41
Table 23 — Operating Modes
MODE
NO.
ITEM EXPANSION
DESCRIPTION
01
FSM CONTROLLING CHILLER
Flotronic™ System Manager (FSM) is controlling the chiller.
02
WSM CONTROLLING CHILLER
Water System Manager (WSM) is controlling the chiller.
03
MASTER/SLAVE CONTROL
Dual Chiller control is enabled.
05
RAMP LOAD LIMITED
Ramp load (pull-down) limiting in effect. In this mode, the rate at which leaving fluid temperature
is dropped is limited to a predetermined value to prevent compressor overloading. See Cooling
Ramp Loading (CRMP) [Configuration, SLCT]. The pull-down limit can be modified, if desired,
to any rate from 0.2° F to 2° F (0.1° to 1° C)/minute.
06
TIMED OVERRIDE IN EFFECT
Timed override is in effect. This is a 1 to 4 hour temporary override of the programmed
schedule, forcing unit to Occupied mode. Override can be implemented with unit under
Local (Enable) or
S
CN (
Sterlco
Comfort Network) control. Override expires after each use.
07
LOW COOLER SUCTION TEMPA
Circuit A cooler Freeze Protection mode. At least one compressor must be on, and the Sat-
urated Suction Temperature is not increasing greater than 1.1° F (0.6° C) in 10 seconds. If
the saturated suction temperature is less than the Brine Freeze Point (BR.FZ) [Set Point,
FRZ] minus 3° F (1.7° C) and less than the leaving fluid temperature minus 14° F (7.8° C)
for 2 minutes, a stage of capacity will be removed from the circuit. Or, If the saturated suc-
tion temperature is less than the Brine Freeze Point (BR.FZ) [Set Point, FRZ] minus 14° F
(7.8 º C), for 90 seconds, a stage of capacity will be removed from the circuit. The control
will continue to decrease capacity as long as either condition exists.
08
LOW COOLER SUCTION TEMPB
Circuit B cooler Freeze Protection mode. At least one compressor must be on, and the Sat-
urated Suction Temperature is not increasing greater than 1.1° F (0.6° C) in 10 seconds. If
the saturated suction temperature is less than the Brine Freeze Point (BR.FZ) [Set Point,
FRZ] minus 3° F (1.7° C) and less than the leaving fluid temperature minus 14° F (7.8° C)
for 2 minutes, a stage of capacity will be removed from the circuit. Or, If the saturated suc-
tion temperature is less than the Brine Freeze Point (BR.FZ) [Set Point, FRZ] minus 14° F
(7.8° C), for 90 seconds, a stage of capacity will be removed from the circuit. The control will
continue to decrease capacity as long as either condition exists.
09
SLOW CHANGE OVERRIDE
Slow change override is in effect. The leaving fluid temperature is close to and moving
towards the control point.
10
MINIMUM OFF TIME ACTIVE
Chiller is being held off by Minutes Off Time (DELY) [Configuration, OPT2].
13
DUAL SETPOINT
Dual Set Point mode is in effect. Chiller controls to Cooling Set Point 1 (CSP.1) [Set Point,
COOL] during occupied periods and Cooling Set Point 2 (CSP.2) [Set Point, COOL] during
unoccupied periods.
14
TEMPERATURE RESET
Temperature reset is in effect. In this mode, chiller is using temperature reset to adjust leav-
ing fluid set point upward and is currently controlling to the modified set point. The set point
can be modified based on return fluid, outdoor-air-temperature, space temperature, or 4 to
20 mA signal.
15
DEMAND/SOUND LIMITED
Demand limit is in effect. This indicates that the capacity of the chiller is being limited by
demand limit control option. Because of this limitation, the chiller may not be able to pro-
duce the desired leaving fluid temperature. Demand limit can be controlled by switch inputs
or a 4 to 20 mA signal.
16
COOLER FREEZE PROTECTION
Cooler fluid temperatures are approaching the Freeze point (see Alarms and Alerts section
for definition). The chiller will be shut down when either fluid temperature falls below the
Freeze point.
17
LOW TEMPERATURE COOLING
Chiller is in Cooling mode and the rate of change of the leaving fluid is negative and
decreasing faster than -0.5° F per minute. Error between leaving fluid and control point
exceeds fixed amount. Control will automatically unload the chiller if necessary.
18
HIGH TEMPERATURE COOLING
Chiller is in Cooling mode and the rate of change of the leaving fluid is positive and increasing.
Error between leaving fluid and control point exceeds fixed amount. Control will automatically
load the chiller if necessary to better match the increasing load.
19
MAKING ICE
Chiller is in an unoccupied mode and is using Cooling Set Point 3 (CSP.3) [Set Point, COOL]
to make ice. The ice done input to the Energy Management Module (EMM) is open.
20
STORING ICE
Chiller is in an unoccupied mode and is controlling to Cooling Set Point 2 (CSP.2) [Set Point
COOL]. The ice done input to the Energy Management Module (EMM) is closed.
21
HIGH SCT CIRCUIT A
Chiller is in a Cooling mode and the Saturated Condensing Temperature (SCT) is greater than
the calculated maximum limit. No additional stages of capacity will be added. Chiller capacity
may be reduced if SCT continues to rise to avoid high-pressure switch trips by reducing con-
densing temperature.
22
HIGH SCT CIRCUIT B
Chiller is in a Cooling mode and the Saturated Condensing Temperature (SCT) is greater than
the calculated maximum limit. No additional stages of capacity will be added. Chiller capacity
may be reduced if SCT continues to rise to avoid high-pressure switch trips by reducing con-
densing temperature.
23
MINIMUM COMP ON TIME
Cooling load may be satisfied, however control continues to operate compressor to ensure
proper oil return. May be an indication of oversized application, low fluid flow rate or low loop
volume.
24
PUMP OFF DELAY TIME
Cooling load is satisfied, however cooler pump continues to run for the number of minutes set
by the configuration variable Cooler Pump Shutdown Delay (PM.DY) [Configuration, OPT1].
25
LOW SOUND MODE
Chiller operates at higher condensing temperature and/or reduced
capacity to minimize overall unit noise during evening/night hours (user-configurable).
26
SHORT LOOP OVERRIDE
Chiller is monitoring how fast compressor(s) is being cycled to maintain the desired leaving
fluid temperature. Control is limiting the rate of compressor cycling when this mode is active
to ensure proper oil return and also to prevent premature compressor failure. Low loop vol-
ume, low cooler flow and/or low chiller load are the primary causes for this mode.
Содержание AquaSnap 30RA010
Страница 6: ...6 Fig 1 Typical Control Box for 30RA010 030 022 030 Shown ...
Страница 7: ...7 Fig 2 Typical Control Box for 30RA032 055 042 055 Shown ...
Страница 8: ...8 Fig 3 Wiring Schematic 30RA010 018 30RA010 018 AQUA SNAP ...
Страница 10: ...10 Fig 4 Wiring Schematic 30RA022 030 30RA022 030 AQUA SNAP ...
Страница 11: ...11 Fig 4 Wiring Schematic 30RA022 030 cont AQUA SNAP LOW VOLTAGE CONTROL SCHEMATIC 022 030 ...
Страница 12: ...12 Fig 5 Wiring Schematic 30RA032 040 30RA032 040 AQUA SNAP ...
Страница 13: ...13 Fig 5 Wiring Schematic 30RA032 040 cont AQUA SNAP LOW VOLTAGE CONTROL SCHEMATIC 032 040 ...
Страница 14: ...14 Fig 6 Wiring Schematic 30RA042 055 30RA042 055 AQUA SNAP ...
Страница 15: ...15 Fig 6 Wiring Schematic 30RA042 055 cont AQUA SNAP LOW VOLTAGE CONTROL SCHEMATIC 042 055 ...
