Evaporator Fans - Carel ir33+ small wide User Manual

ENG
Example: if there is an RTC fault, the defrost programmed by td3 is not
performed, and after the safety time dI a new defrost starts.
ON
DEF
OFF
td1
td2
Key
dI Maximum time between consecutive defrosts DEF Defrost
td1...td3 Programmed defrosts
Note:
•
if dI expires when the controller is OFF, a defrost will be performed
when next switched on;
•
to ensure regular defrosts, the interval between defrosts must be
greater than the maximum defrost duration, plus the dripping time
and post-dripping time;
•
if "dI"=0 and no timed defrosts have been set, defrosts can only be
performed at power on, from digital input, from the supervisor and
from the keypad.
Other defrost parameters
Par. Description
d3 Defrost activation delay
d4 Defrost at start-up
0/1=disabled/enabled
d5 Defrost delay at start-up (if d4=1) or from dI
dd Dripping time after defrost (fans off )
d8 High temperature alarm bypass time after
defrost (and door open)
d9 Defrost priority over compressor protectors 0/1
= yes/no
d/1 Display defrost probe 1
d/2 Display defrost probe 2
dC Time base for defrost
0 = dI in hours, dP1 and dP2 in minutes
1 = dI in minutes, dP1 and dP2 in seconds
•
d3 determines the time that must elapse, when the defrost is activated,
between the stopping of the compressor (heater defrost) or the
starting of the compressor (hot gas defrost), and the activation of the
defrost relays on the main and auxiliary evaporators;
•
d4 determines whether to activate a defrost when switching controller
on. The defrost call at start-up has priority over activation of the
compressor and the continuous cycle. Defrosting when switching
controller on may be useful in special situations.
Example: there are frequent power failures in the system. In the event of a
power failure, the instrument resets the internal clock that calculates the
interval between two defrosts, starting from zero again. If the frequency
of the power failure were, in an extreme case, greater than the defrost
frequency (e.g. a power failure every 8 hours, against a defrost every 10
hours) the controller would never perform a defrost. In a situation of this
type, it is preferable to enable defrost on start-up, above all if the defrost is
controlled by temperature (probe on the evaporator), therefore avoiding
unnecessary defrosts or at least reducing the running times. For systems
with a large number of units, if selecting defrosts at start-up, after a power
failure, all the units will start a defrost. This may cause voltage overloads.
ir33plus +0300028EN rel. 1.1 - 05.05.2017
dI
t
td3
Fig. 6.r
t Time
Def Min Max UOM
0 0 250 min
0 0 1
0 0 250 min
2 0 15
1 0 250 min
0 0 1
- - -
- - -
0 0 1
To overcome this, parameter 'd5' can be used, which adds a delay before
the defrost; the delay must obviously must be diff erent for each unit.
•
d5 represents the time that must elapse between the start-up of the
controller and the start of the defrost on start-up;
•
dd is used to force the stop of the compressor and of the evaporator
fan after a defrost so as to assist the dripping of the evaporator same.
•
d8 indicates the high temperature alarm signal bypass time after
the end of a defrost or when opening the door, if the digital input is
connected to the door switch;
•
d9 overrides the compressor protection times c1, c2, c3 at the start of
the defrost;
•
d/1 and d/2 are used respectively to display the values read by defrost
probe 1 and 2;
•
dC is used to change the unit of measure (hours or minutes) used to
count the times for parameters dI (defrost interval, hours or minutes,),
dP1 and dP2 (defrost duration).

6.10 Evaporator fans

The evaporator fans can be managed according to the temperature
measured by the defrost and control probes. The deactivation threshold
is equal to the value of parameter F1, and the hysteresis is equal to the
value of A0.
Note: during the dripping time and post-dripping time, if set, the
evaporator fans are always off
Below are the parameters involved in managing the evaporator fans, and
an example of the trend based on the diff erence between the evaporator
temperature and the value of the virtual probe (F0=1). If F0=2, activation
depends solely on the evaporator probe temperature.
Par. Description
F0 Evaporator fan management
-
0 = always on
1 = activation based on Sd-Sv (diff erence
between virtual probe and evaporator
min
temperature)
2 = activation based on Sd (evaporator
temperature)
-
F1 Fan activation temperature (only if F0 = 1
or 2)
°C/°F
A0 Alarm and fan diff erential
°C/°F
-
F0=1
F1
Tab. 6.l
F1-A0
ON
FAN
OFF
F0=2
F1
F1-A0
ON
FAN
OFF
Key
Sd Defrost probe
FAN Evaporator fans
F1 Fan activation temperature
34
Def Min Max UOM
0 0 2
5.0 -50 200 °C/°F
2.0 0.1 20
Tab. 6.m
Sd - Sv
t
t
Sd
t
t
Fig. 6.s
A0 Diff erential
t Time
Sv Virtual probe
-
°C/°F