols such as BACnet,

LONworks, Modbus, etc so that integration can occur at any level within the control architecture.

Primary Network Controllers (Automation Level Network ALN)

These controllers:-

Shall be fully programmable and provide standalone operation locally and incorporate built in

energy management strategies such as;

− Peak demand limiting,

− Start-Stop time optimization,

− Equipment scheduling, optimization and sequencing,

− Temperature compensated duty cycling,

− Economizer control,

− Night setback control,

− Automatic Daylight Savings Time switchover,

− Temporary schedule override,

− Holiday scheduling,

− Calendar-based scheduling, and

− Event scheduling.

Must have removable plugs connections to provide easy controller replacement.

Must have a fast enough input scanning to be able to support momentary push button type

inputs eliminating the need for the operator to hold the button, ie: a field response time of no

greater than 3 seconds.

Shall have significant capacity for expansion, trending, and programming. (Limitations of

memory etc. must be disclosed)

Are to be able to communicate back to the CIAL BMS workstation using BACnet/IP and the

existing CIAL TCP/IP network.

Shall have auto sensing of comms fail, TCP/IP Ethernet ports and be compatible to the BACnet

standard.







Shall have standard PID control function. Controllers with the new “Free Adaptive Control

Technology” function which replace PID control functions will be preferred.

Shall support Lonworks, Modbus, BACnet, and other vendor specific protocols,

Secondary Network Controllers (Floor Level Network FLN)

These are usually application based terminal equipment controllers specially designed to control

Fan Coil Units, VAV systems and Heatpumps.

These controllers:-

Shall have the facility to provide standalone operation locally.

Must have removable plugs connections to provide easy controller replacement.

Shall have ‘Afterhours’ push buttons for operation outside of normal operating hours.

Using approved LONworks technology or other approved ‘Open technology’, shall be able to

communicate with the Primary Network Controller/s.

Shall preferably have true differential pressure monitoring transducers onboard, over the mass

flow type devices and “single point hotwire type airflow pickups”, to provide more accurate

volume measurement, especially if used in VAV systems.

Shall be provided with any software tool necessary for commissioning & engineering.

System Note

To assure CIAL of the long term support and maintenance costs of the BMS system;-

All system controllers shall have a documented history of compatibility by design for a

minimum of 15 years.

Future compatibility shall be supported for no less than 10 years.

Compatibility shall be defined as

a) the ability to upgrade existing field panels to current level of technology, and extend

new field panels on a previously installed network.

b) the ability for any existing field panel microprocessor to be connected and directly

communicate with new field panels without bridges, routers or protocol converters.

7.8 CONTROLLER POWER SUPPLY

All controllers must be powered by ‘Essential’ supply, and backed by suitable UPS for at least 5

minutes, to prevent nuisance alarms back to the BMS.

7.9 ALARM NOTIFICATION

The BMS must be able to provide alarm notification via the network to the following

Email (preferred option)

SMS (via email on CIAL network tokens – A separate modem is not permitted on CIAL

networks because of security issues)

Printers







Fax

Alpha numeric pager (via email on CIAL network tokens – A separate modem is not permitted

on CIAL networks because of security issues)

Alarm must be able to be sent simultaneously to various devices based on time of day, alarm

priority, alarm type etc.

The alarm shall be able to escalate after a user defined delay to notify other users.

In the event of any Primary Network Controller or Secondary Network Controller failure/power

down, this must be reported as an Alarm to the above devices.

7.10 SYSTEM GRAPHICS

The control system supplier will provide site web based graphics for each system, using

standard graphics creation software.

The graphics must be able to be created easily, and will be kept as simple as possible and be

user friendly for use by non-technical staff.

Graphics will be stored on a PC based web server (preferred option) or in controller type web

servers.

Graphics shall incorporate graphical picture control link facility to word documents, control

wiring drawings, as built documents by double clicking on the link.

Animation shall be provided to indicate fans and pumps operating and also to show damper

positions.

A point memo function shall be attached to the alarm for easy operator recognition and for

passing on information between operators and engineers regarding the state of the various

systems. Preferably the point memo will automatically be erased and stored in history after

the alarm point has returned to normal and has been acknowledged.

The graphics creation/editing tools will be made available and supplied as part of the contract

if not already on site, with no ongoing maintenance or license fees.

Technical staff training will be included, enabling sufficient and knowledgeable use of the

graphical tools.

Graphics must be able to provide the following minimum functions:-

a) Importing of standard drawing formats, such as Autocad or MicroStation.

b) Animated graphic symbols to easily indicate plant running status.

c) Auto/manual status of outputs and set points. NB:- These must be clearly differentiated by colour coded or ‘hand’ icon. ‘Manual’ status shown in text is not acceptable.

d) Easy adjustment of set points and time schedules.

e) Point status

Graphic Refresh. A graphic with 20 dynamic points shall update with current data within 8 sec.

and shall automatically refresh every 15 sec.

Configuration and Tuning Screens. Screens used for configuring, calibrating, or tuning points,

PID loops, and similar control logic shall automatically refresh within 6 sec.







Alarm Response Time. An object that goes into alarm shall be annunciating at the workstation

within 15 sec.

Program Execution Frequency. Custom and standard applications shall be capable of running

as often as once every 5 sec

7.11 DATABASE MANAGEMENT

All new controller and graphic databases will be supplied once the project is complete for inclusion

into their back-up storage facility.

If a modification to an existing control system is required the current database (after a back-up

copy is made), will be provided for modification by the vendor. Once the project is complete the

amended database will be returned. The vendor must take all care to ensure that modification of

the database does not corrupt any part of the other database.

To ensure that multiple data bases of different version and revisions do not exist the BMS

workstation is responsible for all database backups and restores to all ALN controllers from this

common location without the need for separate databases for workstations and controllers.

All Secondary Network Controllers setup parameters and modifications (i.e. PID tuning, setpoints,

parameters etc) shall be updated and held in the controllers and the BMS workstation.

The BMS workstation shall be programmed to automatically back up the entire data base on a

regular time event (adjustable by CIAL staff).

7.12 INTERFACING TO OTHER EQUIPMENT

Any energy meters, generator equipment, PLCs, power meters, lighting control equipment, power

monitoring equipment etc provided by 3rd parties shall be able to communicate with the BMS via

open protocol such as the Modbus RTU protocol, BacNet, etc.

Graphics and schematic drawings etc shall be generated.







8 GENERIC CONTROL PROTOCOL REQUIREMENTS

8.1 The BMS shall be used to directly control building systems (discreet controls shall not be used).

The following schedule shows the minimum functionality, which is expected of the BMS. Note: the schedule does not identify all the details for

controls functionality. The designer shall fully investigate and coordinate BMS controls requirements with CIAL Facilities Services for each

project.

Equipment Functions (Typical) Point Types (Typical) Alarms (with Alarm Messages) (Typical)

Fans

• Start/stop to suit system function

• Fan Status by differential pressure switch or current transducer

• VSD control

• Fire control (if required)

• Pressure Control (if Required)

• Duty/standby or Lead/lag control

• Run Time total

• Digital Output

• Digital Input

• Analog Output

• Digital Input or/and Virtual

• Analog Input

• Virtual

• Virtual

• Fan fail

• Feedback (I/O mismatch)

Pumps

• Start/stop to suit system function

• Pump Status by differential pressure

switch, current transducer, flow

switch

• VSD control

• Demand Control (if required)

• High Level Alarm Control (if req’d)

• Pump Motor Overload (if req’d)


• Run Time total

• Digital Output

• Digital Input

• Analog Output

• Analog Input

• Digital Input

• Digital Input

• Virtual

• Virtual

• Pump fail

• Feedback (I/O mismatch)

• High Level (if req’d)

Air Handlers • Supply Fan start/stop

• Return Fan start/stop

• Digital Output

• Digital Output

• Fans fail • Fans Feedbacks (I/O mismatch)








• Smoke Fan start/stop (if required)

• Fans Status by differential pressure switches or current transducers

• Fans VSD control

• VSD Faults

• Duct Smoke Detector

• Spring Return Sup.Air Damper

• Spring Return Rtn.Air Damper

• Exhaust Air Damper

• Dampers Position (if Req’d)

• Outside Air Quality (Damper Control)

• Outside Air Temperature

• Return Air Quality

• Return Air temperature

• Space Air Quality (Damper Control)

• Supply Air Temperature

• Filter monitoring by differential pressure switch or sensor

• Heating valve modulation

• Artesian Cooling valve modulation

• Chill Wtr. Cooling valve modulation

• Humidity modulation if applicable

• Fire and smoke control (from Fire or adjacent Fire Zones)

• AfterHrs Control

• ‘Suck down’ Control (negative

• Digital Output

• Digital Inputs

• Analog Outputs

• Digital Inputs

• Digital or Analog Input

• Analog Output / Digital Output

• Analog Output / Digital Output

• Analog Output

• Analog Inputs

• Analog Input

• Analog Input

• Analog Input

• Analog Input

• Analog Input

• Analog Input

• Digital or Analog Input

• Analog Output

• Analog Output

• Analog Output

• Analog Output

• Digital Input or/and Virtual

• Digital Input or Virtual

• Analog Input and Virtual

• Dirty Filter

• Smoke alarm.

• ‘Negative AHU Pressure’








pressure due to faulty dampers)

• FIDs Interface Control

• Economiser Control (Free Cooling)

• Minimum Fresh Air Control

• Supply Air Temperature Reset control

• Enthalpy Control


• Run Time total

• Modbus and Virtual

• Virtual

• Virtual

• Virtual

• Virtual

• Virtual

• Virtual

Chillers

• High Level Interface to local control panel or/and

• Start/stop or

• Arm/Disarm chillers if local control

• Chillers Status

• Water temp in/out monitoring

• Load monitoring from chiller control panel

• Chiller signal to control condenser flow and clg twr fans

• Chiller faults

• Chill Water Flow Switch

• Load Current

• Load Monitoring

• Condensor Pump request (if Req’d)

• Condenser Pump VSD

• Primary W. Pump request (if Req’d)

• Clg. Twr. Fan VSD

• Bacnet, Modbus, or OPC

• Digital Outputs

• Digital Outputs

• Digital Inputs

• Analog Inputs

• Analog Inputs

• Analog Input

• Digital Inputs

• Digital Input

• Analog Input

• Analog Input

• Digital Input & Output

• Analog Output

• Digital Input & Output

• Analog Output

• Flow failure

• Chiller Failure/fault

• Water leak in close loop system from water makeup

• High Temperature

• Feedback

• Wet floor sensor (plantroom only)

• Other Alarms via High level I/F if used.








• Temperature setpoint reset

• CHW Flow Temp. setpoint Reset

• Water Pressure for Water Leak Detection in Close Loop system

• Wet Floor Sensor

• Duty and Lead/Lag Control

• Demand limiting

• Run Time total

• Other I/Os if no local panel used

• Analog Output

• Analog Output

• Analog Input

• Digital Input

• Virtual

• Virtual

• Virtual

• Various Inputs & Outputs

Boilers

• High Level Interface to local control panel or/and

• Start/stop or

• Arm/Disarm boilers if local control

• Boilers Status

• Common and Individual Boiler Flow Water temp monitoring

• Common and Individual Boiler Return Water temp monitoring

• Damper modulating for gas boilers

• Damper monitoring for gas boilers

• Boilers faults

• Demand limiting

• Temperature setpoint reset

• Water Pressure for Water Leak Detection in Close Loop system

• Wet Floor Sensor

• Bacnet, Modbus, OPC, or Hard-wiring if specialise Controller is used.

• Digital Outputs

• Digital Outputs

• Digital Inputs

• Analog Inputs

• Analog Inputs

• Analog Outputs or Local modulating control

• Analog Inputs

• Digital Inputs

• Virtual

• Analog Output

• Analog Input

• Digital Input

• Flow failure if applicable

• Boilers Failure/fault

• High and Low temp

• Water leak in close loop system from

water makeup

• Feedback

• Wet floor sensor (plantroom only)








• Diff. Pressure for Bypass valve Control

• Duty and Lead/Lag Control

• Run Time total

• Analog Input

• Virtual

• Virtual

VAV boxes

• Local VAV controllers with all necessary Temperature and Air flow control by damper modulation with electric reheat or heating coil valve modulation and/or recool by chill water valve modulation or dx cooling where applicable

• Airflow control by in duct velocity sensor

• Individual supply Air Temperature sensor in VAV box where Applicable

• Filter monitoring where applicable

• AHU Supply air duct temperature

• Minimum and Maximum air volume setpoints (litres/sec0

• Air volume monitoring (litres)

• Room/Space temperature setpoint

• Occupied/Unoccupied mode

• Heating/Cooling demand

• Dampers override mode

• Dampers position

• Fire Control

• Heating and cooling actuators

• Run Time total

• Local specific VAV controllers with all relevant Analog & Digital I/Os for air flow rate, air volume dampers modulation, temperature readings, reheats and recool, incl. of room/space temperature.

• Analog Output

• Analog Input

• Digital Input

• Analog Input

• Virtual

• Virtual

• Virtual or via high Level Interface

• Virtual

• Virtual

• Virtual

• Virtual

• Virtual

• Analog Outputs to be 0-10V preferably

• Virtual

• Out of temperature range

• Filter blockage if applicable

• Feedback








Fan Coil Units

• Local FCU controllers with all necessary Fan and temperature control with electric reheat or heating coil valve modulation and chill water or Artesian cooling valve modulation

• Fan assisted where applicable

• Fan status where applicable

• Individual Supply Air Temperature sensor in FCU box for monitoring

• Filter monitoring




• Fire Control

• Heating and cooling actuators

• Run Time total

• Local specific FCU controllers with all relevant Analog & Digital I/Os for start/stop, status, air flow rate, temperature readings, modulating heating and cooling, incl. of room/space temperature.

• Digital Output

• Digital Input

• Analog Input

• Digital Input


• Virtual

• Virtual

• Virtual

• Analog Outputs to be 0-10V preferably

• Virtual


• Filter blockage

• Feedback

Heatpumps

• Refer separate document on split system

• Local Heatpump controllers with all necessary Fan, compressors, reversing valve, fresh air damper for free cooling, and temperature control with CO2 control where applicable

• Temperature setpt control by BMS via high level interface

• Supply Air Temperature sensor

• High level Modbus, or Bacnet Interface or Various I/Os to BMS for controls and monitoring

• Local specific Heatpump controllers with all relevant Analog & Digital I/Os for start/stop, status, temperature readings, staging of compressors, incl. of room/space temperature.

• High level Modbus, or Bacnet Interface or via Local BMS specific Heatpump controller.

• Analog Input


• Filter blockage

• General fault

• Feedback








monitoring

• Return Air Temperature sensor monitoring




• Fire Control

• Fresh Air CO2 Control

• Free Cooling Damper Control

• Filter monitoring

• Run Time total

• Analog Input


• Virtual

• Virtual

• Virtual

• Virtual

• Analog or Digital Output

• Digital Input

• Virtual

Cooling Towers

• Control of condensing water temperature by bypass modulating valve, modulating condenser pump vsd, and cooling tower fan VSD based on pipeline temperature sensor supply to chiller, or signal from Chiller local control panel, incl of

• Clg. Twr. Fans Start/Stop

• Clg. Twr. Fans Status

• Clg. Twr. Fans VSDs

• Clg.Twr. Basin Temperature

• Monitor condensing water flow and return temperature.

• Condenser water Flow switch

• Biocide dosing on/off control base on ORP transducer.

• Bio Pump status

• Various Analog & Digital I/Os

• Digital Outputs

• Digital Inputs

• Analog Outputs

• Analog Input

• Analog Inputs

• Digital Input

• Digital Outputs

• Digital Input

• High / low temp for condensing water.

• Low water level

• High / low ORP

• High TDS

• Excessive make up water volume.

• Excessive Drainage

• VSD Fault

• Fan fault

• Feedback








• TDS on/off control by solenoid dump valve by conductivity transducer.

• Conductivity monitoring in ppm

• Corrosion inhibitor on/off control based on recommendation from Water treatment Consultant.

• Corrosion Inhibitor Low Level

• Filter Control including

• Monitoring Make-up water

• Monitoring Excessive Drainage

• Various Temperature Setpts

• Run Time total

• Digital Outputs

• Analog Input

• Various Analog & Digital I/Os or

• Separate Local Controller

• Digital Input

• Various Analog & Digital I/Os and/or

• Separate Local Controller (eg Amiad)

• Analog Input

• Digital Input and Virtual

• Virtual

• Virtual

Artesian Cooling

Systems

• Pumps Start/stop and staging to suit cooling demand

• Pumps status via flow or differential pressure switches or current transducers

• VSD control and/or soft start

• Water Pressure Monitoring

• Shutdown system via pressure control

• Flow and return water temperature monitoring

• Water Level monitoring

• Low water level

• Flow Rate / Volume of Water Flow

• Digital Outputs

• Digital Inputs

• Digital and Analog Outputs

• Analog Input

• Digital Output

• Analog Inputs

• Analog Input

• Digital Inputs

• Analog Inputs with Local metering

• Pump fail

• Feedback

• Flow and return differential water temperature to comply with resource consent

• Pump Lock out where applicable

• System shutdown

• Low and High Water pressure








• Duty/standby and/or Lead/lag control

• Various Temperature & pressure Setpts

• Cooling Demands

• Return Water Pressure at plantrooms

• Return water modulating valve control at plantrooms by pressure setpt

• Virtual

• Virtual

• Virtual

• Analog Inputs

• Analog Outputs

Potable Water

Systems

• Pumps Start/stop and staging to pressure setpt of 560Kpa (adjustable)

• Pumps status via flow or differential pressure switches or current transducers

• VSD control and/or soft start

• VSD Faults

• Flow water pressure monitoring

• Tank Water Pressure / Water level in Tank

• Compressor Start/Stop

• Compressor Status

• Low water level

• Flow Rate / Volume of Water Flow

• Fire Sprinkler Flow switch

• Pressure Chart Recorder Activation

• Pumps and Chart Recorder Reset

• Fire Sprinkler Control (increase Pressure setpt to 660Kpa)

• Digital Outputs

• Digital Inputs

• Digital and Analog Outputs

• Digital Inputs

• Analog Input

• Analog Input

• Digital Output

• Digital Input

• Digital Inputs if applicable

• Analog Inputs with Local metering where applicable

• Analog Input

• Digital Output

• Digital Output

• Virtual

• Pump fail

• Feedback

• Flow and return differential water temperature to comply with resource consent

• VSD faults

• Pump Lock out

• Flow Water Pressure Alarm

• Tank water Pressure Alarm

• Fire Sprinkler Flow Switch operated

• Excessive pump start








• Duty/standby or Lead/lag pumps control

• Number of Pump starts

• Excessive pump start

• Run Time total

• Virtual

• Virtual

• Virtual

• Virtual

Sewage and Sump

Pumps

• Pump Controls and/or

• Pump Start

• Pump Status

• Pump failure / Overload Monitoring

• High Water level monitoring

• Comms fail if remote monitoring

• Local PLC Controls and/or

• Digital Output

• Digital Input

• Digital Input

• Digital and/or Analog Input

• Digital Input

• Pump fail

• Pump Overload

• High Level

• Feedback where applicable

• Comms fail where applicable

UPS

• Mains fail status

• Battery Status

• General fault

• Digital Input

• Digital Input

• Digital Input

• General fault

• Mains fail

Standby Generator • (Also Refer separate document)

• Maximum Demand Warning

• Maximum Demand Signal

• Generator Start/Stop

• Generator Status

• Generator Co-Gen Status

• Generator ‘Not-in-Auto’ Status

• Generator Pre-Warning

• Generator Shutdown

• Local Controller with I/Os to BMS or

• Bacnet, ModBus or similar High Level Interface

• Digital Input

• Digital Input

• Digital Output

• Digital Input

• Digital Input

• Digital Input

• Digital Input

• Digital Input

• (Refer separate document)

• Refer Appendix for Alarm Messages








• Generator Fuel Solenoid

• Generator Fuel Tank Level or

• Generator Fuel Tank High Level

• Water Pump where applicable

• Generator Rtn. Water Temperature

• Return Water Temperature Bypass valve Control

• Voltage if applicable

• Power factor if applicable

• Mains Fail

• Run Time total

• Digital Input

• Analog Input

• Digital Input

• Digital Output

• Analog Input

• Analog Output

• Analog Input

• Analog Input

• Digital Input

• Virtual

Lighting • Lighting Level Sensor

• FIDs data from FIDS I/F PC

• Lighting Circuit On/Off to Lighting PLC

• AfterHrs switch

• Outside light time scheduling on/off based on light sensor, time schedule, FIDs, and afterhrs switch.

• Digital Input

• Modbus or similar data

• Digital Outputs to Lighting PLC via Modbus

• Digital Input

• PLC Outputs

FIDS Interface • Departure and Arrivals flight schedule

monitoring to control plants and lights for different zones including

• STA, STD, ETA, ETD, ATA, ATD, Gate Number,

• Comms failure

• FIDs Error failure

• ‘FTP’ data or ‘SQL’ from FIDs server to BMS via Modbus or similar

• Comms Fail

• FIDs Error








Main switchboards

(MSB)

• Monitor amps, volts, power factor, KW, KVA, KVAr via meter with high level interface. and/or

• Mains Fail

• Main Breaker Status

• Voltage

• Current

• Power Factor

• Real Power / Demand (KW)

• Apparent Power (KVA)

• Reactive Power (KVAR)

• Metering

• High Level Bacnet, ModBus or similar Interface

• Digital Input

• Digital Input

• Analog Input

• Analog Input

• Analog Input

• Analog Input

• Analog Input

• Analog Input

• Analog Input (Network)

• Low voltage

Motor control

cabinets (MCC)

• Monitor phase failure at point of supply to cabinet

• Controlled restart of equipment following re-establishment of power supply

• Digital Input

• Digital Output

• Phase failure

Fire Alarm • Fire Fan Controls Interface with Fire

Panel (Fire Zones)

• Fire Fans Status to FFCP

• Modbus, Digital Inputs, or High Level Bacnet

• Digital Outputs

Lift System • Lift Machine Room Temperature

• Other Faults, etc

• Analog Input

• Modbus, Digital Inputs, or High Level Bacnet

• High temperature Alarm

Security System • Other Interface where required • Modbus, Digital Inputs, or High Level

Bacnet






s:\operations and infrastructure\facilities services\general\standards\bms policy & methodology.doc Page 2

9 ACTION

9.1 WORK ON THE BMS SYSTEM TYPICALLY INVOLVES THE FOLLOWING:

Specifications of Project

Operations description

Engineering

Drawings including schematics and wiring

I/O Points schedule

Acronyms with reference to the ‘Asset Numbering Protocol’

Plant / Asset acronym labels

Material Schedule followed by the Purchasing Order

Installing and Wiring Controllers and devices

Ethernet connection with IT

Programming (including trending all relevant points)

Graphics and Trending

Commissioning including Urgent Alarm testing to Pagers / Cellphones

Staff training especially on graphics and alarm handling

Fine Tuning to acceptable performance using trends / plotters to prove the result

Hard copy printouts of the I/O points and programs, including Urgent alarm messages

O & M Manual (Electronic and Hard Copy) 1 copy to Drawing Office and 1 to HVAC

Handover / Sign Off

Queries / Defects

Revisit after 1 or 3 months

9.2 I/O POINTS

9.2.1 PURPOSE

This section identifies the layout of AS1000 / APOGEE / Honeywell hardware points in the I/O

spreadsheets and the methodology used for listing and describing typical existing plant items

controlled and/or monitored by the BMS.

9.2.2 ARCHITECTURE / SYSTEM PROFILE / CONFIGURATION

(To be added at in the next draft)

9.2.3 ACRONYMS ACCORDING TO CIAL ASSET NUMBERING PROTOCOL

These acronyms shall have a maximum of 30 characters including spaces. By nature of the

varying plant to be controlled, there are no fixed protocols, but the typical I/O sheets give







good working examples to follow. These protocols must be followed closely to ensure there is

continuity and compatibility with existing acronyms. Refer to the appendix for examples.

Each completed I/O sheet must be submitted to the HVAC Controls Engineer for approval prior

to programming.

9.2.4 I/O TYPE

The hardware will be selected from the “Preferred Mechanical & Electrical materials list”; the

only exception is where the hardware has been supplied with a propriety piece of equipment.

9.2.5 ALARM

This lists the “Priority” of the alarm from a predefined list programmed into the Desigo /

APOGEE Insight / Honeywell EBI Work-Station.

9.2.6 ALARM CONDITION, PRIORITY AND DELAY

This briefly defines for which conditions the alarm will be generated.

Change of State alarms

High / Low alarms

Feedback alarms

9.2.7 ALARM DELAY

This is the time in seconds or minutes that the alarm will be delayed in generating if that point

is outside it’s normal programmed parameters. This delay will apply for control and feedback

operation.

9.2.8 ALARMS TO PAGER AND CELLPHONE

Day - BMS Alarm Pager and Duty Electrician Cellphone.

Night - BMS Alarm Pager and Duty 1st On Call Cellphone.

9.2.9 REPORTS

(To be completed at a later date)

9.2.10 ACCESS LEVEL

Assign access levels for different operators to appropriate graphics and I/O points such as

setpt adjustment, etc. documentation.

9.2.11 ETHERNET NETWORK (TCIP CONFIGURATION)

Refer appendix for example of IP address assignment.

9.2.12 GRAPHICS

Graphics shall be kept as simple as possible and user friendly for use by non-technical

operators. Refer appendix for an example of the graphics.







9.2.13 FILING

2 copies of the latest version of the programmer’s sheet are to be supplied to CIAL Facilities

Services for inclusion in documentation.







Appendix A - CIAL – IP Address for BMS

CIAL - IP Address for BMS for Siemens APOGEE and Honeywell EBI

3-May-07 NB:- Cannot accept underscore

Requested By

Others/CIAL For project Name of Device Cabling to BLN

Site / Node name

System Name Node or Host Name of device Patch # Current IP Address

New VLAN Address

Gen-I Reserved Gen-I In-House HSRP 192.168.21.1

Gen-I Reserved Gen-I In-House CoreSA1 192.168.21.2

Gen-I Reserved Gen-I In-House CoreSB1 192.168.21.3

Gen-I Reserved Gen-I In-House 192.168.21.4







Sng BMS - Colour Printer BMS - HP PSC Colour Printer Colour Printer CIAL Network 178 105BHC BMS CLR_PRT MYD7 TB3-21 202.14.167.35 -

SSL(JA)/Sng BMS - Apogee/EBI Upgrade SNG desktop Workstation CIAL Network 105 105BHCSNG_PC AUB43001ZZ TB3-2 DHCP DHCP

SSL(JA)/Sng BMS - Apogee/EBI Upgrade Apogee2 PC Workstation CIAL Network 105 105BHCAPOGEE2_PC SGH421OCWG TB3-5 DHCP or DHCP

202.14.167.68 ?

Sng BMS - Apogee Upgrade XLAN MS1800 (on Apogee2 PC) ITB HB01 NCRS 3 Port A CIAL Network 105 XLAN MS1800 XLAN MS1800 NCR3-A 192.168.0.2 -

SSL(JA)/Sng BMS - DESIGO DESIGO PC database server ITB HB01 NCRS 2 Port A DESIGO Network 105 105BHCDESIGO_PC 105BHC DESIGO PC TB3-3 202.14.167.20 -







Requested By


Site / Node name


New VLAN Address

SSL(JA)/Sng BMS - Apogee Upgrade (apogee1) Apogee1 PC database server HB01 HVAC Office Apogee1 LAN 105 105BHCAPOGEE1_PC - TB3-4 202.14.167.190 192.168.21.11

SSL.(JA)/Sng BMS - Apogee Upgrade Staefa NCRS 0 Host ITB HB01 NCRS 0 E-Port NCR 105 105BHCHB01STAEFA_NCR XLAN APOG TB1-9 202.14.167.193 192.168.21.12

Sng BMS - FIDs I/F (2good4you) BMS - FIDs I/F PC ITB HB01 CIAL Eq.Rm. CIAL Network 105 105BHCFIDSIF_PC FIDSLINK TB1-36 202.14.168.6 -

SSL(JA)/Sng BMS - Apron Expansion Apogee E.Microserver 200 ITB Pl.Rm. R4 1052HCPRR4_RBLN01 0/21 1052HCPRR4_LMEC021 Node 21 - PlRm.R4 AEM TF3-12 202.14.167.192 192.168.21.13

SSL(JA)/Sng BMS - AirNZ VIP Apogee E.LMEC ITB Pl.Rm. R4 105GHCITB_BLN 105 1052FCPRR4_ELMEC01 1052FC PRR4 ELMEC01 TF3-13 - 192.168.21.14

SSL(JA)/Sng BMS - Apron Expansion Apogee E.Microserver 200 ITB Pl.Rm. G52 105GHCPRG52_RBLN01 0/31 105GHCPRG52_LMEC031 Node 31 - PlRm. G52 AEM 51-20 202.14.167.191 192.168.21.15

SSL(JA)/Sng BMS - Apron Expansion RS485 - PRG52_MEC031 105GHCPRG52_RBLN01 0/42 105GHCPRG52_MEC042 Node 42 - PlRm. G52 AEM - - -

SSL(JA)/Sng BMS - Apron Expansion RS485 - PRG52_MEC031 105GHCPRG52_RBLN01 0/53 105GHCPRG52_MEC053 Node 53 - PlRm. G52 AEM - - -

SSL.(JA)/Sng BMS - Apogee Smart II Driver Apogee Sm II Driver (AEM 200) ITB HB01 CIAL Eq.Rm. 105BHCHB01_RBLN01 0/1 105BHCHB01_SMD01 Node 1 - Smart 2 Driver AEM TB1-10 202.14.167.167 192.168.21.16

SSL.(JA)/Sng BMS - R3F4&F5 SMVU Upgrade Apogee E.LMEC ITB Pl.Rm. R3 105GHCITB_BLN 105 1052FCPRR3_ELMEC01 1052FC PRR3 ELMEC 01 AC-186 202.14.167.194 192.168.21.17

SSL.(JA)/Sng BMS - R3F4&F5 SMVU Upgrade For BMS Laptop use ITB Pl.Rm. R3 - - - - AC-187 DHCP 192.168.21.18

SSL(JA)/Sng BMS - HBS For BMS Laptop use ITB HG04 - - - - TG4-39 DHCP 192.168.21.19

SSL(JA)/Sng BMS - HBS Apogee E.LMEC ITB HG04 105GHCITB_BLN 105 105GHCHG04HBS_ELMEC01 105GHC HG04HBS ELMEC 01 TG4-40 202.14.167.189 192.168.21.20

SSL(JA)/Sng BMS - Emirates Ramp Office Apogee E.MEC ITB HG53 ERO 105GHCITB_BLN 105 105GHCHG53ERO_EMEC01 105GHC HG53 ERO EMEC 01 TG52-20 202.14.167.196 192.168.21.21

SSL(Ja)/Sng BMS - ModBus Driver Apogee MODbus Driver ITB HB01 CIAL Eq.Rm. 105GHCITB_BLN 105 105BHCHB01_EMBDC01 105BHC HB01 MBD 01 TB1-26 202.14.167.201 192.168.21.22

SSL(Ja)/Sng BMS - Spare Spare for future ITB HB01 CIAL Eq.Rm. 105GHCITB_BLN 105 Spare Spare TB1-27 202.14.167.207 192.168.21.23

SSL(Ja)/Sng BMS - Lighting Apogee MODbus Driver 105BHCHB01_EMBDC01 105GHCITB_BLN 105 105BHCHB01_EMBDC01 FLN 1 - 105B Moeller PLC - - -

SSL(Ja)/Sng BMS - Pwr Metering Apogee MODbus Driver 105BHCHB01_EMBDC01 105GHCITB_BLN 105 105BHCHB01_EMBDC01 FLN 2 - 100 Power Meters LAN - - -

SSL(Ja)/Sng BMS - Fire Alarm Upgrade Apogee MODbus Driver 105BHCHB01_EMBDC01 105GHCITB_BLN 105 105BHCHB01_EMBDC01 FLN 3 - 105B FireFinder FFCP - - -







Requested By


Site / Node name


New VLAN Address

SSL(AM)/Sng BMS - TDP Car Park Building Generator Transfer Sw ModBus CarPark Bldg Lvl Gnd. 105GHCITB_BLN 105 105BHCHB01_EMBDC01 FLN 6 - 179 Generator8 179GT-04 202.14.167.157 192.168.21.24

SSL(Ja)/Sng BMS - ModBus Driver Apogee MODbus Driver - - - - FLN 253 - 105B Diagnostics LAN - - -

SSL(JA)/Sng BMS - Fire Alarm Upgrade PRR1 EPXC 01 ITB Pl.Rm. R1 105GHCITB_BLN 105 1052FCPRR1_EPXC01 1052FC PRR1 EPXC 01 TF5-26 202.14.167.174 192.168.21.25

SSL(JA)/Sng BMS - Fire Alarm Upgrade For Laptop use ITB Pl.Rm. R1 TF5-27 DHCP 192.168.21.26

SSL(JA)/Sng BMS - Fire Alarm Upgrade PRR2 EPXC 01 ITB Pl.Rm. R2 105GHCITB_BLN 105 1052FCPRR2_EMEC01 1052FC PRR2 EMEC 01 TF5-28 202.14.167.176 192.168.21.27

SSL(JA)/Sng BMS - Fire Alarm Upgrade For Laptop use ITB Pl.Rm. R2 - - - - TF5-29 DHCP 192.168.21.28

SSL(JA)/Sng BMS - Fire Alarm Upgrade Spare ITB Pl.Rm. R3 105GHCITB_BLN 105 Spare Spare AC-257 202.14.167.177 192.168.21.29

SSL(JA)/Sng BMS - Fire Alarm Upgrade For Laptop use ITB Pl.Rm. R3 - - - - AC-258 DHCP 192.168.21.30

SSL(JA)/Sng BMS - Fire Alarm Upgrade PRR4 EMEC 02 ITB Pl.Rm. R4 105GHCITB_BLN 105 1052FCPRR4_EMEC02 1052FC PRR4 EMEC 02 TS3-1 202.14.167.178 192.168.21.31

SSL(JA)/Sng BMS - Fire Alarm Upgrade For Laptop use ITB Pl.Rm. R4 - - - - TS3-2 DHCP 192.168.21.32

SSL(JA)/Sng BMS - Fire Alarm Upgrade PRG52 EPXC 01 ITB Pl.Rm. G52 105GHCITB_BLN 105 105GFCPRG52_EPXC01 105GFC PRG52 EPXC 01 TG51-115 202.14.167.179 192.168.21.33

SSL(JA)/Sng BMS - Fire Alarm Upgrade For Laptop use ITB Pl.Rm. G52 - - - - TG51-116 DHCP 192.168.21.34

SSL(JA)/Sng BMS - T1 AirNZ Chk/In FCUs Apogee E.MEC T1 Sw.Bd.Rm G4 105GHC T1_BLN 103 103GHCSBRG4_EMEC01 103GHC SBRG4 EMEC 01 B-69 202.14.167.195 192.168.21.35

SSL(JA)/Sng BMS - T1 AirNZ Chk/In FCUs For BMS Laptop use - - - - - B-70 DHCP 192.168.21.36

SSL(AM)/Sng BMS - TDP Car Park Building Apogee E.MEC CarPark Bldg Lvl Gnd. 179GHC CPB_BLN 179 179GHCDB0101E_EMEC01 179GHC DB0101E EMEC 01 179GT-08 202.14.167.148 192.168.21.37

SSL(AM)/Sng BMS - TDP Car Park Building DB11E EPXC 01 CarPark Bldg Lvl 1 179GHC CPB_BLN 179 1791HCDB11E_EPXC01 1791HC DB11E EPXC 01 179GT-12 202.14.167.149 192.168.21.38



SSL(AM)/Sng BMS - TDP Car Park Building MCP01 EPXC 01 CarPark Bldg Lvl 4 179GHC CPB_BLN 179 1794HCMCP01_EPXC01 1794HC MCP01 EPXC 01 1794T-15 202.14.167.154 192.168.21.41








Requested By


Site / Node name


New VLAN Address



SSL(AM)/Sng BMS - TDP Car Park Building MHI BACnet Gateway Virtual N/A - for Soft Controller 179GHC CPB_BLN 179 1794HC MHI BGW VIRTUAL 179:APOGEE1/5420 SoftC - - -

SSL(AM)/Sng BMS - TDP Car Park Building MHI PAC BACnet Gateway CarPark Bldg Lvl 4 1794HC CPB_MHI_BGW 179 BACDev_1000 NODE 1 - MHI_PAC_GATEWAY 1794T-11 202.14.167.158 192.168.21.45

BMS - Honeywell EBI

Requested By Others / CIAL

For project Name of Device Cabling to BLN Site

nameSystem Name Node or Host Name of device Patch # IP Address

New VLAN Address

HWL BMS - EBI Upgrade (imoncall) EBI PC database server EBI Master Server EBI Network 105 105BHCEBI_PC 105BHC EBI PC TB3-6 192.168.20.200 192.168.21.200

HWL BMS - EBI Upgrade BMS EBI Alarm Printer ITB Basement BMS Office CIAL Network 105 105BHC HB01 BMS EBI_PRT 105BHC HB01 BMS EBI PRT Serial to EBI server -

HWL BMS - EBI Upgrade BMS EBI AFS Alarm Printer AFS Tower CIAL Network 178 1782HC AFS BMS EBI_PRT 1782HC AFS BMS EBI PRT AFS 192.168.20.229 192.168.21.201

HWL BMS - EBI Domestic T1 Upgrade Dom.T1 BNA-2DN BNPS ITB Basement BMS Office 103GHC T1_BNA BNPS 103 103GHCT1_BNABNPS 103GHC T1 BNA BNPS TB3-22 192.168.20.201 192.168.21.202

HWL BMS - EBI Domestic T1 Upgrade BNA-A_003 (Ch 1) Dom.T1 BNA-2DN BNPS RTU 21-28 103 DELTANET Ch 1 BNA-A_003 - - - -

HWL BMS - EBI Domestic T1 Upgrade BNA-A_005 (Ch 2) Dom.T1 BNA-2DN BNPS RTU 11-14, 16-18 103 DELTANET Ch 2 BNA-A_005 - - - -

HWL BMS - EBI AVC Upgrade A.V.C. BNA-2DN BNPS 1st Flr MCC Room 1271HC AVC_BNA BNPS 127 1271HC AVC_BNABNPS 1271HC AVC BNA BNPS Hub 192.168.20.202 192.168.21.203







Requested By Others / CIAL

For project Name of Device Cabling to BLN Site

nameSystem Name Node or Host Name of device Patch # IP Address

New VLAN Address

HWL BMS - EBI AVC Upgrade BNA-B_004 (Ch 1) A.V.C. BNA-2DN BNPS RTU 41-45 103 DELTANET Ch 1 BNA-B_004 - - - -

HWL BMS - Penguin Colony Antarctic V.Centre BNA-1CS Penguin Gnd Equip.Rm 1271HC AVC_BNA 1 127 127GHC AVC PENG_BNA1 127GHC AVC PENG BNA 1 A-21 192.168.20.203 192.168.21.204

BMS APOGEE1 Server details

IP Address 202.14.167.190

Subnet mask 255.255.255.0

Gateway 202.14.167.2

DNS

Preferred DNS 202.14.167.204

Alternate DNS 202.14.167.173

DNS Suffix cial.co.nz

BMS EBI Server details

IP Address 192.168.20.200

Subnet mask 255.255.255.0

Gateway 192.168.20.1

DNS

Preferred DNS

Alternate DNS

DNS Suffix cial.co.nz





Date Issued: 10 March 2010 Index: Index: G205


Appendix B – Generators Priority Alarm Message Types

13-Jun-06

Generators Priority 1 Alarm Message Types

Generator X Condition from local controller Generator X

General Not-in-Auto CoGen OFF CoGen ON Pre-Warning Shutdown ON (Running)

OFF (Not Running)

Generator Standby (Auto Mode)

Normal Alm Message E Normal N/A Alm Message G Alm Message H N/A Normal

MSB Y Mains NonEss Fail

Alm Message A Alm Message E Normal N/A Alm Message G Alm Message H Normal Alm Message J

Max Demand Warning -Start Generators

Alm Message B Alm Message E Alm Message F Normal Alm Message G Alm Message H Normal Alm Message K

Max Demand Control Period - Start Generators

Alm Message C Alm Message E Alm Message F Normal Alm Message G Alm Message H Normal Alm Message K

B1 Keyswitch - Start Generators

Alm Message D Alm Message E Alm Message F Normal Alm Message G Alm Message H Normal Alm Message K






Local CoGen Test

N/A

Alm Message E

N/A Priority 2 Alm - Message L

Alm Message G Alm Message H Priority 2 Alm -Message M

N/A

Manual Generator Run N/A Alm Message E N/A N/A Alm Message G Alm Message H Priority 2 Alm -Message M

N/A

Alarm Message Type NB:

A MSB Y Mains NonEss Fail N/A - means it will never happen

B Max Demand Warning Started Normal - means No alm message or return to Normal

C Max Demand Control Period Started

D Generators Keyswitch Enabled Useful I/O Point Description

E Generator X Not-in-Auto Mode 1/Rsudi 160 Max Demand Warning Signal

F Generator X Started - Co-Gen Fail 1/Rsudi 161 Max Demand Control Period Signal

G Generator X Warning 1/Rsdi 154 B1 keyswitch - Start all generators

H Generator X Shutdown

I - NB:- Generators start on either of the following conditions:-

J MSB Y Mains NonEss Fail - Generator X Fail To Start 1) During a Max Demand Warning OR Control Period signal, AND






K Generator X Fail To Start between the adjustable time schedule (default 7:30 - 20:30 hrs)

Priority 2 Alm Message L Generator X on Test - Co-Gen ON 2) When B1 "All generators Start" Keyswitch operate

Priority 2 Alm Message M Generator X - Manual ON






Appendix C

CIAL - Apron Expansion Acronyms for Plants Controllers and Devices

NB:- HVAC zones HF08 and HF09 used instead of H108 and H109; Rest of zones follows new Acronym structure

Plants / Controllers / Devices First Acronyms Proposal Agreed Acronyms (30 Aug 2004) Plant and asset label

***AHU A*** 1052HM_AHUR04HF08 R04-HF08

AHU A Supply Air Fan 1052HMAHUR04HF08_SAF 1052HMAHUR04HF08_SAF R04-HF08-SAF

AHU A Space Temperature 1 1051HCAHUR4F8_RMT1 1051HMAHUR04HF08_RMT1 HF08-RMT1

AHU A Space Humidity 1051HCAHUR4F8_RMH 1051HMAHUR04HF08_RMH HF08-RMH

AHU A Diffuser 1 position 1051HCAHUR4F8_DIF1 1051HMAHUR04HF08_DIF1 HF08-DIF1

AHU A Return Air Damper 1051HCAHUR4F8_RAD 1051HMAHUR04HF08_RAD HF08-RAD

**VAV** 1051HMAHUR04HF08_VAV01 HF08-VAV01

VAV A1 Damper Position 1051HCAHUR4F8VAV01_DMP 1051HMAHUR04HF08VAV01_DMP HF08-VAV01-DMP

**FCU** 1051HMHF08_FCU01 HF08-FCU01









FCU A1 Space Temperature 105GHCF8FCU01_RMT 1051HMHF08FCU01_RMT HF08-FCU01-RMT

FCU A1 Fan 105GHCF8FCU01_SAF 1051HMHF08FCU01_SAF HF08-FCU01-SAF

FCU A Bypass Valve Cooling 105GHCF8FCUBP_CWV 1051HMHF08FCUBP_CWV ? HF08-FCUBP-CWV

FCU A Bypass Valve Heating 105GHCF8FCUBP_HWV 1051HMHF08FCUBP_HWV ? HF08-FCUBP-HWV

FCU A Diff Pressure Cooling 105GHCF8FCUBP_CDP 1051HMHF08FCUBP_CDP ? HF08-FCUBP-CDP

FCU A Diff Pressure Heating 105GHCF8FCUBP_HDP 1051HMHF08FCUBP_HDP ? HF08-FCUBP-HDP

***AHU B*** 1052HM_AHUR04HF09 R04-HF09

AHU B Supply Air Fan 1052HMAHUR04HF09_SAF R04-HF09-SAF

AHU B Space Temperature 1 1051HCAHUR4F9_RMT1 1051HMAHUR04HF09_RMT1 HF09-RMT1

AHU B Space Humidity 1051HCAHUR4F9_RMH 1051HMAHUR04HF09_RMH HF09-RMH

AHU B Return Air Damper 1051HCAHUR4F9_RAD 1051HMAHUR04HF09_RAD HF09-RAD









***AHU C*** 105GHM_AHUG52H151 G52-H151

AHU C Supply Air Fan 105GHMAHUG52H151_SAF G52-H151-SAF

AHU C Space Temperature 1 105GHCAHUG52F9_RMT1 1051HMAHUG52H151_RMT1 H151-RMT1

AHU C Space Humidity 1 105GHCAHUG52F9_RMH1 1051HMAHUG52H151_RMH1 H151-RMH1

AHU C Diffuser 1 position 105GHCAHUG52F9_DIF1 1051HMAHUG52H151_DIF1 H151-DIF1

AHU C Return Air Damper 105GHCAHUG52F9_RAD 105GHMAHUG52H151_RAD H151-RAD

**FCU** 105GHMHG51_FCU01 HG51-FCU01

FCU C1 Space Temperature 105GHCG51FCU01_RMT 105GHMHG51FCU01_RMT HG51-FCU01-RMT









FCU C1 Fan 105GHCG51FCU01_SAF 105GHMHG51FCU01_SAF HG51-FCU01-SAF

FCU C Cooling Bypass W/Valve 1051HCAHUR4FCUBP_CWV 1051HMHG51FCU_CBPWV HG51-FCU-CBP-WV

FCU C Heating Bypass W/Valve 1051HCAHUR4FCUBP_HWV 1051HMHG51FCU_HBPWV HG51-FCU-HBP-WV

FCU C Clg. Bypass Diff Pressure 1051HCAHUR4FCUBP_CDP 1051HMHG51FCU_CBPDP HG51-FCU-CBP-DP

FCU C Htg. Bypass Diff Pressure 1051HCAHUR4FCUBP_HDP 1051HMHG51FCU_HBPDP HG51-FCU-HBP-DP

***AHU D*** 105GHM_AHUG52HG52 G52-HG52

AHU D Supply Air Fan 105GHMAHUG52HG52_SAF G52-HG52-SAF

AHU D Space Temperature 1 105GHCAHUG52G52_RMT1 105GHMAHUG52HG52_RMT1 HG52-RMT1

AHU D Space Humidity 1 105GHCAHUG52G52_RMH1 105GHMAHUG52HG52_RMH1 HG52-RMH1

AHU D Diffuser 1 position 105GHCAHUG52G52_DIF1 105GHMAHUG52HG52_DIF1 HG52-DIF1

AHU D Return Air Damper 105GHCAHUG52G52_RAD 105GHMAHUG52HG52_RAD HG52-RAD









***DAIKEN UNITS***

Daiken A/C Enable 2&4 1051HCF52_HTP02,4 1051HMH152_HTP02,4 H152-HTP02,4



Daiken A/C Setpoint 2&4 1051HCF52_HTP02,4_RMTSP 1051HMH152HTP02,4_RMTSP N/A











Daiken A/C Fan Status 2&4 1051HCF52_HTP02,4_S 1051HMH152HTP02,4_FS H152-HTP02,4



Daiken A/C Space Temperature 2&4 1051HCF52_HTP02,4_RMT 1051HMH152HTP02,4_RMT H152-HTP02,4-RMT



***SPILL FANS***

SPF-C1 105RHCF51_EAF01 105RHMH151_EAF01 H151-EAF01









***SMOKE EXTRACT FANS***

SF1 105RHMFF02HF08_SEF01 FF02-HF08-SEF01

SF2 105RHMFF02HF08_SEF02 FF02-HF08-SEF02

SF3 105RHMFF02H151_SEF03 FF02-H151-SEF03



Queries

Where are the bypass valves?

Where is FCU C1 located?







Appendix D

B1 Chillers 1 & 2

Condenser Pumps

& R4 Cooling Towers

CT 1 & 2

Controls

“ B1CH* ”

( NCRS 1 / Trk 1 / RS0D )

TABLE OF CONTENTS Page

Description – ................................................................................................ 42

Rev. Description Drw. Chk. Auth Date

CIALB1 Chill 1 & 2

A d C d P

R4 Cl T CT1 & 2

E i i C t l

D t D t N

ME / HVAC /

1/1/D/B1CH

B1CHCNCT.DOC Pg 41 of 2







Description:

NCRS 1 / Trk 1 / RS0D

B1 Chillers 1 & 2 Condenser Pumps and R4 Cooling Towers CT1 & 2 Controls

The BMS receives a DI signal from each chiller requesting the respective condenser pump to

start.

The BMS also receives a 0 – 10 V signal from each chiller system. This signal indirectly

represents the cooling demand from the condenser water for that chiller.

These signals are sent from the B1 Chillers’ COP panel.

Control Strategy.

The 0 – 10 V signal from the COP panel controls the condenser pump VSD from 5 – 50 Htz.

At the same time, the 0 – 10 V signal varies the condenser return water temperature setpt

from 20 to 29 Deg.C.

The two cooling tower fan VSDs are then subsequently PI controlled by the variable Cond.

RWT setpt.

(Eg. PI Output 40 –70 % = Fan A VSD 10 – 64 Htz. and

PI Output 70 – 100 % = Fan B VSD 10 – 64 Htz. )

The controls are identical for Chillers 1 & 2 condenser system and respective cooling towers

CT1 and CT2.







Appendix E







Date post:	22-Nov-2014
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