17
Occupancy Determination
The building’s occupancy is affected by a number of different
factors. When the unit is operating with a space temperature sensor
(T--55, T--56, T--58 or T--59), occupancy affects the unit set points
and the operation of the economizer. If the unit is operating under
thermostat control, occupancy only affects the operation of the
economizer.
The factors affecting occupancy are listed below
from highest to lowest priority.
Level 1 Priority
Level 1 classification is a force/write to occupancy and can occur
three ways. Listed in order of priority: force on OCCUPIED, a
write to NVI_OCC, and a Linkage write.
The CCN point
OCCUPIED is forced via an external device such as a
ComfortID
t
controller or a service tool. When OCCUPIED is
forced to YES, the unit is considered occupied, when OCCUPIED
is forced to NO, the unit is considered unoccupied. If the 3rd party
protocol LON is writing to NVI_OCC, the control maps it to
OCCUPIED as an input. If the unit is being controlled by
Linkage, the occupancy is communicated and mapped to
OCCUPIED as an input. LON and Linkage do not force the point,
only write to it, therefore a force applied to OCCUPIED will
override them.
If OCCUPIED is not being forced or written to, proceed to the
level 2 priority.
Level 2 Priority
Remote Occupancy Switch should be configured to either
Normally Open or Normally Closed when the user would like to
control the occupancy with an external switch. This switch is
field--supplied (24v, single pole, single throw [SPST]). There are
three possible configurations for the remote occupancy switch:
1. (
Configuration
→
UNIT
→
RM.SW = 0
) No Switch
2. (
Configuration
→
UNIT
→
RM.SW = 1
) Normally Open
Switch
3. (
Configuration
→
UNIT
→
RM.SW = 2
) Normally Closed
Switch
If the switch is configured to No Switch (0), the switch input value
will be ignored and software will proceed to level 3 priority. For
each type of switch, the appropriate configuration and states are
listed in the table below.
The Remote Occupancy Switch
(
INPUTS
→
GEN.I
→
RM.OC
) point will show the status of the
switch.
TYPE OF SWITCH
SWITCH
CONFIGURATION
STATE OF SWITCH
AND STATE OF
OCCUPANCY
Occupied when Closed
or Unoccupied when
Open
Normal Open (1)
Open and Unoccupied
Closed and Occupied
Occupied when Open or
Unoccupied when
Closed
Normal Closed (2)
Open and Occupied
Closed and Unoccupied
NOTE
: To perform remote occupancy, an Economizer Control
Board must be installed in the unit.
Level 3 Priority
The following occupancy options are determined by the state of
Occupancy Schedule Number (
Configuration
→
CCN
→
SCH.O
→
SCH.N
) and the Global Schedule Broadcast (
Configuration
→
CCN
→
BROD
→
B.GS
).
1. (
Configuration
→
CCN
→
SCH.O
→
SCH.N = 0
)
The unit is always considered occupied and the
programmed schedule is ignored.
This is the factory
default.
2. (
Configuration
→
CCN
→
SCH.O
→
SCH.N = 1- 64
)
Follow the local programmed schedule. Schedules 1 to 64
are local within the controller. The unit can only store one
local schedule and therefore changing this number only
changes the title of the schedule table.
3. (
Configuration
→
CCN
→
SCH.O
→
SCH.N
=
65- 99
)
Follow the global programmed schedule. If the unit is
configured
as
a
Global
Schedule
Broadcaster
(
Configuration
→
CCN
→
BROD
→
B.GS = YES
), the unit
will follow the unit’s programmed schedule and broadcast
the schedule so that other devices programmed to follow
this schedule number can receive the schedule. If the unit is
not programmed as a Global Schedule Broadcaster
(
Configuration
→
CCN
→
BROD
→
B.GS = NO
), the unit
will receive broadcasted schedules from a unit programmed
to broadcast this schedule number.
While using the
programmed schedule, occupancy can be temporarily
switched from unoccupied to occupied by pressing the
override button for approximately 3 seconds on the T--55,
T--56, T--58 or T--59 space temperature sensor. Override
will only occur if SPT Override Enabled (
Configuration
→
CCN
→
SCH.O
→
OV.SP
) is set to YES. The length of the
override period when pressing the override button is
determined by the Override Time Limit (
Configuration
→
CCN
→
SCH.O
→
OV.TL
).
The hours remaining in
override is displayed
as Timed
Override Hours
(
Configuration
→
CCN
→
SCH.O
→
OV.EX
). This point can
also be changed from the local display or network to set or
change the override period length.
Indoor Fan Operation
The indoor fan is controlled by the Indoor Fan Relay (
Outputs
→
FANS
→
IDF
) on the MBB (main base board) control, which
then operates the indoor fan contactor (IFC). For gas heating units,
the IGC control fan output is also monitored by the MBB control.
This can result in additional modification of fan delays or other
operation due to safety functions of the IGC control.
The
Humidi--MiZer
t
gas heating units do not monitor the IGC fan
output; instead an indoor fan on relay (IFOR) is used to allow the
IGC to turn the fan on. If configured for IAQ fan operation, the
fan may be turned on to satisfy air quality demands. See the
Indoor Air Quality section if using IAQ (indoor air quality)
accessory sensors. The fan can only be turned on under thermostat
or space sensor control if the System Mode (SYS) status is enabled.
The fan will remain on if compressors or heat relays are ever stuck
on. If configured for fan status switch (FN.SW) and Shut Down
on IDF Failure (
Configuration
→
UNIT
→
IDF.F = Yes
) is enabled,
the fan and unit will be shutdown on alarm. See the Adaptive Fan
section for information on its operation.
Thermostat Control
In thermostat mode, the IDF relay will be on in the following
situations: fan request G in ON, cooling request Y1 or Y2 is ON,
or heating request W1 or W2 is ON. If G is dropped or never on
with an Y1, Y2, W1, or W2 call, the IDF relay will turn off after a
configurable time delay with respect to the HVAC mode that is
ending. The Fan--off Delay delays are as follows: Mech Cool
(
Configuration
→
COOL
→
FOD.C
), Elect Heat (
Configuration
→
HEAT
→
FOD.E
), and Gas Heat (
Configuration
→
HEAT
→
FOD.G
).
Space Sensor Control
In Space Sensor mode, the IDF relay will be on if the unit is in
Occupied mode and the indoor fan is configured to always run
while occupied (
Configuration
→
UNIT
→
OC.FN = YES
). If the
indoor fan is configured for intermittent fan (
Configuration
→
UNIT
→
OC.FN = No
), the fan will only be on when there is a
cooling, heating, dehumidification, or air quality demand. During
the unoccupied period, the fan will operate intermittent. With
intermittent fan, the IDF relay will turn off after a configurable time
delay with respect to the HVAC mode that is ending. The Fan--off
Delay delays are as follows: Mech Cool (
Configuration
→
COOL
→
FOD.C
), Elect Heat (
Configuration
→
HEAT
→
FOD.E
), and
Gas Heat (
Configuration
→
HEAT
→
FOD.G
).
48/
50P
G
and
P
M
Summary of Contents for 48/50PG Series
Page 32: ...32 C07009 Fig 20 Air Baffle Dimensions 48 50PG03 16 48 50PG and PM...
Page 33: ...33 C08077 Fig 21 Air Baffle Dimensions 48 50PG20 28 and 48 50PM16 28 48 50PG and PM...
Page 58: ...58 C08549 Fig 28 48PG03 16 Control Wiring Schematic 48 50PG and PM...
Page 59: ...59 C08550 Fig 29 50PG03 16 Control Wiring Schematic 48 50PG and PM...
Page 64: ...64 C08471 Fig 34 Typical 48PG and PM16 28 Control Schematic 48PM16 28 Shown 48 50PG and PM...
Page 66: ...66 C08557 Fig 36 Typical 50PG and PM16 28 Control Schematic 50PG20 28 Shown 48 50PG and PM...
Page 68: ...68 C08558 Fig 38 Typical 48 50PG and PM16 28 Power Schematic 48 50PM16 28 Shown 48 50PG and PM...
Page 72: ...72 C08565 Fig 42 Typical 48 50PG20 28 Component Arrangement 48 50PG20 24 Shown 48 50PG and PM...
Page 73: ...73 C08067 Fig 43 48 50PM16 28 Component Arrangement 48 50PG and PM...
Page 74: ...74 C08562 Fig 44 48 50PM16 28 with Humidi MiZert Component Arrangement 48 50PG and PM...
Page 208: ...208 48 50PG and PM...
