2007 McQuay International. "McQuay" is a registered trademark of McQuay International, Information covers the McQuay International
products at the time of publication and we reserve the right to make changes in design and construction at anytime without notice.
The following are trademarks or registered trademarks of their respective companies: BACnet from ASHRAE; LONM
managed, granted and used by LONMARK International under a license granted by Echelon Corporation; McQuay and MicroTech II, Open Choices, FanTrol
from McQuay International.
2 OM AGSDP-2
ARK and LONWORKS Logo
are
This manual provides setup, operating, and troubleshooting information for the McQuay
MicroTech ΙΙ controller for Model AGSDP, air-cooled, rotary screw compressor chillers.
Please refer to the current version of IMM AGSDP (available from the local McQuay sales
office or on www.mcquay.com) for information relating to the solid state starters and to the
unit itself.
NOTE: This manual covers units with Software Version AGSU30101H. The unit’s
software version number can be viewed by pressing the MENU and ENTER keys (the two
right keys) simultaneously. Then, pressing the MENU key will return to the Menu screen.
BOOT version 3.0F
BIOS version 3.62
!
WARNING
Electric shock hazard. Can cause personal injury or equipment damage. This equipment
must be properly grounded. Connections to, and service of the MicroTech II control panel
must only be performed by personnel who are knowledgeable in the operation of the
equipment being controlled.
!
CAUTION
Static sensitive components. A static discharge while handling electronic circuit boards can
cause damage to the components. Discharge any static electrical charge by touching the
bare metal inside the control panel before performing any service work. Never unplug any
cables, circuit board terminal blocks, or power plugs while power is applied to the panel.
NOTICE
This equipment generates, uses and can radiate radio frequency energy and, if not installed and
used in accordance with this instruction manual, can cause interference to radio
communications. Operation of this equipment in a residential area is likely to cause harmful
interference in which case the user will be required to correct the interference at the user’s
expense. McQuay International Corporation disclaims any liability resulting from any
interference or for the correction thereof.
Temperature and Humidity Limitations
The MicroTech ΙΙ controller is designed to operate within an ambient temperature range of
-20°F to +149°F (-29°C to +65.1°C) with a maximum relative humidity of 95% (noncondensing).
OM AGSDP-2 3
MicroTech II Features
• Control of leaving chilled water within a ±0.2°F (±0.1°C) tolerance.
• Readout of the following temperature and pressure readings:
• Entering and leaving chilled water temperature.
• Saturated evaporator refrigerant temperature and pressure.
• Saturated condenser temperature and pressure.
• Outside air temperature.
• Suction line, liquid line, and discharge line temperatures − calculated superheat for
discharge and suction lines − calculated subcooling for liquid line.
• Automatic control of primary and standby chilled water pumps. The control will start one
of the pumps (based on lowest run-hours) when the unit is enabled to run (not necessarily
running on a call for cooling) and when the ambient temperature reaches a point of freeze
possibility.
• Two levels of security protection against unauthorized changing of setpoints and other
control parameters.
• Warning and fault diagnostics to inform operators of warning and fault conditions in plain
language. All events, alarms, and faults are time- and date-stamped, for identification of
when the fault condition occurred. In addition, the operating conditions that existed just
prior to shutdown can be recalled to aid in isolating the cause of the problem.
• Twenty-five previous alarms and related operating conditions are available.
• Remote input signals for chilled water reset, demand limiting, and unit enable.
• Manual control mode allows the service technician to command the unit to different
operating states. This function can be useful for system checkout.
• Building Automation System (BAS) communication capability via LONW
Modbus, or BACnet standard open protocols for all BAS manufacturers-simplified
with McQuay’s Open Choices feature.
• Service Test mode for troubleshooting controller hardware.
• Pressure transducers for direct reading of system pressures. Preemptive control of low
evaporator pressure conditions and high discharge temperature and pressure to take
corrective action prior to a fault trip.
• Quiet Night function that reduces the unit sound level during a selected night-time period.
ORKS
,
4 OM AGSDP-2
General Description
General Description
The Model AGS MicroTech ΙΙ distributed control system consists of multiple
microprocessor-based controllers that provide monitoring and control functions required for
the controlled, efficient operation of the chiller. The system consists of the following
components:
• Unit Controller, one per chiller − controls functions and settings that apply to the unit
and communicates with all other controllers. It is located in the control panel for circuit
#1 and is labeled “UNIT CONTROL”.
• Circuit Controller for each compressor/circuit (two or three depending on model size)
that control compressor functions and settings specific to the circuit. The controllers are
located in their circuit's control panel that is mounted between the condenser coil
sections and are labeled “CIRCUIT CONROL”.
In addition to providing all normal operating controls, the MicroTech II control system
monitors equipment protection devices on the unit and will take corrective action if the
chiller is operating outside of its normal design envelope. If an alarm condition develops,
the controller will shut the compressor down and activate an alarm output. Important
operating conditions at the time an alarm condition occurs are retained in the controller’s
memory to aid in troubleshooting and fault analysis.
The system is protected by a password scheme that allows access only by authorized
personnel. The operator must enter the operator password into the controller's keypad
before any setpoints can be altered.
Control Architecture
Figure 1, Major Control Components
BACnet MS/TP
BACnet IP
BACnet Ethernet
LonTalk
ModBus
Chiller A
RS485/LON/Ethernet
Unit
Controller
4x20 LCD
Solid
State
Starter
RS485
pLAN
( Future)
EXV
Circuit #1
Controller
4x20 LCD
Other Circuit
Controllers
( Future)
OM AGSDP-2 5
Component Description
Unit and Circuit Controller Description
Terminology and Definitions
Accumulator
The accumulator is an electronic “bank” that stores information relative to fan operation and
fan capacity required. It is the heart of the controller’s fuzzy logic feature. Various events
such as cooling load changes and ambient air temperature changes, add or subtract points in
the bank. When a certain number of points are accumulated, a fan will be started.
Active Setpoint
The active setpoint is the setting in effect at any given moment. This occurs on setpoints
that can be altered during normal operation. Resetting the chilled water leaving temperature
setpoint by one of several methods, such as return water temperature, is an example.
Condenser Saturated Temperature Target
The saturated condenser temperature target is calculated by first using the following
equation:
Sat condenser temp target raw = 0.833(evaporator sat temp) + 68.34
The “raw” value is the initial calculated value. This value is then limited to a range defined
by the Condenser Saturated Temperature Target minimum and maximum setpoints. These
setpoints simply cut off the value to a working range, and this range can be limited to a
single value if the two setpoints are set to the same value.
CPU Error
These are problems caused by a malfunction of the central processing unit.
Dead Band
The dead band is a set of values associated with a setpoint such that a change in the variable
occurring within the dead band causes no action from the controller. For example, if a
temperature setpoint is 44°F and it has a dead band of ± 2 degrees, nothing will happen until
the measured temperature is less than 42°F or more than 46°F.
Delta-T
Delta-T is a range of degrees of temperature. For example, a Start Up Delta-T of 5 degrees
means that the water temperature must be 5 degrees above the LWT setpoint before the start
signal is given.
Discharge Superheat
Discharge superheat shall be calculated for each circuit using the following equation:
Discharge Superheat = Discharge Temperature – Condenser Saturated Temperature
Error
In the context of this manual, “Error” is the difference between the actual value of a variable
and the target setting or setpoint.
Evaporator Approach
The evaporator approach is calculated for each circuit. The equation is as follows:
Evaporator Approach = LWT – Evaporator Saturated Temperature
6 OM AGSDP-2
EvapRecTimer
The evaporator recirculation timer establishes the time the chilled water pump will run after
the controller receives an enable signal and the Wait for Flow timer time out. This allows
time for the chilled water to circulate sufficiently to determine if there is a need for cooling.
EXV
Electronic expansion valve, used to control the flow of refrigerant to the evaporator,
controlled by the circuit microprocessor.
High Saturated Condenser – Hold Value
High Cond Hold Value = Max Saturated Condenser Value – 5°F
This function prevents the compressor from loading whenever the pressures approach
within 5 degrees of the maximum discharge pressure. The purpose is to keep the
compressor online during periods of possibly temporary elevated pressures.
Low Ambient Lockout
Prevents compressors from starting when ambient air temperature is below the setpoint
(55°F default). Clears when ambient rises 5-degrees above the setpoint.
Low OAT Start
Allows start attempts at low ambient temperatures.
High Saturated Condenser – Unload Value
High Cond Unload Value = Max Saturated Condenser Value – 3°F.
This function unloads the compressor whenever the pressures approach within 3 degrees of
the maximum discharge pressure. The purpose is to keep the compressor online during
periods of possibly temporary elevated pressures.
Low Pressure Hold Setpoint
The psi evaporator pressure setting at which the controller will not allow further compressor
loading.
Low/High Superheat Error
The difference between actual evaporator superheat and the superheat target.
LWT
Leaving water temperature. The “water” is any fluid used in the chiller circuit.
LWT Error
Error in the controller context is the difference between the value of a variable and the
setpoint. For example, if the LWT setpoint is 44°F and the actual temperature of the water
at a given moment is 46°F, the LWT error is +2 degrees.
LWT Slope
The LWT slope is an indication of the trend of the water temperature. It is calculated by
taking readings of the temperature every few seconds and subtracting them from the
previous value, over a rolling one minute interval.
Maximum Saturated Condenser Temperature
The maximum saturated condenser temperature allowed is calculated based on the
compressor operational envelope.
Mode
There are three possible operating modes for the unit: Some can be combined and then
selected by an external signal or from the keypad.
1. Cool, the compressors are under normal loading and staging control and the minimum
LWT setpoint is 40°F. Cool with Glycol merely reduces the minimum LWT to 30°F.
2. ICE, primarily controls the compressor at full load until the LWT setpoint is reached,
then shuts unit off.
3. Test, allows outputs to be actuated manually.
OM AGSDP-2 7
ms
Milli-second
OAT
Outside ambient air temperature
pLAN
Peco Local Area Network is the proprietary name of the network connecting the control
elements.
Refrigerant Saturated Temperature
Refrigerant saturated temperature is calculated from the pressure sensor readings for each
circuit. The pressure is fitted to an R-134a temperature/pressure curve to determine the
saturated temperature.
Slide
Slide is an abbreviation for the compressor slide valve, which determines the compressor
capacity. It is positioned by the controller such that to unload, it moves toward the main
rotor suction end and discharge gas is bypassed from the rotor discharge back to suction.
Slide Target, Slide Position
See page 14 for explanation of these terms.
SP
Setpoint
SSS
Solid state starter as used on McQuay screw compressors
Suction Superheat
Suction superheat is calculated for each circuit using the following equation:
Suction Superheat = Suction Temperature – Evaporator Saturated Temperature
Stageon/Stageup
Stage On or Stage Up is the act of starting a compressor or fan when another is still
operating. The two phrases are interchangeable and either one can be used depending on
the date of issue of the software. “Start” is the act of starting the first compressor or fan on
a unit.
Stageoff/Stagedown
Stage Off or Stage Down is the act of stopping a compressor or fan when another is still
operating. The two phrases are interchangeable and either one can be used depending on
the date of issue of the software. “Stop” is the act of stopping the last compressor or fan on
a unit.
VDC
Volts, Direct current, sometimes noted as vdc
VFD
Variable Frequency Drive, a device used to vary an electric motor’s speed.
Unit and Circuit Controller Description
Hardware Structure
The controllers are fitted with a 16-bit microprocessor for running the control program.
There are terminals for connection to the controlled devices (for example: solenoid valves,
expansion valves, chilled water pumps). The program and settings are saved permanently in
FLASH memory, preventing data loss in the event of power failure without requiring a
back-up battery. It also has optional remote communication access capability for a BAS
interface.
8 OM AGSDP-2
Each chiller has one unit controller and a circuit controller for each compressor circuit (two
ALARM
or three depending on unit size). The controllers are connected and communicate via a
pLAN (local area network). The circuit controllers communicate with, and control the
operation of, the compressor's solid state starter and the circuit electronic expansion valve
(EXV).
Keypad
A 4-line by 20-character liquid crystal display and 6-button keypad is mounted on the unit
and compressor controllers.
Figure 2, Keypad
Key-to-Screen Pathway
Red Alarm Light
MENU Key
Air Conditioning
<
VIEW
<
<
ARROW Keys (4)
SET
ENTER Key & Green Run Light
The four arrow keys (UP, DOWN, LEFT, RIGHT) have three modes of use.
1. Scroll between data screens in the direction indicated by the arrows (default mode).
2. Select a specific data screen in the menu matrix using dynamic labels on the right side
of the display such as ALARM, VIEW, etc. (this mode is entered by pressing the
MENU key). For ease of use, a pathway connects the appropriate button to its
respective label on the screen.
3.
Change field values in setpoint programming mode as follows:
LEFT key = Default RIGHT key = Cancel
UP key = Increase (+) DOWN key = Decrease (-)
These four programming functions are indicated by one-character abbreviation on the right
side of the display. This programming mode is entered by pressing the ENTER key.
OM AGSDP-2 9
Control Operation
This section on MicroTech II control is divided into four subsections:
• Circuit Controller, explains the functions of the circuit controller, see page 10.
• Unit Controller, explains the functions of the unit controller, see page 24.
• Using the Controller, explains how to navigate through the menus and how to make
entries, see page 38.
• Screen Definitions, details the menu screen content and how to use them, see page 42.
Circuit Controller
Inputs/Outputs
Table 1, Analog Inputs
# Description Signal Source Range
1 Evaporator Pressure 0.5 - 4.5 VDC (NOTE)
2 Condenser Pressure 0.5 - 4.5 VDC (NOTE)
3 Liquid Pressure 0.5 - 4.5 VDC (NOTE)
4 Suction Temperature Thermistor (10k@25°C)
5 Discharge Temperature Thermistor (10k@25°C)
6 Liquid Temperature Thermistor (10k@25°C) -58 to 212°F
7 Slide Load Indicator 4 to 20 mA
8 Open
NOTE: Value at the converter board input. Value at the converter board output is 0.1 VDC – 0.9 VDC.
0 to 132 psi
3.6 to 410 psi
3.6 to 410 psi
-58°F to 212°F
-58° to 212°F
0 to 100%
These parameters are analog inputs to the circuit controller. They are used internally as
needed and are sent to the correct pLAN addresses for use by other controllers or displays.
Table 2, Analog Outputs
# Description Output Signal Range
1 Fan 1&2 VFD 0 to 10 VDC 20 to 60 Hz
2 Open
3 EXV Driver 0 to 10 VDC 0 to 6386 steps
4 Open
These parameters are analog outputs from this controller. The values are sent to the correct
pLAN addresses for use by other controllers or displays.
Pressure Switch
6 Mech High Pressure 0 VAC (Fault) 24 VAC (No Fault)
7 Low Pressure Switch 0 VAC (Fault) 24 VAC (No Fault)
8 Open
9 Oil Level Sensor 0 VAC (Fault) 24 VAC (No Fault)
10 Open
11 Open
0 VAC (Fault) 24 VAC (No Fault)
10OM AGSDP-2
Table 4, Digital Outputs
# Description Load Output OFF Output ON Voltage
1 Compressor Starter Contact Relay Compressor off Compressor on 120
2 M1 Contactor (fan 1) Contactor Coil Fans off Fans on 120
3 M2 Contactor (fan 2) Contactor Coil Fans off Fans on 120
4 M3 Contactor (fan 3) Contactor Coil Fans off Fans on 120
5 M4 Contactor (fan 4) Contactor Coil Fans off Fans on 120
6 M5 Contactor (fan 5 & 6) Contactor Coil Fans off Fans on 120
7 Load/Unload Pulse Solenoid Hold load slide Move load slide 24
8 Load/Unload Select Relay Unload Load 24
9 M7 Contactor (fan 7 & 8) Contactor Coil Fans off Fans on 120
10 Oil Return Line Solenoid Closed Open
11 Open
12 Open
13 EXV Close Signal Contact
EXV Follows
0 – 10 VDC
EXV Closed,
Ignores 0 – 10
VDC
10
These parameters are digital outputs from this controller. Their values are sent to the correct
pLAN addresses for use by other controllers or displays.
Setpoints
The following parameters are remembered during power off, are factory set to the
Default value, and can be adjusted to any value in the Range column.
The PW (password) column indicates the password that must be active in order to
change the setpoint. Codes are as follows:
O = Operator, password is 100
M = Manager
Entering a Password
The password is located in the unit controller only and can be found at SET, UNIT SPS on
the last menu conveniently located so that you can scroll up one menu to access the
Password Enter Screen.
OM AGSDP-2 11
Table 5, Circuit Controller Setpoints
Description Default Range PW
Compressor
Circuit mode Enable Disable, Enable, Test M
Slide control Auto Auto, Manual M
Slide position 0 0-100% M
Compressor Size 205 205,220,235 M
Clear Cycle Timers N o No, Yes M
Maximum Slide Target 100.0 0-100.0% M
EXV
EXV control Auto Auto, Manual M
Manual EXV position 0 0-6386 M
Pre-open timer 60 20-120 sec M
Service Pumpdown No No, Yes M
Fans
Fan VFD enable Yes No, Yes M
Number of fans 6 6,8 M
Saturated Condenser Temp Target 110.0 90.0 – 130.0 oF M
Stage 1 Up Deadband 5.0 1.0-20.0 oF M
Stage 2 Up Deadband 8.0 1.0-20.0 oF M
Stage 3 Up Deadband 10.0 1.0-20.0 oF M
Stage 4 Up Deadband 12.0 1.0-20.0 oF M
Stage 1 Down Deadband 8.0 1.0-20.0 oF M
Stage 2 Down Deadband 7.0 1.0-20.0 oF M
Stage 3 Down Deadband 6.0 1.0-20.0 oF M
Stage 4 Down Deadband 5.0 1.0-20.0 oF M
VFD Max Speed 100% 90 to 110% M
VFD Min Speed 25% 20 to 60% M
Forced FanTrol 1
Forced FanTrol 2
Forced FanTrol 3
Sensors
Evap pressure offset 0 -10.0 to 10.0 psi M
Cond pressure offset 0 -10.0 to 10.0 psi M
Liquid pressure offset 0 -10.0 to 10.0 psi M
Suction temp offset 0 -5.0 to 5.0 deg M
Discharge temp offset 0 -5.0 to 5.0 deg M
Liquid temp offset 0 -5.0 to 5.0 deg M
Slide Minimum Position 0 -15 to 15% M
Slide Maximum Position 0 -15 to 15% M
1 1-8 M
2 1-8 M
3 1-8 M
12 OM AGSDP-2
Circuit Operating Mode
The circuits on the chiller can each be individually enable or disabled. Test mode on each
circuit can also be entered independent of the all other circuits. With the circuit switch on,
the circuit mode setpoint offers settings of either Enable or Disable. This simply allows the
circuit to be disabled through a keypad setting.
Cool Mode
When the chiller is in COOL mode, capacity of the compressor is adjusted to maintain
leaving water temperature at the Active LWT setpoint while balancing the load between
running circuits. Load balance offset, LWT error, and LWT slope are used to calculate a
change in slide position.
ICE Mode
Ice mode is designed to have the compressors run at full load until the LWT setpoint is
reached, then shut off until the next ice making cycle starts. ICE settings are made in the
unit controller.
In ICE mode, the compressor capacity is increased at the maximum rate continuously until
reaching the maximum slide position. Load balancing, LWT error, and LWT slope are
ignored. Low and high pressure events are disabled.
An adjustable Start-to-Start Ice Delay Timer will limit the frequency with which the chiller
may start in ICE mode. The timer starts when the first compressor starts while the unit is in
ICE mode. While this timer is active, the chiller cannot restart in ICE mode. The time
delay is user adjustable.
The Ice Delay Timer may be manually cleared to force a restart in ICE mode. A set point
specifically for clearing the ICE mode delay is available. In addition, cycling the power to
the controller will clear the Ice Delay Timer.
Circuit Test Mode
The circuit test mode allows manual testing of all controller outputs. Entering this mode
requires the following conditions.
• Circuit Switch = OFF
• Technician password active
• Circuit Mode setpoint = TEST
A test menu can then be selected to allow activation of the outputs. It is possible to switch
each digital output ON or OFF and set the analog outputs to any value. Upon entering the
test mode, all outputs will always default to the OFF state. Upon leaving the test mode, all
outputs will automatically reset to the OFF state.
Compressors cannot be started in TEST mode.
Slide Position
Each compressor will estimate its slide load percentage from the present value of the slide
load indicator. The percentage is based on the 4-20mA signal from the slide load indicator
and varies somewhat by compressor size. A load percentage value of 0 corresponds to mA
Low signal; a percentage value of 100 corresponds to the mA High signal shown in Table 6.
This information is located on the View Cir Status (1) menu. It shows slide position and
slide target.
Table 6, Slide Valve Position
Compressor
Size
205
220
235
NOTE: See the Physical Data tables in the current version of IMM AGSDP for unit compressor sizes.
mA Low mA High
4.94 14.6
4.62 17.0
4.32 19.4
OM AGSDP-2 13
Slide Calibration Procedure
The slide is calibrated in the factory before shipment but may have to be recalibrated in the
field, especially if relevant slide parts have been replaced.
Slide Position is a relative capacity adjustment from 0.0%(Min load) to 100.0%(Max Load).
There are two MicroTech II controller readings that apply to the indicator, Slide Target and
Slide Position. It is important to understand the difference between these. The Slide Target
is the value in which the controller uses to display the calculated prediction of slide
position. This value represents the destination or goal of pulsing the load and unload
solenoids. The slide target is used for direction of control for all load and unload operations,
including alarm limit events. When putting a circuit in Manual mode, the slide target is the
value that you will be adjusting and the controller will load or unload the chiller to match,
with in about 3%, the target entered with the current slide position value. The second value
is the Slide Position (Pos) this is the slide position value which is the 4-20mA reading
received from the position indicator. These values can be viewed at the circuit controller on
screen “VIEW CIR STATUS (1)”.
A slide target of 0.0% is fully unloaded and the unload solenoid will be constantly
energized. A slide target of 100.0% means that the chiller is at full load and the load
solenoid is continually energized. The chiller will regulate the slide position to infinite steps
between 0% and 100% by pulsing the appropriate solenoid. Facing the front of the
compressor the solenoid on the left is for load (oil vent) and the solenoid on the right is for
unload (oil feed). In Circuit Enable mode (normal operation) the controller makes decisions
to move the Slide target, the calculated value, and pulses the proper solenoid in order to
keep the actual and the target position with in a few percent.
1. It is recommended that the circuit to be calibrated is near normal operating
temperatures, although a preliminary calibration before first starting the compressor is
acceptable, as long as the value is verified soon after compressor shuts down. Note that
it requires sufficient oil pressure to unload the compressor while it is running, and may
load up due to lack of oil pressure. When the compressor is not running there is a large
spring that forces the compressor unloaded, therefore in the off state you have the best
opportunity for verifying an accurate calibration at minimum slide position.
2. On the Circuit controller first verify what your current slide target is at screen “View
Circ Status (1)” and then go to screen “SET COMP SPs (2)” to switch circuit into
manual slide control. Note: Some inhibit limits will be ignored but all alarm limits are
still active.
3. Slowly take the circuit either to 0% or 100% load. When the slide target is at either 0%
or 100%, you may want to verify that the corresponding coil is energized.
4. On the circuit controller scroll all the way to the right, then the calibration and offsets
menu. Scroll down until you see “SET SENSOR OFFSET (3)”. You will see an
adjustment for Min Load and Max Load and on the bottom line you will see the value of
the actual slide position indicator. Add offset until value is within +/-.5%.
5. Repeat until all circuits have both positions calibrated with in +/-.5%.
Note: The Slide Indicator Transducers may vary a considerable amount with temperature
change, and therefore they need to be calibrated at typical running temperatures.
14 OM AGSDP-2
Compressor Control
Multiple Compressor Staging
This section defines which compressor is the next one to start or stop. The next section
defines when the start, or stop, is to occur.
Functions
1. Can start/stop compressors according to an operator-defined sequence.
2. Can start compressors based on the least number of starts (run hours if starts are equal)
and stop on most run hours.
The above two modes can be combined so that there are two or more groups where all
compressors in the first group are started (based on number of starts/hours) before any in the
second group, etc. Conversely, all compressors in a group are stopped (based on run hours)
before any in the preceding group, etc.
Required Parameters
1. Sequence number setpoint for all compressors. Possible settings = (1-3). Compressors
will start in the specified order. Default operation sequence is 1 for all compressors
(meaning they will start based on number of starts). That is, if all are 1s, the controller
will look at number of starts and run-hours
2. Maximum Number of compressors ON setpoint. Possible settings = (1-3).
3. Number of starts for all compressors.
4. Number of run hours for all compressors.
5. Status of all compressors (Available/Unavailable, Pumping down, Running, etc.).
Multiple Compressor Start/Stop Timing
This section defines when a compressor is to start, or stop, and the scenario for doing so.
Starting
Staging up, no compressors on the unit are running:
The first compressor can start when the LWT is more than the sum of the active LWT
setpoint and the Startup Delta-T. For example, with default settings, the active setpoint
would be 44°F and the startup delta would be 10 degrees F. In this case, the LWT must be
greater than 54°F. This is a necessary, but may not be a sufficient, condition for starting the
first compressor. The Startup Delta-T is adjustable from 10 degrees down to 0 degrees F.
Staging up, at least one compressor is already running:
Additional compressors can start when the LWT is more than the sum of the active LWT
setpoint and the Stage Delta-T. With the default settings, the active setpoint is 44°F, and the
Stage Delta would be 2 degrees F. So, one necessary condition for staging an additional
compressor on is that the LWT must be higher than 46°F.
If in Cool Mode, an additional requirement is that all running compressors are running at
their maximum capacity, or at least 75% slide position and the Stage Up Delay Timer (5
minute default) has timed out. Also, a compressor is considered to be at its maximum
capacity if it is in an inhibit or unload situation due to low evaporator pressure, high
condenser pressure, or low discharge superheat. If a compressor is set for manual slide
control, or the slide target has reached the maximum allowed by the Max Slide setpoint, it
will also be flagged as being at maximum capacity.
OM AGSDP-2 15
Stopping
Staging down, at least two compressors running:
For staging off compressors, the LWT must be less than the active LWT setpoint minus the
Stage Delta-T. Based on default settings, the active setpoint would be 44°F, and stage delta
of 2 degrees F. So the LWT must be less than 42°F to stage off a compressor. This is a
sufficient condition to trigger a stage down.
For 3 compressor units, the Stage Down Delay Timer must time out before the second lag
compressor will stage down, unless LWT minus Stage Down Delta-T is exceeded, or the
LWT rises above the setpoint.
Staging down, one compressor running:
With one compressor left running, the stage off requires that the LWT be less than the active
LWT setpoint minus the Stop Delta-T. With default settings, the active setpoint is 44°F, and
the Stop Delta is 3 degrees F, so the LWT must be less than 41°F to stage off the last
compressor. This is a sufficient condition to trigger a stage down.
History Storage
The number of starts and total compressor run hours is maintained in non-volatile memory
and can be viewed on the Unit Controller or corresponding Circuit Controller.
Compressor Capacity Control
Compressor capacity is determined by calculating a slide position target. Adjustment to the
slide target for normal running conditions occurs every 10 seconds. For loading, a
maximum change of 1% is allowed, and for unloading, a maximum change of 2% is
allowed. During alarm conditions, the slide target may be reduced to satisfy alarm limits.
The change to the target is calculated as follows.
Capacity Overrides – Limits of Operation
The following conditions override the automatic slide control when the chiller is in COOL
mode or ICE mode. These overrides keep the circuit from entering a condition in which it
is not designed to run. As previously noted, any compressor that is running with capacity
limits because of these conditions will be considered to be at full load in the compressor
staging logic. An important point to realize is that a particular chiller’s components are
designed for a specific range of capacity and chilled water flow. Varied conditions such as
high water temperature or low condenser pressure can cause higher refrigerant flow than the
chiller is designed to handle, therefore the chiller control may limit unit operation to
maintain system integrity at the highest compressor load possible.
Low Evaporator Pressure
If the compressor is running and the evaporator pressure drops below the Low Evaporator
Pressure-Hold setpoint, the compressor will not be allowed to increase capacity. The slide
position target will be limited to a maximum value equal to the target at the time the hold
condition was triggered. This limit will be active until the evaporator pressure reaches the
hold setpoint plus 2-psi.
If the compressor is running above minimum load capacity and the evaporator pressure
drops below the Low Evaporator Pressure-Unload setpoint, the compressor will begin
reducing capacity. The maximum allowed slide target will be adjusted down 5% every 5
seconds until the evaporator pressure rises above the Low Evaporator Pressure-Unload
setpoint. The slide target will then be limited to the current value until the evaporator
pressure rises to the unload setpoint plus 2-psi. If the pressure drops to the Unload Setpoint,
the EXV will switch to pressure control.
16 OM AGSDP-2
High Condenser Pressure
If the compressor is running and the condenser pressure rises above the High Lift Pressure
Hold setpoint, the compressor will not be allowed to increase capacity. The slide position
target will be limited to a maximum value equal to the target at the time the hold condition
was triggered. This limit shall be active until the condenser pressure drops 10 psi below the
hold setpoint.
If the compressor is running above minimum load capacity and the condenser pressure rises
above the High Condenser Pressure Unload setpoint, the compressor will begin reducing
capacity. The maximum allowed slide target will be adjusted down 5% every 5 seconds
until the condenser pressure drops below the High Condenser Pressure-Unload setpoint.
The slide target will then be limited to the current value until the condenser pressure drops
to 10 psi below the unload setpoint.
High Leaving Water Temperature
If the LWT is above 50°F, then the Max Slide is limited to 80% to avoid overloading.
Low Discharge Superheat
If the compressor is running, and the discharge superheat is less than 22oF, the compressor
will not be allowed to increase capacity. This limit will be active until the superheat is more
than 22oF.
If the compressor is running above minimum load capacity, and the discharge superheat is
less than 20oF, then the compressor will begin reducing capacity. The slide target will be
adjusted down 2% every 5 seconds, as long as the superheat remains below 20oF.
Maximum LWT Pulldown Rate
The maximum rate at which the leaving water temperature can drop is limited by the
Maximum Rate setpoint. A slope unload factor is used to reduce the slide target if the
pulldown rate exceeds the Maximum Rate setpoint.
Slope Unload Factor: Maximum Rate + LWT slope
If the pulldown rate is too fast, the slide adjustment will be made equal to the slope unload
factor.
Unit Capacity Overrides
Unit capacity limits can be used to limit total unit capacity in COOL and COOL w/
GLYCOL modes only. Multiple limits may be active at any time, and the lowest limit is
always used in the compressor capacity control.
These limits represent a limit on the unit capacity as a whole. Therefore, an estimate of the
current unit capacity is needed. Any circuit that is off is considered to be running at 0% of
its capacity. A running circuit is assumed to be running at a minimum of 20% capacity, and
the assumed capacity will very linearly from 20% to 100% as the slide position varies from
0% to 100%. The unit capacity is calculated using the following formula:
Unit Capacity = (Cir1 Capacity + Cir2 Capacity + Cir3 Capacity) / Number of Circuits
The estimated unit capacity and the active capacity limit are sent to all circuits for use in
compressor capacity control.
The active capacity limit values can be viewed at View Unit Status (2) and consist of the
following:
Soft Load
Soft Loading is a configurable function used to ramp up the unit capacity over a given time.
The set points that control this function are:
OM AGSDP-2 17
• Soft Load – (ON/OFF)
• Begin Capacity Limit – (Unit %)
• Soft Load Ramp – (seconds)
The Soft Load Unit Limit increases linearly from the Begin Capacity Limit set-point to
100%, over the amount of time specified by the Soft Load Ramp set-point. If the option is
turned off, the soft load limit is set to 100%.
Demand Limit
The maximum unit capacity can be limited by a 4 to 20 mA signal on the Demand Limit
analog input. This function is only enabled if the Demand Limit setpoint is set to ON. The
maximum unit capacity changes linearly from 0% (at 20 mA) to the 100% (at 0 mA).
Network Limit
The maximum slide load percentage of the compressor can be limited by a value sent
through a BAS network connection and stored in the Network Limit variable. This function
will be enabled if the control source is set to BAS.
ICE Mode Start Delay
In ICE mode there is a 12 hour delay from the time the unit shuts off until it may start again.
If the chiller is in ICE mode and the delay is active, the unit state will be Off and the unit
status will indicate this condition. The time left will also be displayed. While this delay is
active, the chiller may still start in cool mode.
If needed, the ice delay can be cleared using a setting found in the unit set points menu.
Pumpdown
When a circuit reaches a condition where the compressor needs to shut down normally, a
pumpdown will be performed. The slide target will automatically go to 0 while pumping
down, and the compressor will run until the pumpdown pressure has been reached, or the
pumpdown time has been exceeded. The Pumpdown Setpoint may need to be reduced if the
unit is running in the COOL w/ GLYCOL mode.
Service Pumpdown
If the option for a service pumpdown is enabled, then on the next pumpdown the pressure
setpoint will be 15 psi. The circuit will pump down to this pressure and shut off. When the
compressor has completed the service pumpdown, the setpoint is reset to No.
Manual Slide Control Mode
The slide position on each circuit can be controlled manually. A setting on the compressor
setpoints screen in each circuit controller allows the operator to select manual slide control.
On the same screen, a slide target can be selected from 0% to 100%.
Anytime a circuit is in manual slide control, it is considered to be at full load in the staging
logic. It also will not be considered a running compressor for load balancing purposes.
None of the capacity limits outlined above will apply in manual slide control, but all stop
alarms are still applicable.
Slide Positioning
Slide Load Indicator
Each compressor will estimate its slide load percentage from the present value of the slide
load indicator. The percentage is based on the 4-20mA signal from the slide load indicator.
See Table 6 on page 13 for the mA signal corresponding to slide position.
18 OM AGSDP-2
Load/Unload Select
The load/unload selector determines which solenoid will be pulsed for a change in capacity.
When unloading is required, the load/unload select output should be off. When loading of
the compressor is required, the output should be on.
Slide Pulse
The slide pulse output moves the compressor slide in order to reach the capacity reflected
by the slide position target. The output will pulse for 200 ms every 3 seconds until the slide
position is within a 3% deadband around the target.
Condenser Fan Control
The compressor must be running in order to stage its fans on.
VFD (Standard)
Condenser pressure trim control is accomplished using a variable frequency drive (VFD) on
the first two fans that turn on. This VFD control uses a proportional integral function to
drive the saturated condenser temperature to a target value by changing the fan speed. The
target value is normally the same as the saturated condenser temperature target setpoint.
The VFD will start the fans when the saturated condenser temperature goes above the
temperature target. Once the VFD fans are on, they will not shut off until the saturated
condenser temperature is less than the minimum saturated temperature plus 5 degrees F.
Stage up Compensation
In order to create a smoother transition when another fan is staged on, the VFD compensates
by slowing down initially. This is accomplished by adding the new fan stage up deadband
to the VFD target. The higher target causes the VFD logic to decrease fan speed. Then,
every 10 seconds, 0.5oF is subtracted from the VFD target until it is equal to the saturated
condenser temperature target setpoint. This will allow the VFD to slowly bring the
saturated condenser temperature back down.
Condenser Target
This logic is only used with VFD = Yes. Most applications will benefit from using the
default values. In the software versions previous to AGSU30101F, there was only one
setting for condenser target setpoint, with a default of 110°. Beginning with AGSU30101F
software there are two setpoints used to set a minimum (Min) and a maximum (Max) range
for the saturated condenser target. This can be found on the circuit controller at Set Fan
Sps(5). This will allow for a floating condenser target based on saturated evaporator
temperature. The default values of the minimum and maximum are both set to 110°
saturated condensing temperature. This will allow for the most stable unit operation.
Adjusting the Min or Max setpoint at each circuit controller will vary the condenser target
along a line determined by two points which are, 85° saturated condenser at 20° saturated
suction and 110° saturated condenser at 50° saturated suction. Note that the chiller system
is designed for specific refrigerant flow capacities, which may be exceeded by decreasing
the condenser target. The result will be at lower ambient temperatures, the chiller may
attain the maximum unit tonnage capacities while compressor loading will be limited on
low discharge superheat.
Fan Stages with VFD Option
The VFD option must always be enabled. The first two fans are controlled by the fan VFD.
This leaves 6 stages of FanTrol available with 8 fan circuits, and 4 stages available on 6
fan circuits. Although fans 5/6 and 7/8 are controlled by one contactor each, more stages
are created by using virtual stages. See the table below:
There are four stage-up deadbands that apply to the FanTrol stages. Stages one through
three use their respective deadbands. Stage four to eight share the fourth stage-up
deadband.
When the saturated condenser temperature is above the Target + the active deadband, a
Stage Up error is accumulated.
The saturated condenser temperature must not be falling for a Stage Up accumulation to
occur.
Stage Up Error Step = Saturated Condenser Refrigerant temperature – (Target + Stage
Up Deadband)
The Stage Up Error Step is added to Stage Up Accumulator once every Stage Up Error
Delay seconds. When Stage Up Error Accumulator is greater than the Stage Up Error
Setpoint, another stage is added.
When a stage up occurs, or the saturated condenser temperature falls back within the Stage
Up deadband, the Stage Up Accumulator is reset to zero.
Forced Fan Stage At Start
Fans may be started simultaneously with the compressor based on outdoor ambient
temperature. When the compressor starts, a FanTrol stage is forced, based on the following
table.
There are four Stage Down deadbands. Stages one through three use their respective
deadbands. Stages four to eight share the fourth Stage Down deadband.
When the condenser saturated refrigerant temperature is below the Target – the active
deadband, a Stage Down error is accumulated.
Stage Down Error Step = (Target - Stage Down deadband) - Saturated Condenser
Refrigerant temperature
The Stage Down Error Step is added to Stage Down Accumulator once every Stage Down
Error Delay seconds. When the Stage Down Error Accumulator is greater than the Stage
Down Error Setpoint, another stage of condenser fans turned off.
When a stage down occurs, or the saturated temperature rises back within the Stage Down
deadband, the Stage Down Error Accumulator is reset to zero. The accumulator is also held
at zero after startup until either the outside ambient temperature is less than or equal to 75°F,
or the saturated condenser temperature is greater than the condenser target less the active
stage down deadband.
20 OM AGSDP-2
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