Emerson Dixell XM670K Wiring diagram
1592023130 XM670K_XM679K GB r4.2 26.06.2017.docx XM670K - XM679K 1/10
CONTROLLERS FOR MULTIPLEXED CABINETS
XM670K- XM679K
-MANUAL FOR THE SW REL. 4.2-
1. GENERAL WARNING
1.1 PLEASE READ BEFORE USING THIS MANUAL
This manual is part of the product and should be kept near the instrument for easy and quick
reference.
The instrument shall not be used for purposes different from those described hereunder. It cannot
be used as a safety device.
Check the application limits before proceeding.
Dixell Srl reserves the right to change the composition of its products, even without notice, ensuring
the same and unchanged functionality.
1.2 SAFETY PRECAUTIONS
Check the supply voltage is correct before connecting the instrument.
Do not expose to water or moisture: use the controller only within the operating limits avoiding
sudden temperature changes with high atmospheric humidity to prevent formation of condensation
Warning: disconnect all electrical connections before any kind of maintenance.
Fit the probe where it is not accessible by the End User. The instrument must not be opened.
In case of failure or faulty operation send the instrument back to the distributor or to “Dixell S.r.l.”
(see address) with a detailed description of the fault.
Consider the maximum current which can be applied to each relay (see Technical Data).
Ensure that the wires for probes, loads and the power supply are separated and far enough from
each other, without crossing or intertwining.
In case of applications in industrial environments, the use of mains filters (our mod. FT1) in parallel
with inductive loads could be useful.
2. BEFORE PROCEEDING
2.1 CHECK THE SW REL. OF THE XM679K
1. Look at the SW rel. of XM679K printed on the label of the controller.
2. If the SW release is 4.2 proceed with this manual otherwise contact Dixell to get the right manual.
3. GENERAL DESCRIPTION
The XM670K/XM679K are high level microprocessor based controllers for multiplexed cabinets suitable
for applications on medium or low temperature. It can be inserted in a LAN of up to 8 different sections
which can operate, depending on the programming, as stand alone controllers or following the commands
coming from the other sections. The XM670K/XM679K are provided with 6 relay outputs to control the
solenoid valve, defrost - which can be either electrical or hot gas - the evaporator fans, the lights, an
auxiliary output and an alarm output and with one output to drive pulsed electronic expansion valves
(only XM679K). The devices are also provided with four probe inputs, one for temperature control, one
to control the defrost end temperature of the evaporator, the third for the display and the fourth can be
used for application with virtual probe or for inlet/outlet air temperature measurement. The model XM679K
is provided by other two probes that have to be used for superheat measurement and regulation. Finally,
the XM670K/XM679K are equipped with the three digital inputs (free contact) fully configurable by
parameters.
The instruments are equipped with the HOTKEY connector that permits to be programmed in a simple
way. Direct serial output RS485 ModBUS-RTU compatible permits a simple XWEB interfacing. RTC are
available as options. The HOTKEY connector can be used to connect X-REP display (Depending on the
model).
4. INSTALLATION AND MOUNTING
This device can operate without any user interface, but normal application is with Dixell CX660 keyboard.
Figure 1a
Figure 1b
The CX660 keyboard shall be
mounted on vertical panel, in a 29x71
mm hole, and fixed using the special
bracket supplied as shown in fig. 1a/1b.
The temperature range allowed for
correct operation is 0 to 60°C. Avoid
places subject to strong vibrations,
corrosive gases, excessive dirt or
humidity.
The same recommendations apply to
probes. Let air circulate by the cooling
holes.
Figure 1c
5. WIRING DIAGRAM AND CONNECTIONS
5.1 IMPORTANT NOTE
XM device is provided with disconnectable terminal block to connect cables with a cross section up to 1.6 mm2 for
all the low voltage connection: the RS485, the LAN, the probes, the digital inputs and the keyboard. Other inputs,
power supply and relay connections are provided with screw terminal block or fast-on connection (5.0 mm). Heat-
resistant cables have to be used.
Before connecting cables make sure the power supply complies with the instrument’s requirements. Separate the
probe cables from the power supply cables, from the outputs and the power connections. Do not exceed the
maximum current allowed on each relay, in case of heavier loads use a suitable external relay. N.B. Maximum
current allowed for all the loads is 16A. The probes shall be mounted with the bulb upwards to prevent damages
due to casual liquid infiltration. It is recommended to place the thermostat probe away from air streams to correctly
measure the average room temperature. Place the defrost termination probe among the evaporator fins in the
coldest place, where most ice is formed, far from heaters or from the warmest place during defrost, to prevent
premature defrost termination.
5.2 XM670K –ALL POWER SUPPLY
5.3 XM679K –230VAC VALVES
5.4 XM679K –24VAC VALVES
NOTE: the jumper indicated as JMP is inside the case of the controller. This jumper
has to be closed only in case of driving 24Vac valve.
5.5 KEYBOARD DISPLAY CX660
The XM670/679K board can operate also without keyboard.
Polarity:
Terminal [34] [-]
Terminal [35] [+]
Use twisted shielded cable
AWG 18 or less in case of long
distance.
Max distance: 30m
5.6 SYNCHRONIZED DEFROST –MAXIMUM 8 SECTIONS
Follow next steps to create a LAN connection, which is a necessary condition to perform synchronized defrost
(also called master-slave functioning):
1) connect a shielded cable between terminals [38] [-] and [39] [+] for a maximum of 8 sections;
2) the Adr parameter is the number to identify each electronic board. Address duplication is not permitted,
in this case the synchronized defrost and the communication with monitoring system is not guaranteed (the
Adr is also the ModBUS address). For example, a correct configuration is the following:
If the LAN is well connected, the green LED will be ON. If the green LED blinks then the connection is
wrongly configured.
The max distance allowed is 30m
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5.7 SENSORS FOR SUPERHEAT CONTROL –ONLY FOR XM679K
Temperature probe: Pb6 terminals [19] - [20] without any polarity.
Select the kind of sensor with P6C parameter.
Pressure transducer: Pb5 terminals:
[21] = input of the signal; [22] = Power Supply for 4to20mA transducer;
[20] = GND; [23] = +5Vdc power supply for ratiometric pressure
transducer.
Select the configuration of the transducer with parameter P5C.
5.8 HOW TO USE ONLY ONE PRESSURE TRANSDUCER ON MULTIPLEXED APPLICATIONS
A working LAN connection is required (green LED lit on all XM670-XM679K boards of the same LAN). Connect
and configure a pressure transducer only on one XM670-XM679K of the network. Afterwards, the value of
pressure read by the unique transducer connected will be available to each device connected to the same LAN.
By pressing UP ARROW button, the user will be able to enter a fast selection menu and to read the value of the
following parameters:
dPP = measured pressure (only on master device);
dP5 = value of temperature obtained from pressuretemperature conversion;
rPP = pressure value read from remote location (only for slave devices).
Examples of error messages:
dPP = Err the local transducer read a wrong value, the pressure is out of the bounds of the pressure
transducer or the P5C parameter is wrong. Check all these options and eventually change the transducer;
rPF the remote pressure transducer is on error situation. Check the status of the onboard GREEN LED: if
this LED is OFF the LAN is not working, otherwise check the remote transducer.
LAST CHECKS ABOUT SUPERHEAT
On the fast access menu:
dPP is the value read by the pressure gauge;
dP6 is the value read by the temperature probe, temperature of the gas on the outlet section of the evaporator;
SH is the value of the superheat. The nA or Err messages mean that the superheat has no sense in that
moment and its value is not available.
5.9 HOW TO CONNECT MONITORING SYSTEM
1) Terminals [36] [-] and [37] [+].
2) Use shielded twisted cable. For example Belden®
8762 o 8772 or cat 5 cables.
3) Maximum distance 1Km.
4) Don’t connect the shield to the earth or to GND
terminals of the device, avoid accidental contacts by
using insulating tape.
Only one device for each LAN has to be connected to the RS485 connection.
The Adr parameter is the number to identify each electronic board. Address duplication is not permitted, in
this case the synchronized defrost and the communication with monitoring system is not guaranteed (the Adr is
also the ModBUS address).
5.10 DIGITAL INPUTS
1) The terminals from [30] to [33] are all free of voltage;
2) Use shielded cable for distance higher than one
meter;
For each input, has to be configured: the polarity of
activation, the function of the input and the delay of
signaling.
The parameters to perform this configuration are i1P, i1F, i1d respectively for polarity, functioning and delay. The
i1P can be: cL = active when closed; oP = active when opened. The i1F parameter can be: EAL = external alarm,
bAL = serious lock alarm, PAL = pressure switch alarm, dor = door switch, dEF = external defrost, AUS = auxiliary
activation command, LiG = light activation, OnF = board On/OFF, FHU = don’t use this configuration, ES =
day/night, HdY = don’t use this configuration. Then there is i1d parameter for delay of activation. For the others
digital inputs there are a set of the same parameters: i2P, i2F, i2d, i3P, i3F, i3d.
5.11 ANALOG OUTPUT
Selectable between 4 to 20mA and
0 to 10Vdc.
Use CABCJ15 to perform the connections
It’s located near the terminal [39] on a 2-pin connector. It’s possible to use the output to control anti-sweat heaters
through a chopped phase controller XRPW500 (500watt) or family XV...D or XV...K.
6. QUICK REFERENCE GUIDE: HOW TO RUN THE SELF ADAPTIVE
REGULATION IN 4 STEPS.
1. After wiring the XM679K, set the proper gas via Fty parameter. Pre-set gas is R404A.
2. Configure the probes:
- Regulation and evaporator probe are preset as NTC. If another kind of sensors is used, set it via
P1c and P2c parameters.
- Superheat evaporator outlet probe is pre-set as Pt1000, if another kind of sensor is used, set it
via P6c parameter.
- The PP11 (-0.5÷11bar) is pre-set as pressure probe. It operates at relative pressure (Pru = rE).
If you’re using a ratiometric transducer, set P5c = 0-5, then use parameters PA4 and P20 to set
the range
NOTE: check the pressure gauge reading with the value of dPP, press the UP arrow once to enter
the Fast Access Menu. If ok, proceed; otherwise solve the situation before proceeding acting on
par. Pru, PA4 and P20.
3. Set the parameters for self adaptive regulation of superheat
NOTE: the parameters Pb (regulation band) and Int (integral time) are automatically calculated by the
controller
- Set CrE = no, this disable the continuos regulation of the temperature. Default is CrE = no.
- Set SSH, superheating setpoint: a value between 4 and 8 is acceptable. Default is SSH=8
- Set AMS = y to start the self adaptive regulation. Default is AMS = y
- Set ATU = y to start the search of the lowest stable superheat. Default is ATU = y. This function
reduces automatically the setpoint in order to optimize the use of the evaporator, keeping, at the
same time, the superheating regulation stable. The minimum allowed SH set point is LSH+2°C.
- Set LSH, low superheating limit: a value between 2-4 is acceptable. Default is LSH = 3
- Set SUb, pressure filter: Default is SUb = 10. The value can be increased up to 20 in case of too
fast response of the pressure variations.
4. Set the parameters for the temperature regulation
- Set the temperature setpoint. Default is -5°C
- Set the differential HY: Default is 2°C.
- If the capacity of the valve is higher than requested, it can be reduced by the par. MNF (Default
is 100). A proper setting of MnF will reduce the time that the algorithm takes to reach the stability.
MNF value doesn’t affect the band witdh
7. USER INTERFACE
7.1 ICONS
Cooling output
↓
With icon ON the output is
active, while with blinking icon
there is a delay.
MEASUREMENT UNIT
°C, Bar and (time) are
ON depending on the
selection.
Light →
←Fan
Defrost →
AUX
←Auxiliary relay
Energy saving →
←Multimaster Enabled
Generic alarm →
←Clock / time
DURING PROGRAMMING: blink the measurement units of temperature and pressure
7.2 KEYBOARD COMMANDS
Single commands:
LIGHT relay
Press light button.
AUX relay
Press down arrow.
Manual defrost
Press and hold for 3 sec the defrost button
ON/OFF
Press for 3 sec the ON/OFF button (if the function is enabled).
Energy Saving
Press for 3 sec the ON/OFF button (if the function is enabled).
Double commands:
Press and hold for about 3 sec to lock (Pon) or unlock (PoF) the keyboard.
Pressed together to exit from programming mode or from menu; on submenus rtC and EEV
this combination allow to come back to previous level.
Pressed together for 3 sec allow to access to first level of programming mode.
7.3 HOW TO MODIFY THE SET POINT FOR AIR TEMPERATURE REGULATION
The thermostat set point is the value that will be used to regulate the air temperature. The regulation output is
controlled by the electronic valve or by the relay.
BEGIN
Press SET button for 3 sec, the measurement units will blink together.
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Value
modification
or
With the arrows it’s possible to change the value within the LS and US
parameters value.
EXIT
By pressing SET it is possible to confirm the value that will blink for
about 2 sec.
In any case, it is possible to wait for about 10 sec to exit. In order to show the air temperature set is sufficient to
press and release the SET button, the value is displayed for about 60 sec.KEY COMBINATIONS
8. HOW TO PROGRAM THE PARAMETERS (PR1 AND PR2)
The device provide 2 programming levels: Pr1 with direct access and Pr2 protected with a password (intended
for experts).
ACCESS to
Pr1
Press and hold for about 3 sec to have access to the first
programming level (Pr1).
Select item
or
Select the parameter or submenu using the arrows.
Show value
Press SET button.
Modify
or
Use the arrows to modify the value.
Confirm and
store
Press SET key: the value will blink for 3 sec, and then the display
will show the next parameter.
EXIT
Instantaneous exit from the programming mode, otherwise wait for
about 10 sec (without press any button).
8.1 HOW TO HAVE ACCESS TO “PR2”
To enter Pr2 programming menu:
1. Access to a Pr1 menu by pressing both SET+DOWN keys for 3 sec, the first parameter label will be
showed;
2. Press DOWN key till the Pr2 label will be showed, then press SET;
3. The blinking PAS label will be showed, wait some seconds;
4. Will be showed “0 - -” with blinking 0: insert the password [321] using the keys UP and DOWN and
confirming with SET key.
GENERAL STRUCTURE: The first two item rtC and EEV are related to submenus with others parameters.
SET+UP keys on rtC or EEV submenus allow coming back to parameter list,
SET+UP keys on parameter list allow immediate exit.
8.2 HOW TO MOVE PARAMETER FROM PR1 TO PR2 AND VICE VERSA
Enter on Pr2; select the parameter; press together [SET + DOWN]; a left side LED ON gives to the parameter the
presence on Pr1 level, a left side LED OFF means that the parameter is not present on Pr1 (only Pr2).
9. FAST ACCESS MENU
This menu contains the list of probes and some values that are automatically evacuate by the board such as the
superheat and the percentage of valve opening. The values: nP or noP stands for probe not present or value not
evacuate, Err value out of range, probe damaged not connected or incorrectly configured.
Entering fast
access menu
By press and release the UP arrow. The duration of the menu in
case of inactivity is about 3 min.
The values that will be showed depend on the configuration of the
board.
Use
or
arrows to
select an
entry,
then press
to see the
value or to
go on with
other value.
HM Access to clock menu or reset of the RTC alarm;
An Value of analog output;
SH Value of superheat. nA = not Available;
oPP Percentage of valve opening.
dP1 (Pb1) Value read by probe 1.
dP2 (Pb2) Value read by probe 2.
dP3 (Pb3) Value read by probe 3.
dp4 (Pb4) Value read by probe 4.
dP5 (Pb5) Temperature read by probe 5 or value obtained from pressure transducer.
dP6 (Pb6) Value read by probe 6.
dPP Pressure value read by (Pb5) transducer.
rPP Virtual pressure probe, only on slave.
L°t Minimum room temperature;
H°t Maximum room temperature;
dPr Virtual probe for room temperature regulation [rPA and rPb];
dPd Virtual probe for defrost management [dPA];
dPF Virtual probe for fan management [FPA];
rSE Real thermoregulation set point: the value includes the sum of SET, HES and/or the
dynamic set point if the functions are enabled.
Exit
Pressed together or wait the timeout of about 60 sec
10. MENU FOR MULTIMASTER FUNCTION: SEC
The function “section” SEC is enabled when icon is lit. It allows entering in the remote programming mode,
from a keyboard not physically connected to the board, through the LAN functionality.
Action
Button or display
Notes
Enter menu
Press UP arrow for about 3 sec, the icon will be ON.
Waiting for action
SEC
The menu to change the section will be entered. SEC label
will be displayed.
Enter section list
Press SET to confirm. The following list will be available to
select the proper network function.
Select proper
function
Or
LOC
ALL
SE1
SEn
SE8
To gain access only to the local device.
To gain access to all the devices connected to the LAN.
To gain access to the device with 1st Adr (*)
…
To gain access to the device with 8th Adr (*)
Confirm
Select and confirm an entry by pressing SET button.
Exit menu
Press SET and UP together or wait about 10 seconds.
(*) The devices on the LAN are indexed by using the Adr parameter (in ascending order).
EXAMPLES:
1. To modify the same parameter values in all the devices connected to the LAN: enter multimaster menu.
Select and confirm ALL. Exit from multimaster menu. Enter the programming menu and change the
required parameter values.
The new values will be changed on all devices connected to the LAN.
2. To modify a parameter value in the device with [Adr = 35]: find the relevant indexed section (the one
linked to [Adr = 35]). Enter multimaster menu. Select and confirm this section from the multimaster menu.
Exit from multimaster menu. Enter the programming menu and change the required parameter value.
3. If the alarm nod is present: enter the multimaster menu. Select and confirm the LOC section. Exit from
multimaster menu.
AT THE END OF THE PROGRAMMING PROCEDURE, SELECT THE SECTION “LOC”. IN THIS WAY
THE ICON WILL BE SWITCHED OFF!!
10.1 SYNCHRONIZED DEFROST
The synchronized defrost allow to manage multiple defrost from different boards connected through the LAN
connection. In this way, the boards can perform simultaneous defrosts with the possibility to end them in a
synchronized way.
The Adr parameter cannot be duplicated because in this case the defrost cannot be correctly managed.
BEGIN
Press for 3 seconds, the rtC or other will be showed. The
measurement unit blinks.
Find Adr
Press more than once the DOWN arrow to find the Adr parameter,
the press SET.
Modify Adr
or
Set the value of Adr parameter, then press SET to confirm the
parameter.
EXIT
Press the two keys together to exit from menu or wait for about 10
seconds.
The LSn and LAn parameter are only to show the actual settings (read only). Se the following example of
configuration:
DAILY DEFROST FROM RTC: : [cPb = y] & [EdF = rtC]
IdF Parameter: for safety reason force the value of Idf at +1 respect to the interval between two Ld parameters.
The IdF timer is reinitialized after defrost and at every power-on.
DEFROST START: at the time selected by the parameters Ld1 to Ld6 or Sd1 to Sd6.
DEFROST END: if the probes reach the dtE temperature or for maximum MdF time.
SAFETY and RtC or RtF ALARM: with clock alarm the device will use the parameter IdF, dtE and MdF.
WARNING: don’t set [EdF = rtC] and [CPb = n].
MULTIMASTER DEFROST: all the probes with clock
Table for example
Par.
Unit A (RTC)
Unit B (RTC)
Unit C (RTC)
Adr
n
N + 1
N + 2
EdF
rtC (clock)
rtC (clock)
rtC (clock)
IdF
9 hours safety
9 hours safety
9 hours safety
MdF
45 min safety
45 min safety
45 min safety
dtE
12°C safety
12°C safety
12°C safety
Ld1
06:00 1°
06:00 1°
06:00 1°
Ld2
14:00 2°
14:00 2°
14:00 2°
Ld3
22:00 3°
22:00 3°
22:00 3°
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11. COMMISSIONING
11.1 CLOCK SETTING AND RTC ALARM RESET
If the clock is present: [EdF = rtC] enable the defrost from rtc [Ld1 to Ld6].
BEGIN
UP arrow (press once) to access the fast access menu
Display
HM identify the clock RTC submenu; press
Display
HUr = hour press to confirm/modify
Min = minutes press to confirm/modify
…… don’t use others parameters if present.
EXIT
Press for about 10 sec. The operation resets the RTC alarm.
Note: the rtC clock menu is present also on the second level of parameters. Warning: if the board shows the
rtF alarm, the device has to be changed.
11.2 ELECTRONIC VALVE SETTINGS –ONLY FOR XM679K
Some parameters have to be checked:
[1] Superheat temperature probe: Ntc, Ptc, Pt1000 with parameter P6C. The sensor has to be fixed at the end
of the evaporator.
[2] Pressure transducer: [4 to 20mA] or ratiometric P5C = 420 or 5Vr with parameter P5C.
[3] Range of measurement: check the parameter of conversion PA4 and P20 that are related to the transducer.
TRANSDUCER: [-0.5/7Bar] or [0.5/8Bar abs] the correct setup is relative pressure with PA4 = -0.5 and P20 = 7.0.
The [0.5/12Bar abs] the correct setup is relative pressure with PA4 = -0.5 and P20 = 11.00.
Example of virtual pressure with unique [4 to 20mA] or [0 to 5V] transducer:
Param.
XM6x9K_1
without transducer
XM6x9K_2 + with
transducer
XM6x9K_3+ without
transducer
Adr
n
n + 1
n + 2
LPP
LPP = n
LPP = Y
LPP = n
P5C
LAN or not connect the
probe
P5C= 420 or 0-5V
LAN or not connect the
probe
PA4
Not used
-0.5 bar
Not used
P20
Not used
7.0 bar
Not used
[4] From EEV submenu: select the correct kind of gas with FTY parameter.
[5] Use the following parameters to setup the right valve driving, according to the valve datasheet from the
manufacturer.
12. KIND OF REGULATION FOR SUPERHEAT: SELF ADAPTIVE OR
MANUAL OPERATING MODE
12.1 GENERAL CONSIDERATIONS: SELF ADAPTIVE OR MANUAL SH CONTROL
The controller is able to regulate the superheat in manual or self adaptive mode, according to the value of the
parameter AMS, autotuing enabling.
With AMS = n: the normal SH regulation is performed
With AMS = y: the self adaptive SH regulation is performed
12.2 MANUAL OPERATING MODE - AMS = NO
The temperature and SH regulation can be performed in 2 ways according to the value of the parameter CrE:
on/off or continuous. See below in details.Standard temperature regulation
12.2.1 ON/OFF TEMPERATURE REGULATION [CrE = n]
1. Temperature regulation is ON/OFF and it depends on the SET point and HY parameter (dfferential) Valve
is closed when the temperature reaches the set point and open when the temperature is higher than set
point + differential.
2. The superheat is regulated to be closer to its set point.
3. With more pauses normally also the humidity is bigger.
4. Regulation pauses can be realized using Sti and Std parameters (during these pauses the valve is closed).
12.2.2 COUNTINUOUS REGULATION OF THE TEMPERATURE [CrE = Y] (with
superheat regulation):
1. The HY parameter becomes temperature band for PI control. A default good value is 6°C.
2. The regulation of injection is continuous and the cooling output is always on. The icon is always ON
excluding the defrost phase.
3. The superheat is regulated following the SSH parameter.
4. Regulation pauses can be realized using Sti and Std parameters (during these pauses the valve is closed).
5. Increasing the Int integral time it is possible to decrease the speed of reaction of the regulator on the HY
band.
12.3 SELF ADAPTIVE OPERATING MODE –AMS = YES
Auto-adaptive means to find and maintain the condition of the lowest super heating according to the load and
environmental conditions present in a given time on the evaporator.
The parameter AMS enables the self adaptive mode for the superheat regulation.
In this functioning the values of Pb and inC parameter are automatically set by the controller according to the kind
of applications and the response of the system.
With the AMS = YES, CrE must be set at NO.
The self adaptive algorithm does not affect, the functions related to the forced opening of the valve in special
situation such as:
Forced opening of the valve at start of regulation, parameter SFd (percentage) and SFd (time).
Forced opening of the valve after defrost, parameter oPd (percentage) and Pdd (time).
12.4 MINIMUM STABLE SUPERHEAT SEARCH - AMS = YES, ATU = YES
With the parameter ATU, the minimum stable superheat search function is enabled.
With ATU = yES controllers start searching the mimimum stable value for the SH, the minimum admitted value in
any case is LSH + 2°C (4°F).
Please take it in consideration, before setting LSH value.
12.5 VALVE CAPACITY REDUCING –MNF PARAMETER
Thanks to the parameter MnF it’s possible to reduce the capacity of the valve, to fine tune the valve to the
evaporator.
The regulation band is not affected from the modification of the MnF parameter.
See below the behaviour of the capcity of the valve, when the MnF parameter is adjusted.
NOTE: during the soft start phase (oPE, SFd), MnF parameter is not taken in consideration and the
capacity of the valve is set by the parameters oPE and oPd, respectively.
12.6 PRESSURE FILTERING –SUB PARAMETER
For a good SH regulation, it’s important to use a filtered value of the pressure.
This can be done by the parameter Sub.
Suggested values:
From 1-5 evaporators for each racks: Sub = 20
From 6-30 evaporators for each racks: Sub = 15
More than 30 evaporators for each racks: Sub =10
13. DISPLAY MESSAGES
Display
Causes
Notes
KEYBOARD
1
nod
No display: the keyboard is trying to work with
another board that is not working or not
present
Press for 3 sec UP arrow, enter the SEC
menu and select LOC entry.
2
Pon
Keyboard is unlocked
3
PoF
Keyboard is locked
4
rSt
Alarm reset
Alarm output deactivated
5
noP, nP
nA
Not present (configuration)
Not available (evaluation)
6
noL
The keyboard is not able to communicate with
the XM670-XM679K
Verify the connection. Call the Service
ALARM FROM PROBE INPUT
6
P1
P2
P3
P4
P5
P6
PPF
CPF
Sensor brake down, value out of range or
sensor incorrectly configured P1C, P2C to
P6C.
PPF can be showed by slaves of pressure
that don’t receive the value of pressure.
CPF is showed when the remote probe 4 is
not working.
P1: the cooling output works with Con
and COF,
With defrost probe on error the defrost is
performed only at interval.
For P5, P6 and PPF: the percentage of
the valve opening is fixed at PEO value.
TEMPERATURE ALARM
7
HA
Temperature alarm from parameter ALU on
probe rAL.
Outputs unchanged.
8
LA
Temperature alarm from parameter ALL on
probe rAL.
Outputs unchanged.
"HAd
Defrost high temperature
Outputs unchanged.
"LAd”
Defrost low temperature
Outputs unchanged.
"FAd”
Fan low temperature
Outputs unchanged.
"HAF”
Fan high temperature
Outputs unchanged.
DIGITAL INPUT ALARM
13
dA
Door open alarm from input i1F, i2F or i3F =
after delay d1d, d2d or d3d.
Cooling relay and fan follow the odc
parameter. Cooling restart as specified
on rrd parameter.
14
EA
Generic alarm from digital input i1F, i2F, i3F =
EAL.
15
CA
Severe alarm of regulation lock from digital
input i1F, i2F, i3F = bAL.
Regulation output OFF.
16
PAL
Pressure switch lock i1F, i2F o i3F = PAL.
All the outputs are OFF.
ELECTRONIC VALVE ALARM
17
LOP
Minimum operating pressure threshold from
LOP parameter.
The valve output increases its opening of
dML quantity every second.
18
MOP
Maximum operating pressure threshold from
MOP parameter.
The valve output decreases its opening
of dML quantity every second.
19
LSH
Low superheating from LSH parameter and
SHd delay.
The valve will be closed; the alarm will
be showed after SHd delay.
20
HSH
High superheating from HSH parameter and
SHd delay.
Only display.
CLOCK ALARM
21
rtC
Clock settings lost.
Defrost will be performed with IdF till
restoring the settings of RTC.
22
rtF
Clock damaged.
Defrost will be performed with IdF.
OTHERS
23
EE
EEPROM serious problem.
Output OFF.
24
Err
Error with upload/download parameters.
Repeat the operation.
25
End
Parameters have been correctly transferred.
13.1 ALLARM RECOVERY
Probe alarms P1, P2, P3 and P4 start some seconds after the fault in the related probe; they automatically stop
some seconds after the probe restarts normal operation. Check connections before replacing the probe.
Temperature alarms HA, LA, HA2 and LA2 automatically stop as soon as the temperature returns to normal
values.
Alarms EA and CA (with i1F = bAL)recover as soon as the digital input is disabled. Alarm CA (with i1F = PAL)
recovers only by switching off and on the instrument.
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14. ELECTRONIC EXPANSION VALVE MENU (ONLY FOR XM679K)
+SET
1. Enter the Programming mode by pressing the SET and DOWN key for few
seconds (measurement unit starts blinking).
2. Press arrows until the instrument shows EEU label;
3. Press SET. You are now in EEV function menu;
15. CONTROLLING LOADS
15.1 THE SOLENOID VALVE
The regulation is performed according to the temperature measured by the thermostat probe that can be
physical probe or virtual probe obtained by a weighted average between two probes (see parameters
table description) with a positive differential from the set point. If the temperature increases and reaches
set point plus differential the solenoid valve is opened and then it is closed when the temperature reaches
the set point value again.
In case of fault in the thermostat probe the opening and closing time of solenoid valve is configured by
“Con” and “CoF”parameters.
15.2 STANDARD REGULATION AND CONTINUOUS REGULATION
The regulation can be performed in two ways: the goal of the first way (standard regulation) is reaching
the best superheat via a classic temperature regulation obtained using hysteresis. The second way,
permits to use the valve to realise an high performance temperature regulation with a good factor of
superheat precision. This second possibility, it can be used only in centralized plants and it is
available only with electronic expansion valve by selecting CrE=Y parameter.
In any case, the regulation is performed via PI regulator that gives the opening percentage to the valve
via PWM modulation explained as follow. Opening percentage is obtained from average of Opening Time
respect to CyP time period like following diagram:
With opening percentage we mean percentage of cycle period where valve is open. For example, if
CyP=6s (standard value) by saying: “The valve is opened at 50%”; this means that the valve is opened
for 3s during cycle period.
First kind of regulation:
In this case, the Hy parameter is the differential for standard ON/OFF regulation. In this case the int
parameter is neglected. The regulation follow this diagram:
Second kind of regulation –Continuous regulation (only XM679K):
In this case, the Hy parameter is the proportional band of PI in charge of room temperature regulation and
we advise to used at least Hy=5.0°C/10°F. The int parameter is the integral time of the same PI regulator.
Increasing int parameter the PI regulator become slow in reaction and of course is true vice versa. To
disable the integral part of regulation you should set int=0.
15.3 DEFROST
Defrost starting
In any case, the device check the temperature read by configured defrost probe before starting
defrost procedure, after that:
-(If RTC is present)Two defrost modes are available through the “tdF” parameter: defrost with electrical
heater and hot gas defrost. The defrost interval is controlled by parameter “EdF”: (EdF = rtc) defrost is
made in real time depending on the hours set in the parameters Ld1..Ld6 in workdays and in Sd1…Sd6
on holidays; (EdF = in) the defrost is made every “IdF” time;
-defrost cycle starting can be operated locally (manual activation by means of the keyboard or digital
input or end of interval time) or the command can come from the Master defrost unit of the LAN. In this
case the controller will operate the defrost cycle following the parameters it has programmed but, at
the end of the drip time, will wait that all the other controllers of the LAN finish their defrost cycle before
to re-start the normal regulation of the temperature according to dEM parameter;
-Every time any of the controller of the LAN begin a defrost cycle it issue the command into the network
making all the other controllers start their own cycle. This allows a perfect synchronisation of the defrost
in the whole multiplexed cabinet according to LMd parameter;
-Selecting dPA and dPb probes and by changing the dtP and ddP parameters the defrost can be started
when the difference between dPA and dPb probes is lower than dtP for all ddP time. This is useful to
start defrost when a low thermal exchange is detected. If ddP=0 this function is disabled;
Defrost ending
-When defrost is started via rtc, the maximum duration of defrost is obtained from Md parameter and
the defrost end temperature is obtained from dtE parameter (and dtS if two defrost probes are
selected).
-If dPA and dPb are present and d2P=y the instrument stops the defrost procedure when dPA is higher
than dtE temperature and dPb is higher than dtS temperature;
At the end of defrost the drip time is controlled through the “Fdt” parameter.
15.4 FANS
CONTROL WITH RELAY
The fan control mode is selected by means of the “FnC” parameter:
C-n = running with the solenoid valve, OFF during the defrost;
C-y = running with th1e solenoid valve, ON during the defrost;
O-n = continuous mode, OFF during the defrost;
O-y = continuous mode, ON during the defrost;
An additional parameter “FSt” provides the setting of temperature, detected by the evaporator probe,
above which the fans are always OFF. This can be used to make sure circulation of air only if his
temperature is lower than set in “FSt”.
CONTROL WITH ANALOG OUTPUT (if present)
The modulating output (trA=rEG) works in
proportional way (excluding the first AMt
seconds where the fans speed is the
maximum). The regulation set point is relative
to regulation set point and is indicated by ASr,
the proportional band is always located above
SET+ASr value and its value is PbA. The fan
are at minimum speed (AMi) when the
temperature read by fan probe is SET+ASr
and the fan is at maximum speed (AMA) when
the temperature is SET+ASr+PbA.
15.5 ANTI SWEAT HEATERS
The anti-sweat heater regulation can be performed with on board relay (if OA6 = AC) or with the analog output (if
present by setting trA = AC). However the regulation can be performed in two ways:
Without real dew-point information: in this case the default value for dew-point is used (SdP
parameter).
Receiving dew-point from XWEB5000 system: the SdP parameter is overwritten when valid value
for dew-point is received from XWEB. In case of XWEB link is lost, SdP is the value that will be
used for safety.
The best performance can be obtained using probe 4. In this case, the regulation follows the chart:
Probe 4 should be placed on the showcase glass. For each cabinet can be used only one probe 4 (P4) sending
its value to the others section that are connected to the LAN.
HOW TO WORK WITH PROBE 4 THROUGH THE LAN:
Param.
XM6x9K_1
Without probe 4
XM6x9K_2 + with probe 4
XM6x9K_3+ Without
probe 4
Adr
n
n + 1
n + 2
LCP
LCP = n
LCP = Y
LCP = n
P4C
LAN or not connect the
probe
P4C = NTC, PtC or PtM
LAN or not connect the
probe
trA
trA = AC if the device has the analog output
OA6
OA6 = AC if the device will use the AUX relay for regulation
HOW TO WORK WITHOUT PROBE 4:
Param.
XM6x9K
Without probe 4
P4C
nP
AMt
% of ON
In this case, the regulation is performed by switching on
and off the auxiliary relay on a 60 minutes time base. The
ON time will be the AMt value, so that the relay will be ON
for AMt minutes and OFF for [60-AMt] minutes.
In case of P4 error or if P4 is absent the output is at AMA value for the AMt time then the output is at 0 value for
the time [255 –AMt] time performing a simple PWM modulation.
15.6 AUXILIARY OUTPUT
The auxiliary output is switch ON and OFF by means of the corresponding digital input or by pressing and releasing
the down arrow key.
16. PARAMETER LIST
REGULATION
Set Temperature set point (LS÷US)
rtC Access to CLOCK submenu (if present);
EEU Access to EEV submenu (only XM679K);
Hy Differential: (0,1÷25,5°C; 1÷45°F): Intervention differential for set point, always positive.
Solenoid valve Cut IN is Set Point Plus Differential (Hy). Solenoid valve Cut OUT is when the
temperature reaches the set point.
Int Integral time for room temperature regulation (Only XM679K): (0 ÷ 255 s) integral time for
room temperature PI regulator. 0= no integral action;
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CrE Continuous regulation activation (Only XM679K): (n÷Y) n= standard regulation; Y=
continuous regulation. Use it only in centralized plants;
LS Minimum set point limit: (-55.0°C
SET; -67°F÷SET) Sets the minimum acceptable value for
the set point.
US Maximum set point limit: (SET
150°C; SET÷302°F) Set the maximum acceptable value for set
point.
OdS Outputs activation delay at start up: (0÷255 min) This function is enabled at the initial start up
of the instrument and inhibits any output activation for the period of time set in the parameter.
(AUX and Light can work)
AC Anti-short cycle delay: (0÷60 min) interval between the solenoid valve stop and the following
restart.
CCt Compressor ON time during continuous cycle: (0.0÷24.0h; resolution 10min) Allows to set
the length of the continuous cycle: compressor stays on without interruption for the CCt time. Can
be used, for instance, when the room is filled with new products.
CCS Set point for continuous cycle: (-55÷150°C / -67÷302°F) it sets the set point used during the
continuous cycle.
Con solenoid valve ON time with faulty probe: (0÷255 min) time during which the solenoid valve is
active in case of faulty thermostat probe. With COn=0 solenoid valve is always OFF.
CoF solenoid valve OFF time with faulty probe: (0÷255 min) time during which the solenoid valve
is off in case of faulty thermostat probe. With COF=0 solenoid valve is always active.
DISPLAY
CF Temperature measurement unit: °C=Celsius; °F=Fahrenheit. !!! WARNING !!! When the
measurement unit is changed the parameters with temperature values have to be checked.
PrU Pressure mode: (rEL or AbS) it defines the mode to use the pressure. !!! WARNING !!! the setting
of PrU is used for all the pressure parameters. If PrU=rEL all pressure parameters are in relative
pressure unit, if PrU=AbS all pressure parameters are in absolute pressure unit. (Only XM679K)
PMU Pressure measurement unit: (bAr –PSI - MPA) it selects the pressure measurement units.
MPA= the value of pressure measured by kPA*10. (Only XM679K)
PMd Way of displaying pressure : (tEM - PrE) it permits showing the value measured by pressure
probe with tEM= temperature or by PrE= pressure; (Only XM679K)
rES Resolution (for °C): (in = 1°C; dE = 0.1 °C) allows decimal point display;
Lod Instrument display: (nP; P1; P2, P3, P4, P5, P6, tEr, dEF) it selects which probe is displayed by
the instrument. P1, P2, P3, P4, P5, P6,tEr= virtual probe for thermostat, dEF= virtual probe for
defrost.
red Remote display: (nP; P1; P2, P3, P4, P5, P6, tEr, dEF) it selects which probe is displayed by
the X-REP. P1, P2, P3, P4, P5, P6,tEr= virtual probe for thermostat, dEF= virtual probe for
defrost.
dLy Display delay: (0 ÷24.0 m; resolution 10s) when the temperature increases, the display is
updated of 1 °C/1°F after this time.
rPA Regulation probe A: (nP; P1; P2, P3, P4, P5) first probe used to regulate room temperature. If
rPA=nP the regulation is performed with real value of rPb.
rPb Regulation probe B: (nP; P1; P2, P3, P4, P5) second probe used to regulate room temperature.
If rPb=nP the regulation is performed with real value of rPA
rPE Regulation virtual probe percentage: (0 ÷ 100%) it defines the percentage of the rPA respect
to rPb. The value used to regulate room temperature is obtained by:
value_for_room = (rPA*rPE + rPb*(100-rPE))/100
ELECTRONIC EXPANSION VALVE SUBMENU (Only XM679K)
FtY Kind of gas:
LABEL
REFRIGERANT
OPERATING RANGE
R22
r22
-50-60°C/-58÷120°F
134
r134A
-50-60°C/-58÷120°F
290
r290 –Propane
-50-60°C/-58÷120°F
404
r404A
-70-60°C/-94÷120°F
47A
r407A
-50-60°C/-58÷120°F
47C
r407C
-50-60°C/-58÷120°F
47F
r407F
-50-60°C/-58÷120°F
410
r410A
-50-60°C/-58÷120°F
448
r448A
-45-60°C/-69÷120°F
449
r449A
-45-60°C/-69÷120°F
450
r450A
-45-60°C/-69÷120°F
507
r507
-70-60°C/-94÷120°F
513
r513A
-45-60°C/-69÷120°F
CO2
r744 - Co2
-50-60°C/-58÷120°F
Atu Minimum STABLE superheat search (No; yES) This parameter enables the search of the minimum
stable superheat. The lowest admitted value is LSH+2°C
AMS Self self adaptive SH regulation enabling (No; yES) This parameter enables the self adaptive
regulation of the superheat. CrE = no must to be set, when this function is enabled.
SSH Superheat set point: [0.1°C ÷ 25.5°C] [1°F ÷ 45°F] it’s the value used to regulate superheat
CyP Cycle Period: (1 ÷ 15s) it permits to set cycle time;
Pb Proportional band: (0.1 ÷ 60.0 / 1÷108°F) PI proportional band;
rS Band Offset: (-12.0 ÷ 12.0°C / -21÷21°F) PI band offset;
inC Integration time: (0 ÷ 255s) PI integration time;
PEO Probe Error opening percentage: (0÷100%) if a temporary probe error occurs, valve opening
percentage is PEo until PEd time is elapsed;
PEd Probe Error delay before stopping regulation: (0÷239 sec. –On=unlimited) if probe error
duration is bigger than PEd then valve totally closes. Pf message is showed. If PEd=On valve
opening is PEo until probe error finishes;
OPE Start opening Percentage: (0÷100%) Opening valve percentage when start function is active.
This phase duration is SFd time;
SFd Start Function duration: (0.0 ÷ 42.0 min: resolution 10s) It sets start function duration and post-
defrost duration. During this phase the alarms are neglected;
OPd Opening Percentage after defrost phase: (0÷100%) Opening valve percentage when after
defrost function is active. This phase duration is Pdd time;
Pdd Post Defrost Function duration: (0.0 ÷ 42.0 min: resolution 10s) It sets start function duration
and post-defrost duration. During this phase the alarms are neglected;
MnF Maximum opening percentage at normal Functioning: (0÷100%) during regulation it sets the
maximum valve opening percentage;
dCL Delay before stopping valve regulation: (0 ÷ 255s) When the cooling request goes off, the
electronic valve regulation can go on for the dCL time in order to prevent uncontrolled superheat
variation;
Fot Forced opening percentage: (0÷100% - nu) it permits to force the valve opening to the specified
value. This value overwrite the value calculated by PID algorithm. !!!! WARNING !!!! to obtain
the correct superheat regulation you have to set Fot=nu;
PA4 Probe value At 4mA or At 0V: (-1.0 ÷ P20 bar / -14 ÷ PSI / -10 ÷ P20 kPA*10) pressure value
measured by probe at 4mA or at 0V (related to PrM parameter) Referred to Pb5
P20 Probe value 20mA or At 5V: (PA4 ÷ 50.0 bar / 725 psi / 500 kPA*10) pressure value measured
by probe at 20mA or at 5V (related to PrM parameter) Referred to Pb5
LPL Lower Pressure Limit for superheat regulation: (PA4 ÷ P20 bar / psi / kPA*10) when suction
pressure comes down to LPL the regulation is performed with a LPL fixed value for pressure,
when pressure comes back to LPL the normal pressure value is used. (related to PrM parameter)
MOP Maximum Operating Pressure threshold: (PA4 ÷ P20 bar / psi / kPA*10)if suction pressure
exceeds maximum operating pressure value, instrument signals situation with MOP alarm.
(related to PrM parameter)
LOP Lowest Operating Pressure threshold: (PA4 ÷ P20 bar / psi / kPA*10) if the suction pressure
comes down to this value a low pressure alarm is signalled with LOP alarm. (related to PrM
parameter)
dML delta MOP-LOP: (0 ÷ 100%) when a MOP alarm occurs valve will close of the dML percentage
every cycle period until MOP alarm is active. When LOP occurs valve will open of the dML
percentage every cycle period until LOP alarm is active.
MSH Maximum Superheat alarm: (LSH ÷ 80.0°C / LSH ÷ 144°F) when superheat exceeds this value
an high superheat alarm is signalled after interval SHd
LSH Lowest Superheat alarm: (0.0 ÷ MSH °C / 0÷MSH °F) when superheat goes down to this value
a low superheat alarm is signalled after interval SHd
SHy Superheat alarm Hysteresis: (0.1÷25.5°C/1÷45°F) hysteresis for superheat alarm deactivation
SHd Superheat alarm activation delay: (0.0 ÷ 42.0 min: resolution 10s) when a superheat alarm
occurs, the time SHd have to pass before signalling alarm;
FrC Fast-recovery Constant: (0÷100 s) permits to increase integral time when SH is below the set-
point. If FrC=0 fast recovery function is disabled.
Sub Pressure filter (0÷100) It uses the last average values of the pressure to calculate the superheat.
SLb Reaction time (0÷255s): time to update the valve open percentage.
EI. With SLb = 24: the valve open percentage is updated every 24s.
DEFROST
dPA defrost Probe A: (nP; P1; P2, P3, P4, P5) first probe used for defrost. If rPA=nP the regulation
is performed with real value of dPb.
dPb defrost Probe B: (nP; P1; P2, P3, P4, P5) second probe used for defrost. If rPB=nP the
regulation is performed with real value of dPA.
dPE defrost virtual probe percentage: (0÷100%) it defines the percentage of the dPA respect to
dPb. The value used to regulate room temperature is obtained by:
value_for_defrost= (dPA*dPE + dPb*(100-dPE))/100
tdF Defrost type: (EL –in) EL = electrical heater; in = hot gas;
EdF Defrost mode: (rtc –in) (only if RTC is present) rtc= defrost activation via RTC; in= defrost
activation with idf.
Srt Heater set point during defrost: (-55.0 ÷ 150.0°C; -67 ÷ 302°F) if tdF=EL during the defrost
the defrost relay perform an ON/OFF regulation with Srt as set point.
Hyr Differential for heater: (0.1°C ÷ 25.5°C , 1°F ÷ 45°F) the differential for heater;
tod Time out for heater: 0 ÷ 255 (min.) if the defrost probe temperature is bigger than Srt for all tod
time the defrost ends altough the defrost probe temperature is lower than dtE or dtS. It permits to
reduce defrost duration;
dtP Minimum temperature difference to start defrost: [0.1°C ÷ 50.0°C] [1°F ÷ 90°F] if the
difference between the two defrost probes stays lower than dtP for all ddP time the defrost is
activated;
ddP Delay before starting defrost (related to dtP): (0 ÷ 60 min) delay related to dtP.
d2P Defrost with two probes: (n –Y) n= only the dPA probe is used to defrost management; Y=
defrost is managed with dPA probe and dPb probe. Defrost can performed only if both probe
value are lower than dtE for dPA probe and dtS for dPb probe;
dtE Defrost termination temperature (Probe A): (-55,0÷50,0°C; -67÷122°F) (Enabled only when
the evaporator probe is present) sets the temperature measured by the evaporator probe dPA
which causes the end of defrost;
dtS Defrost termination temperature (Probe B): (-55,0÷50,0°C; -67÷122°F) (Enabled only when
the evaporator probe is present) sets the temperature measured by the evaporator probe dPb
which causes the end of defrost;
IdF Interval between defrosts: (0÷120h) Determines the time interval between the beginning of two
defrost cycles;
MdF Maximum duration of defrost: (0÷255 min) When dPA and dPb aren’t present, it sets the
defrost duration, otherwise it sets the maximum duration for defrost;
dSd Start defrost delay: (0 ÷ 255 min) This is useful when different defrost start times are necessary
to avoid overloading the plant.
dFd Display during defrost: rt = real temperature; it = temperature reading at the defrost start; Set
= set point; dEF = “dEF” label;
dAd Defrost display time out: (0
255 min) Sets the maximum time between the end of defrost and
the restarting of the real room temperature display.
Fdt Drain down time: (0÷255 min.) time interval between reaching defrost termination temperature
and the restoring of the control’s normal operation. This time allows the evaporator to eliminate
water drops that might have formed due to defrost.
dPo First defrost after start-up: y = Immediately; n= after the IdF time
dAF Defrost delay after continuous cycle: (0÷23.5h) time interval between the end of the fast
freezing cycle and the following defrost related to it.
FAN
FPA Fan probe A: (nP; P1; P2, P3, P4, P5) first probe used for fan. If FPA=nP the regulation is
performed with real value of FPB;
FPB Fan probe B: (nP; P1; P2, P3, P4, P5) second probe used for defrost. If FPB=nP the regulation
is performed with real value of FPB;
FPE Fan virtual probe percentage: (0÷100%) it defines the percentage of the FPA respect to FPb.
The value used to regulate room temperature is obtained by:
value_for_defrost= (FPA*FPE + FPb*(100-FPE))/100
FnC Fan operating mode: C-n = running with the solenoid valve, OFF during the defrost; C-y =
running with the solenoid valve, ON during the defrost; O-n = continuous mode, OFF during the
defrost; O-y = continuous mode, ON during the defrost;
Fnd Fan delay after defrost: (0÷255 min) The time interval between the defrost end and evaporator
fans start.
FCt Temperature differential avoiding short cycles of fans (0.0°C ÷ 50.0°C; 0°F ÷ 90°F) If the
difference of temperature between the evaporator and the room probes is more than the value of
the Fct parameter, the fans are switched on;
FSt Fan stop temperature: (-50÷110°C; -58÷230°F) setting of temperature, detected by evaporator
probe, above which the fan is always OFF.
FHy Differential to restart fan: (0.1°C ÷ 25.5°C) (1°F ÷ 45°F) when stopped, fan restarts when fan
probe reaches FSt-FHy temperature;
Fod Fan activation time after defrost: (0 ÷ 255 min.) it forces fan activation for indicated time;
Fon Fan ON time: (0÷15 min) with Fnc = C_n or C_y, (fan activated in parallel with compressor). it
sets the evaporator fan ON cycling time when the compressor is off. With Fon =0 and FoF ≠ 0
the fan are always off, with Fon=0 and FoF =0 the fan are always off.
FoF Fan OFF time: (0÷15 min) with Fnc = C_n or C_y, (fan activated in parallel with compressor). it
sets the evaporator fan off cycling time when the compressor is off. With Fon =0 and FoF ≠ 0 the
fan are always off, with Fon=0 and FoF =0 the fan are always off.
MODULATING OUTPUT (AnOUT) if present
trA Kind of regulation with PWM output: (UAL –rEG –AC) it selects the functioning for the PWM
output. UAL= the output is at FSA value; rEG= the output is regulated with fan algorithm
described in fan section; AC= anti-sweat heaters control (require the XWEB5000 system);
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SOA Fixed value for analog output: (0 ÷ 100%) value for the output if trA=UAL;
SdP Default value for Dew point: (-55,0÷50,0°C; -67÷122°F) default value of dew point used when
there is no supervising system (XWEB5000). Used only when trA=AC;
ASr Dew-point offset (trA=AC) / Differential for modulating fan regulation (trA=rEG): (-25.5°C ÷
25.5°C) (-45°F ÷ 45°F);
PbA Differential for anti-sweat heaters: (0.1°C ÷ 25.5°C) (1°F ÷ 45°F)
AMi Minimum value for analog output: (0÷AMA)
AMA Maximum value for analog output: (Ami ÷ 100)
AMt Anti-sweat heaters cycle period (trA=AC)/ Time with fan at maximum speed (trA=rEG):
(0÷255 s) when the fan starts, during this time the fan is at maximum speed;
ALARMS
rAL Probe for temperature alarm: (nP - P1 - P2 - P3 - P4 - P5 –tEr) it selects the probe used to
signal alarm temperature
ALC Temperature alarm configuration: rE = High and Low alarms related to Set Point; Ab = High
and low alarms related to the absolute temperature.
ALU High temperature alarm setting: (ALC= rE, 0
50°C or 90°F / ALC= Ab, ALL
150°C or 302°F)
when this temperature is reached and after the ALd delay time the HA alarm is enabled.
ALL Low temperature alarm setting: (ALC = rE , 0
50 °C or 90°F / ALC = Ab , - 55°C or - 67°F
ALU) when this temperature is reached and after the ALd delay time, the LA alarm is enabled.
AHy Differential for temperature alarm: (0.1°C ÷ 25.5°C / 1°F ÷ 45°F) Intervention differential for
recovery of temperature alarm;
ALd Temperature alarm delay: (0÷255 min) time interval between the detection of an alarm condition
and the corresponding alarm signalling.
dLU High temperature alarm (defrost probe): (ALC= rE, 0
50°C or 90°F / ALC= Ab, ALL
150°C
or 302°F) when this temperature is reached and after the ddA delay time the HAdalarm is
enabled.
dLL Low temperature alarm (defrost probe): (ALC = rE , 0
50 °C or 90°F / ALC = Ab , - 55°C or
- 67°F
ALU) when this temperature is reached and after the ALd delay time, the LAd alarm is
enabled.
dAH Differential for temperature alarm (defrost probe): (0.1°C ÷ 25.5°C / 1°F ÷ 45°F) Intervention
differential for recovery of temperature alarm;
ddA Temperature alarm delay (defrost probe): (0÷255 min) time interval between the detection of
an alarm condition and the corresponding alarm signalling.
FLU High temperature alarm (defrost probe): (ALC= rE, 0
50°C or 90°F / ALC= Ab, ALL
150°C
or 302°F) when this temperature is reached and after the FAd delay time the HAFalarm is
enabled.
FLL Low temperature alarm (defrost probe): (ALC = rE , 0
50 °C or 90°F / ALC = Ab , - 55°C or
- 67°F
ALU) when this temperature is reached and after the FAddelay time, the LAFalarm is
enabled.
FAH Differential for temperature alarm (defrost probe): (0.1°C ÷ 25.5°C / 1°F ÷ 45°F) Intervention
differential for recovery of temperature alarm;
FAd Temperature alarm delay (defrost probe): (0÷255 min) time interval between the detection of
an alarm condition and the corresponding alarm signalling.
dAO Delay of temperature alarm at start-up: (0min÷23h 50min) time interval between the detection
of the temperature alarm condition after the instrument power on and the alarm signalling.
EdA Alarm delay at the end of defrost: (0
255 min) Time interval between the detection of the
temperature alarm condition at the end of defrost and the alarm signalling.
dot Temperature alarm exclusion after door open:
Sti Stop regulation interval (Only XM679K): (0.0÷24.0 hours: tens of minutes) after regulating
continuously for Sti time, the valve closes for Std time in order to prevent ice creation.
Std Stop duration (Only XM679K): (0÷60 min.) it defines stop regulation time after Sti.
nMS Maximum number of regulation pauses (nu, 1÷255)
OPTIONAL OUTPUT (AnOUT) if present
OA6 Sixth relay configuration (CPr-dEF-Fan-ALr-LiG-AUS-db-OnF): CPr= relay works as a
compressor or solenoid valve relay; dEF= relay works as defrost relay; Fan= relay works as a
Fan relay; ALr= activation with alarm conditions; LiG= light activation; AUS= auxiliary relay, it
can be switched ON/OFF also by key; db= dead band regulation (not compatible with CrE=y);
OnF= ON/OFF functioning;
CoM Type of functioning modulating output:
For models with PWM / O.C. output PM5= PWM 50Hz; PM6= PWM 60Hz;
OA7= not set it;
For models with 4÷20mA / 0÷10V output Cur= 4÷20mA current output; tEn=
0÷10V voltage output;
AOP Alarm relay polarity: cL= normally closed; oP= normally opened;
iAU Auxiliary output is unrelated to ON/OFF device status: n= if the instrument is switched off
also the auxiliary output is switched off; Y= the auxiliary output state is unrelated to the ON/OFF
device status
DIGITAL INPUTS
i1P Digital input 1 polarity: (cL –oP) CL: the digital input is activated by closing the contact; OP:
the digital input is activated by opening the contact.
i1F Digital input 1 function: (EAL –bAL –PAL –dor –dEF –AUS –LiG –OnF –Htr –FHU –ES
–Hdy) EAL= external alarm; bAL= serious external alarm; PAL= pressure switch activation; dor=
door open; dEF= defrost activation; AUS= auxiliary activation; LiG= light activation; OnF= switch
on/off the instrument; Htr= change type of action ; FHU= not used; ES= activate energy saving;
Hdy= activate holiday function;
d1d Time interval/delay for digital input alarm: (0
255 min.) Time interval to calculate the number
of the pressure switch activation when i1F=PAL. If I1F=EAL or bAL (external alarms), “d1d”
parameter defines the time delay between the detection and the successive signalling of the
alarm. If i1F=dor this is the delay to activate door open alarm
i2P Digital input 2 polarity: (cL –oP) CL : the digital input is activated by closing the contact; OP:
the digital input is activated by opening the contact.
i2F Digital input 2 function: (EAL –bAL –PAL –dor –dEF –AUS –LiG –OnF –Htr –FHU –ES
–Hdy) EAL= external alarm; bAL= serious external alarm; PAL= pressure switch activation; dor=
door open; dEF= defrost activation; AUS= auxiliary activation; LiG= light activation; OnF= switch
on/off the instrument; Htr= change type of action ; FHU= not used; ES= activate energy saving;
Hdy= activate holiday function;
d2d Time interval/delay for digital input alarm: (0
255 min.) Time interval to calculate the number
of the pressure switch activation when i2F=PAL. If I2F=EAL or bAL (external alarms), “d2d”
parameter defines the time delay between the detection and the successive signalling of the
alarm. If i2F=dor this is the delay to activate door open alarm
i3P Digital input 3 polarity: (cL –oP) CL : the digital input is activated by closing the contact; OP:
the digital input is activated by opening the contact.
i3F Digital input 3 function: (EAL –bAL –PAL –dor –dEF –AUS –LiG –OnF –Htr –FHU –ES
–Hdy) EAL= external alarm; bAL= serious external alarm; PAL= pressure switch activation; dor=
door open; dEF= defrost activation; AUS= auxiliary activation; LiG= light activation; OnF= switch
on/off the instrument; Htr= change type of action ; FHU= not used; ES= activate energy saving;
Hdy= activate holiday function;
d3d Time interval/delay for digital input alarm: (0
255 min.) Time interval to calculate the number
of the pressure switch activation when i3F=PAL. If i3F=EAL or bAL (external alarms), “d3d”
parameter defines the time delay between the detection and the successive signalling of the
alarm. If i3F=dor this is the delay to activate door open alarm
nPS Pressure switch number: (0
15) Number of activation of the pressure switch, during the “d#d”
interval, before signalling the alarm event (I2F= PAL). If the nPS activation in the did time is
reached, switch off and on the instrument to restart normal regulation.
odc Compressor and fan status when open door: no = normal; Fan = Fan OFF; CPr =
Compressor OFF; F_C = Compressor and fan OFF.
rrd Outputs restart after doA alarm: no = outputs not affected by the doA alarm; yES = outputs
restart with the doA alarm;
RTC SUBMENU (if present)
CbP Clock Presence (n÷y): it permits to disable or enable the clock;
Hur Current hour (0 ÷ 23 h)
Min Current minute (0 ÷ 59min)
dAY Current day (Sun ÷ SAt)
Hd1 First weekly holiday (Sun ÷ nu) Set the first day of the week which follows the holiday times.
Hd2 Second weekly holiday (Sun ÷ nu) Set the second day of the week which follows the holiday
times.
Hd3 Third weekly holiday (Sun ÷ nu) Set the third day of the week which follows the holiday times.
ILE Energy Saving cycle start during workdays: (0 ÷ 23h 50 min.) During the Energy Saving cycle
the set point is increased by the value in HES so that the operation set point is SET + HES.
dLE Energy Saving cycle length during workdays: (0 ÷ 24h 00 min.) Sets the duration of the
Energy Saving cycle on workdays.
ISE Energy Saving cycle start on holidays. (0 ÷ 23h 50 min.)
dSE Energy Saving cycle length on holidays (0 ÷ 24h 00 min.)
HES Temperature increase during the Energy Saving cycle (-30÷30°C / -54÷54°F) sets the
increasing value of the set point during the Energy Saving cycle.
Ld1÷Ld6 Workday defrost start (0 ÷ 23h 50 min.) These parameters set the beginning of the 6
programmable defrost cycles during workdays. Ex. When Ld2 = 12.4 the second defrost starts at
12.40 during workdays.
Sd1÷Sd6 Holiday defrost start (0 ÷ 23h 50 min.) These parameters set the beginning of the 6
programmable defrost cycles on holidays. Ex. When Sd2 = 3.4 the second defrost starts at 3.40
on holidays.
ENERGY SAVING
ESP Energy saving probe selection: (nP - P1 - P2 - P3 - P4 - P5 –tEr).
HES Temperature increase during the Energy Saving cycle : (-30÷30°C / -54÷54°F) sets the
increasing value of the set point during the Energy Saving cycle.
PEL Energy saving activation when light is switched off: (n÷Y) n= function disabled; Y= energy
saving is actived when the light is switched off and vice versa;
LAN MANAGEMENT
LMd Desfrost synchronisation: y= the section send a command to start defrost to oher controllers,
n= the section don’t send a global defrost command
dEM Type of end defrost: n= the of the LAN defrost are indipendent; y= the end of the defrost are
synchronisated;
LSP L.A.N. set-point synchronisation: y= the section set-point, when modified, is updated to the
same value on all the other sections; n= the set-point value is modified only in the local section
LdS L.A.N. display synchronisation: y= the value displayed by the section is sent to all the other
sections; n= the set-point value is modified only in the local section
LOF L.A.N. On/Off synchronisation this parameter states if the On/Off command of the section will
act on all the other ones too: y= the On/Off command is sent to all the other sections; n= the
On/Off command acts only in the local section
LLi L.A.N. light synchronisation this parameter states if the light command of the section will act
on all the other ones too: y= the light command is sent to all the other sections; n= the light
command acts only in the local section
LAU L.A.N. AUX output synchronisation this parameter states if the AUX command of the section
will act on all the other ones too: y= the light command is sent to all the other sections; n= the
light command acts only in the local section
LES L.A.N. energy saving synchronisation this parameter states if the energy saving command of
the section will act on all the other ones too: y= the Energy Saving command is sent to all the
other sections; n= the Energy Saving command acts only in the local section
LSd Remote probe display: this parameter states if the section has to display the local probe value
or the value coming from another section: y= the displayed value is the one coming from another
section (which has parameter LdS = y); n= the displayed value is the local probe one.
LPP Remote pressure probe: n= the value of pressure probe is read from local probe; Y= the value
of pressure probe is sent via LAN;
StM Solenoid activation via LAN: n= not used; Y= a generic cooling requests from LAN activate the
solenoid valve connected to compressor relay;
PROBE CONFIGURATION
P1C Probe 1 configuration: (nP –Ptc –ntc –PtM) nP= not present; PtC= Ptc; ntc= NTC; PtM=
Pt1000;
Ot Probe 1 calibration: (-12.0
12.0°C/ -21
21°F) allows to adjust possible offset of the thermostat
probe.
P2C Probe 2 configuration: (nP –Ptc –ntc –PtM) nP= not present; PtC= Ptc; ntc = NTC; PtM=
Pt1000;
OE Probe 2 calibration: (-12.0
12.0°C/ -21
21°F) allows to adjust possible offsets of the evaporator
probe.
P3C Probe 3 configuration: (nP –Ptc –ntc –PtM) nP= not present; PtC= Ptc; ntc = NTC; PtM=
Pt1000;
o3 Probe 3 calibration: (-12.0
12.0°C/ -21
21°F) allows to adjust possible offset of the probe 3.
P4C Probe 4 configuration: (nP –Ptc –ntc –PtM) nP= not present; PtC= Ptc; ntc = NTC; PtM=
Pt1000;
o4 Probe 4 calibration: (-12.0
12.0°C/ -21
21°F) allows to adjust possible offset of the probe 4.
P5C Probe 5 configuration: (nP –Ptc –ntc –PtM –420 –5Vr) nP= not present; PtM= Pt1000; 420=
4÷ 20mA; 5Vr= 0÷5V ratiometric; (Only XM679K)
o5 Probe 5 calibration: (-12.0
12.0°C/ -21
21°F) allows to adjust possible offset of the probe 5.
(Only XM679K)
P6C Probe 6 configuration: (nP –Ptc –ntc –PtM) nP= not present; PtC= Ptc; ntc = NTC; PtM=
Pt1000; (Only XM679K)
o6 Probe 6 calibration: (-12.0
12.0°C/ -21
21°F) allows to adjust possible offset of the probe 6.
(Only XM679K)
SERVICE –READ ONLY
CLt Coling time percentage: it shows the effective cooling time calculated by XM600 during
regulation;
tMd Time to next defrost: it shows time before the next defrost if interval defrost is selected;
LSn L.A.N. section number (1 ÷ 8) Shows the number of sections available in the L.A.N.
Lan L.A.N. serial address (1 ÷ LSn) Identifies the instrument address inside local network of
multiplexed cabinet controller.
Adr RS485 serial address (1÷247): Identifies the instrument address when connected to a ModBUS
compatible monitoring system.
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Rel Release software: (read only) Software version of the microprocessor.
Ptb Parameter table: (read only) it shows the original code of the Dixell parameter map.
Pr2 Access to the protected parameter list (read only).
17. DIGITAL INPUTS
The XM600 series can support up to 3 free of voltage contact configurable digital inputs (depending on
the models). They are configurable via i#F parameter
17.1 GENERIC ALARM (EAL)
As soon as the digital input 1, 2, or 3 is activated the unit will wait for “d1d” or “d2d”or “d3d”time delay
before signalling the “EAL” alarm message. The outputs status don’t change. The alarm stops just after
the digital input is de-activated.
17.2 SERIOUS ALARM MODE (BAL)
When the digital input is activated, the unit will wait for “d1d” or “d2d”or “d3d” delay before signalling the
“BAL” alarm message. The relay outputs are switched OFF. The alarm will stop as soon as the digital
input is de-activated.
17.3 PRESSURE SWITCH (PAL)
If during the interval time set by “d1d” or “d2d”or “d3d” parameter, the pressure switch has reached the number
of activation of the “nPS” parameter, the “CA” pressure alarm message will be displayed. The compressor and
the regulation are stopped. When the digital input is ON the compressor is always OFF. If the nPS activation in
the d#d time is reached, switch off and on the instrument to restart normal regulation.
17.4 DOOR SWITCH INPUT (dor)
It signals the door status and the corresponding relay output status through the “odc” parameter: no = normal
(any change); Fan = Fan OFF; CPr = Compressor OFF; F_C = Compressor and fan OFF. Since the door is
opened, after the delay time set through parameter “d#d”, the door alarm is enabled, the display shows the
message “dA” and the regulation restarts after rrd time. The alarm stops as soon as the external digital input
is disabled again. With the door open, the high and low temperature alarms are disabled.
17.5 START DEFROST (DEF)
It executes a defrost if there are the right conditions. After the defrost is finished, the normal regulation
will restart only if the digital input is disabled otherwise the instrument will wait until the “Mdf” safety time
is expired.
17.6 RELAY AUX ACTUATION (AUS)
This function allows to turn ON and OFF the auxiliary relay by using the digital input as external switch.
17.7 RELAY LIGHT ACTUATION (LIG)
This function allows to turn ON and OFF the light relay by using the digital input as external switch.
17.8 REMOTE ON/OFF (ONF)
This function allows to switch ON and OFF the instrument.
17.9 KIND OF ACTION (HTR)
This function allows to change the kind of regulation from cooling to heating and vice versa.
17.10 FHU –NOT USED
This function allows to change the kind of regulation from cooling to heating and viceversa.
17.11 ENERGY SAVING INPUT (ES)
The Energy Saving function allows to change the set point value as the result of the SET+ HES
(parameter) sum. This function is enabled until the digital input is activated.
17.12 CONFIGURABLE INPUT - HOLIDAY FUNCTION (HDY)
In Holiday function Energy saving and defrost cycles follow holiday times. (Sd1…Sd6)
17.13 DIGITAL INPUTS POLARITY
The digital inputs polarity depends on “I#P”parameters: CL : the digital input is activated by closing the
contact; OP : the digital input is activated by opening the contact.
18. USE OF THE PROGRAMMING “HOT KEY“
The XM units can UPLOAD or DOWNLOAD the parameter list from its own E2 internal memory to the
“Hot Key” and vice-versa through a TTL connector.
18.1 DOWNLOAD (FROM THE “HOT KEY” TO THE INSTRUMENT)
1. Turn OFF the instrument by means of the ON/OFF key ,insert the “Hot Key” and then turn the unit
ON.
2. Automatically the parameter list of the “Hot Key” is downloaded into the controller memory, the
“doL” message is blinking. After 10 seconds the instrument will restart working with the new
parameters. At the end of the data transfer phase the instrument displays the following messages:
“end“ for right programming. The instrument starts regularly with the new programming. “err” for
failed programming. In this case turn the unit off and then on if you want to restart the download
again or remove the “Hot key” to abort the operation.
18.2 UPLOAD (FROM THE INSTRUMENT TO THE “HOT KEY”)
1. When the XM unit is ON, insert the “Hot key” and push “UP” key.
2. The UPLOAD begins; the “uPL” message is blinking.
3. Remove the “Hot Key”.
At the end of the data transfer phase the instrument displays the following messages:
“end “ for right programming.
“err” for failed programming. In this case push “SET” key if you want to restart the programming
again or remove the not programmed “Hot key”.
19. TECHNICAL DATA
CX660 keyboard
Housing: self extinguishing ABS.
Case: CX660 facia 35x77 mm; depth 18mm
Mounting: panel mounting in a 29x71 mm panel cut-out
Protection: IP20; Frontal protection: IP65
Power supply: from XM600K power module
Display: 3 digits, red LED, 14,2 mm high;
Optional output: buzzer
Power modules
Case: 8 DIN
Connections: Screw terminal block
1,6 mm2heat-resistant wiring and 5.0mm Faston
Power supply: depending on the model 12Vac –24Vac - 110Vac
10% - 230Vac
10% or 90÷230Vac
with switching power supply.
Power absorption: 9VA max.
Inputs: up to 6 NTC/PTC/Pt1000 probes
Digital inputs: 3 free of voltage
Relay outputs: Total current on loads MAX. 16A
Solenoid Valve: relay SPST 5(3) A, 250Vac
defrost: relay SPST 16 A, 250Vac
fan: relay SPST 8 A, 250Vac
light: relay SPST 16 A, 250Vac
alarm: SPDT relay 8 A, 250Vac
Aux: SPST relay 8 A, 250Vac
Valve output: a.c. output up to 30W (Only XM679K)
Optional output (AnOUT) DEPENDING ON THE MODELS:
PWM / Open Collector outputs: PWM or 12Vdc max 40mA
Analog output: 4÷20mA or 0÷10V
Serial output: RS485 with ModBUS - RTU and LAN
Data storing: on the non-volatile memory (EEPROM).
Kind of action: 1B. Pollution degree: 2 Software class: A. Operating temperature: 0÷60 °C.
Storage temperature: -25÷60 °C. Relative humidity: 20
85% (no condensing).
Measuring and regulation range:
NTC probe: -40÷110°C (-58÷230°F).
PTC probe: -50÷150°C (-67 ÷ 302°F)
Pt1000 probe: -100 ÷ 100°C (-148 ÷ 212°F)
Resolution: 0,1 °C or 1°C or 1 °F (selectable). Accuracy (ambient temp. 25°C): ±0,5 °C ±1 digit
20. DEFAULT SETTING VALUES
Lab
Val
Menù
Description
Range
SEt
2.0
- - -
Set point
LS - US
rtC
-
Pr1
CLOCK AND DEFROST menu
access
-
EEU
-
Pr1
Electro valve menu access
-
Regulation
Hy
2.0
Pr1
Differential
[0.1°C ÷ 25.5°C] [1°F ÷ 45°F]
Int
150
Pr1
Integral time for room temperature
regulation
0 ÷ 255 s
CrE
n
Pr1
Continuous regulation activation
n(0) –Y(1)
LS
-30
Pr2
Minimum set point
[-55.0°C ÷ SET] [-67°F ÷ SET]
US
20
Pr2
Maximum set point
[SET ÷ 150.0°C] [SET ÷ 302°F]
odS
0
Pr1
Outputs activation delay at start
up
0 ÷ 255 (min.)
AC
0
Pr1
Anti-short cycle delay
0 ÷ 60 (min.)
CCt
0.0
Pr2
Continous cycle duration
0 ÷ 24.0(144) (hour.10min)
CCS
2.0
Pr2
Continuous cycle set point
[-55.0°C ÷ 150,0°C] [-67°F ÷
302°F]
Con
15
Pr2
Compressor ON time with faulty
probe
0 ÷ 255 (min.)
CoF
30
Pr2
Compressor OFF time with faulty
probe
0 ÷ 255 (min.)
CF
°C
Pr2
Measurement unit: Celsius ,
Fahrenheit
°C(0) - °F(1)
PrU
rE
Pr2
Pressure Mode
rE(0) - Ab(1)
PMU
bAr
Pr2
Pressure measurement unit
bAr(0) –PSI(1) - MPA(2)
PMd
PrE
Pr2
Pressure displaying mode:
temperature or pressure
tEM(0) - PrE(1)
rES
dE
Pr2
Resolution (only °C) : decimal,
integer
dE(0) - in(1)
Lod
P1
Pr2
Local display: default display
nP(0) - P1(1) - P2(2) - P3(3) -
P4(4) - P5(5) - P6(6) –tEr(7) -
dEF(8)
rEd
P1
Pr2
Remote display: default display
nP(0) - P1(1) - P2(2) - P3(3) -
P4(4) - P5(5) - P6(6) –tEr(7) -
dEF(8)
dLy
0
Pr1
Display delay
0 ÷ 24.0(144) (Min.10s)
rPA
P1
Pr1
Regulation probe A
nP(0) - P1(1) - P2(2) - P3(3) -
P4(4) - P5(5)
rPb
nP
Pr1
Regulation probe B
nP(0) - P1(1) - P2(2) - P3(3) -
P4(4) - P5(5)
rPE
100
Pr1
Virtual probe percentage (room
temperature)
0 ÷ 100 (100=rPA, 0=rPb)
Electronic Expansion Valve
Fty
404
Pr1
Kind of gas
R22-134-290 - 404- 47A-47C- 47F
410-448-449-450- 507 -513-CO2
Atu
YES
Pr2
Minimum STABLE superheat
search
No; yES
AMS
YES
Pr2
Self self adaptive SH regulation
enabling
No; yES
SSH
8.0
Pr1
Superheat set point
[0.1°C ÷ 25.5°C] [1°F ÷ 45°F]
CyP
6
Pr1
Cycle Period
1 ÷ 15 s
Pb
5.0
Pr1
Proportional band for superheat
regulator
[0.1°C ÷ 60.0 °C] [1°F ÷ 108 °F]
rS
0.0
Pr1
Band Offset for superheat
regulator
[-12.0°C ÷ 12.0°C] [-12°C ÷
12°C] [-21°F ÷ 21°F]
inC
120
Pr1
Integration time for superheat
regulator
0 ÷ 255 s
PEO
50
Pr1
Probe error opening percentage
0 ÷ 100
PEd
On
Pr1
Probe error delay before stopping
regulation
0 ÷ 239 s - On(240)
OPE
85
Pr1
Start opening percentage
0 ÷ 100
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SFd
0.3
Pr1
Start function duration
0 ÷ 42.0(252) (min.10sec)
OPd
85
Pr1
Opening percentage after defrost
phase
0 ÷ 100
Pdd
0.3
Pr1
Post defrost function duration
0 ÷ 42.0(252) (min.10sec)
MnF
100
Pr1
Maximum opening percentage at
normale functioning
0 ÷ 100
dCL
0
Pr1
Delay before stopping valve
regulation
0 ÷ 255 s
Fot
nu
Pr1
Forced opening percentage
0 ÷ 100 - "nu"(101)
PA4
-0.5
Pr2
Probe value at 4 mA or at 0V
BAR : [PrM=rEL] -1.0 ÷ P20
[PRM=Abs] 0.0 ÷ P20
PSI : [PrM=rEL] -14 ÷ P20
[PRM=Abs] 0 ÷ P20
dKP : [PrM=rEL] -10 ÷ P20
[PRM=Abs] 0 ÷ P20
P20
11.0
Pr2
Probe value at 20 mA or at 5V
BAR : [PrM=rEL] PA4 ÷ 50.0
[PrM=AbS] PA4 ÷ 50.0
PSI : [PrM=rEL] PA4 ÷ 725
[PrM=AbS] PA4 ÷ 725
dKP : [PrM=rEL] PA4 ÷ 500
[PrM=AbS] PA4 ÷ 500
LPL
-0.5
Pr1
Lower pressure limit for superheat
regulation
PA4 ÷ P20
MOP
11.0
Pr1
Maximum operating pressure
threshold
LOP ÷ P20
LOP
-0.5
Pr1
Lowest operating pressure
threshold
PA4 ÷ MOP
dML
30
Pr1
Delta MOP-LOP opening variation
0 ÷ 100
MSH
80.0
Pr1
Maximum superheat alarm
threshold
[LSH ÷ 80,0°C] [LSH ÷ 144°F]
LSH
2.0
Pr1
Minimum superheat alarm
threshold
[0.0 ÷ MSH °C] [0 ÷ MSH °F]
SHy
2.0
Pr2
Superheat alarm hysteresis
[0.1°C ÷ 25.5°C] [1°F ÷ 45°F]
SHd
3.0
Pr1
Superheat alarm activation delay
0 ÷ 42.0(252) (min.10sec)
FrC
100
Pr1
Fast-recovery costant
0 ÷ 100
SUb
10
Pr2
Pressure filter
0÷100
SLb
5
Pr2
Reaction time
0÷255s
Defrost
dPA
P2
Pr1
Defrost probe A
nP(0) - P1(1) - P2(2) - P3(3) -
P4(4) - P5(5)
dPb
nP
Pr1
Defrost probe B
nP(0) - P1(1) - P2(2) - P3(3) -
P4(4) - P5(5)
dPE
100
Pr1
Virtual probe percentage (defrost
temperature)
0 ÷ 100 (100=dPA, 0=dPb)
tdF
EL
Pr1
Defrost type
EL(0) - in(0)
EdF
in
Pr1
Defrost mode: Clock or interval
rtc(0) - in(1)
Srt
150
Pr1
Heater set point during defrost
[-55.0°C ÷ 150°C] [-67°F ÷
302°F]
Hyr
2.0
Pr1
Differential for heater
[0.1°C ÷ 25.5°C] [1°F ÷ 45°F]
tod
255
Pr1
Time out for heater
0 ÷ 255 (min.)
dtP
0.1
Pr1
Minimum temperature difference
to start defrost
[0.1°C ÷ 50.0°C] [1°F ÷ 90°F]
ddP
60
Pr1
Delay before starting defrost
0 ÷ 60 (min.)
d2P
n
Pr1
Defrost with two probes
n(0) –Y(1)
dtE
8.0
Pr1
Defrost termination temperature
(Probe A)
[-55.0°C ÷ 50.0°C] [-67°F ÷
122°F]
dtS
8.0
Pr1
Defrost termination temperature
(Probe B)
[-55.0°C ÷ 50.0°C] [-67°F ÷
122°F]
idF
6
Pr1
Interval between defrosts
0 ÷ 120 (hours)
MdF
30
Pr1
Defrost Maximum duration
0 ÷ 255 (min.)
dSd
0
Pr1
Start defrost delay
0 ÷ 255 (min.)
dFd
it
Pr1
Display during defrost
rt(0) - it(1) - SEt(2) - dEF(3)
dAd
30
Pr1
Defrost display time out
0 ÷ 255 (min.)
Fdt
0
Pr1
Drain down time
0 ÷ 255 (min.)
dPo
n
Pr1
Defrost at start-up
n(0) –Y(1)
dAF
0.0
Pr1
Defrost delay after continuous
cycle
0 ÷ 24.0(144) (hours.10min)
Fan
FPA
P2
Pr1
Fan probe A
nP(0) - P1(1) - P2(2) - P3(3) -
P4(4) - P5(5)
FPb
nP
Pr1
Fan probe B
nP(0) - P1(1) - P2(2) - P3(3) -
P4(4) - P5(5)
FPE
100
Pr1
Virtual probe percentage (fan
management)
0 ÷ 100 (100=FPA, 0=FPb)
FnC
O-n
Pr1
Fan operating mode
C-n(0) - O-n(1) - C-y(2) - O-y(3)
Fnd
10
Pr1
Fan delay after defrost
0 ÷ 255 (min.)
FCt
10
Pr1
Temperature differential to avoid
short cycles of fans
[0.0°C ÷ 50.0°C] [0°F ÷ 90°F]
FSt
2.0
Pr1
Fan stop temperature
[-55.0°C ÷ 50.0°C] [-67°F ÷
122°F]
FHy
1.0
Pr1
Fan stop differential
[0.1°C ÷ 25.5°C] [1°F ÷ 45°F]
Fod
0
Pr1
Fan activation time after defrost
(without compressor)
0 ÷ 255 (min.)
Fon
0
Pr1
Fan ON time
0÷15 (min.)
FoF
0
Pr1
Fan OFF time
0÷15 (min.)
trA
UAL
Pr2
Kind of regulation for modulating
output
UAL(0) - rEG(1) - AC(2)
SOA
80
Pr2
Fixed speed for fan
AMi ÷ AMA
SdP
30.0
Pr2
Default Dew Point value
[-55.0°C ÷ 50.0°C] [-67°F ÷
122°F]
ASr
1.0
Pr2
Differential for fan / offset for anti
sweat heater
[-25.5°C ÷ 25.5°C] [-45°F ÷ 45°F]
PbA
5.0
Pr2
Proportional band for modulating
output
[0.1°C ÷ 25.5°C] [1°F ÷ 45°F]
AMi
0
Pr2
Minimum output for modulating
output
0 ÷ AMA
AMA
100
Pr2
Maximum output for modulating
output
AMi ÷ 100
AMt
3
Pr2
Time with fan at maximum speed
0 ÷ 255 s
Alarm
rAL
P1
Pr1
Probe for temperature alarm
nP(0) - P1(1) - P2(2) - P3(3) -
P4(4) - P5(5) - tEr(6)
ALC
Ab
Pr1
Temperature alarm configuration
rE(0) - Ab(1)
ALU
10
Pr1
High temperature alarm setting
[0.0°C ÷ 50.0°C o ALL ÷ 150.0°]
[0°F ÷ 90°F o ALL ÷ 302°F]
ALL
-30
Pr1
Low temperature alarm setting
[0.0°C ÷ 50.0°C o -55,0°C ÷
ALU] [0°F ÷ 90°F o -67°F ÷
ALU°F]
AHy
1.0
Pr1
Differential for temperature alarm
[0.1°C ÷ 25.5°C] [1°F ÷ 45°F]
ALd
15
Pr1
Temperature alarm delay
0 ÷ 255 (min.)
dLU
150
Pr2
High temperature alarm setting
(defrost probe)
[0.0°C ÷ 50.0°C o dLL ÷ 150.0°]
[0°F ÷ 90°F o dLL ÷ 302°F]
dLL
-55
Pr2
Low temperature alarm setting
(defrost probe)
[0.0°C ÷ 50.0°C o -55,0°C ÷
dLU] [0°F ÷ 90°F o -67°F ÷
dLU°F]
dAH
1.0
Pr2
Differential for temperature alarm
(defrost probe)
[0.1°C ÷ 25.5°C] [1°F ÷ 45°F]
ddA
15
Pr2
Temperature alarm delay (defrost
probe)
0 ÷ 255 (min.)
FLU
150
Pr2
High temperature alarm setting
(fan probe)
[0.0°C ÷ 50.0°C o FLL ÷ 150.0°]
[0°F ÷ 90°F o FLL ÷ 302°F]
FLL
-55
Pr2
Low temperature alarm setting
(fan probe)
[0.0°C ÷ 50.0°C o -55,0°C ÷
FLU] [0°F ÷ 90°F o -67°F ÷
FLU°F]
FAH
1.0
Pr2
Differential for temperature alarm
(fan probe)
[0.1°C ÷ 25.5°C] [1°F ÷ 45°F]
FAd
15
Pr2
Temperature alarm delay (fan
probe)
0 ÷ 255 (min.)
dAo
1.3
Pr1
Delay of temperature alarm at
start-up
0 ÷ 24.0(144) (hours.10min)
EdA
30
Pr1
Alarm delay at the end of defrost
0 ÷ 255 min
dot
15
Pr1
Temperature alarm exclusion after
door open
0 ÷ 255 min
Sti
nu
Pr2
Stop regulation interval
"nu"(0) ÷ 24.0(144)
(hour.10min)
Std
3
Pr2
Stop duration
1 ÷ 255 min
oA6
AUS
Pr2
Sixth relay output configuration
CPr(0) - dEF(1) - FAn(2) - ALr(3)
- LiG(4) - AUS(5) - db(6) -
OnF(7)
CoM
Cur
Pr2
Modulating output configuration
CUr(0) - tEn(1) - PM5(2) -
PM6(3) - oA7(4)
AOP
cL
Pr1
Alarm relay polarity
OP(0) - CL(1)
iAU
n
Pr1
Auxiliary output indipendent from
ON/OFF state
n(0) –Y(1)
Digital Inputs
i1P
cL
Pr1
Digital input 1 polarity
OP(0) - CL(1)
i1F
dor
Pr1
Digital input 1 configuration
EAL(0) - bAL(1) - PAL(2) - dor(3)
- dEF(4) - AUS(5) -LiG(6) -
OnF(7) - Htr(8) - FHU(9) -
ES(10) - Hdy(11)
d1d
15
Pr1
Digital input 1 activation delay
0 ÷ 255 (min.)
i2P
cL
Pr1
Digital input 2 polarity
OP(0) - CL(1)
i2F
LiG
Pr1
Digital input 2 configuration
EAL(0) - bAL(1) - PAL(2) - dor(3)
- dEF(4) - AUS(5) -LiG(6) -
OnF(7) - Htr(8) - FHU(9) -
ES(10) - Hdy(11)
d2d
5
Pr1
Digital input 2 activation delay
0 ÷ 255 (min.)
i3P
cL
Pr1
Digital input 3 polarity
OP(0) - CL(1)
i3F
ES
Pr1
Digital input 3 configuration
EAL(0) - bAL(1) - PAL(2) - dor(3)
- dEF(4) - AUS(5) -LiG(6) -
OnF(7) - Htr(8) - FHU(9) -
ES(10) - Hdy(11)
d3d
0
Pr1
Digital input 3 activation delay
0 ÷ 255 (min.)
nPS
15
Pr1
Number of pressure switch
activation before lock
0 ÷ 15
OdC
F-C
Pr1
Compressor and fan status when
open door
no(0) - FAn(1) - CPr(2) - F-C(3)
rrd
30
Pr1
Outputs restart after door open
alarm
0 ÷ 255 (min.)
1592023130 XM670K_XM679K GB r4.2 26.06.2017.docx XM670K - XM679K 10/10
Clock
CbP
Y
Pr1
Clock presence
n(0) –Y(1)
Hur
- - -
Pr1
Current hour
- - -
Min
- - -
Pr1
Current minutes
- - -
dAY
- - -
Pr1
Current day
Sun(0) - SAt(6)
Hd1
nu
Pr1
First weekly day
Sun(0) - SAt(6) - nu(7)
Hd2
nu
Pr1
Second weekly day
Sun(0) - SAt(6) - nu(7)
Hd3
nu
Pr1
Third weekly day
Sun(0) - SAt(6) - nu(7)
ILE
0.0
Pr1
Energy saving cycle start during
workdays
0 - 23.5(143) (hours.10min)
dLE
0.0
Pr1
Energy saving cycle length during
workdays
0 ÷ 24.0(144) (hours.10min)
ISE
0.0
Pr1
Energy saving cycle start during
holidays
0 - 23.5(143) (hours.10min)
dSE
0.0
Pr1
Energy saving cycle length during
holidays
0 ÷ 24.0(144) (hours.10min)
HES
0.0
Pr1
Temperature increasing during
Energy Saving cycle
[-30.0°C ÷ 30.0°C] [-54°F ÷ 54°F]
Ld1
nu
Pr1
Workdays First defrost start
0.0 ÷ 23.5(143) - nu(144)
(hours.10min)
Ld2
nu
Pr1
Workdays Second defrost start
Ld1 ÷ 23.5(143) - nu(144)
(hours.10min)
Ld3
nu
Pr1
Workdays Third defrost start
Ld2 ÷ 23.5(143) - nu(144)
(hours.10min)
Ld4
nu
Pr1
Workdays Fourth defrost start
Ld3 ÷ 23.5(143) - nu(144)
(hours.10min)
Ld5
nu
Pr1
Workdays Fifth defrost start
Ld4 ÷ 23.5(143) - nu(144)
(hours.10min)
Ld6
nu
Pr1
Workdays Sixth defrost start
Ld5 ÷ 23.5(143) - nu(144)
(hours.10min)
Sd1
nu
Pr1
Holidays First defrost start
0.0 ÷ 23.5(143) - nu(144)
(hours.10min)
Sd2
nu
Pr1
Holidays Second defrost start
Sd1 ÷ 23.5(143) - nu(144)
(hours.10min)
Sd3
nu
Pr1
Holidays Third defrost start
Sd2 ÷ 23.5(143) - nu(144)
(hours.10min)
Sd4
nu
Pr1
Holidays Fourth defrost start
Sd3 ÷ 23.5(143) - nu(144)
(hours.10min)
Sd5
nu
Pr1
Holidays Fifth defrost start
Sd4 ÷ 23.5(143) - nu(144)
(hours.10min)
Sd6
nu
Pr1
Holidays Sixth defrost start
Sd5 ÷ 23.5(143) - nu(144)
(hours.10min)
Energy Saving
ESP
P1
Pr1
Energy saving probe selection
nP(0) - P1(1) - P2(2) - P3(3) -
P4(4) - P5(5) - tEr(6)
HES
0.0
Pr1
Temperature increasing during
Energy Saving
[-30.0°C ÷ 30.0°C] [-54°F ÷ 54°F]
PEL
n
Pr1
Energy saving activation when
Light switched off
n(0) –Y(1)
L.A.N. Management
LMd
y
Pr2
Defrost Synchronisation
n(0) –Y(1)
dEM
y
Pr2
Defrost end Synchronisation
n(0) –Y(1)
LSP
n
Pr2
SET-POINT Synchronisation
n(0) –Y(1)
LdS
n
Pr2
Display Synchronisation
(temperature sent via LAN)
n(0) –Y(1)
LOF
n
Pr2
ON/OFF Synchronisation
n(0) –Y(1)
LLi
y
Pr2
Light Synchronisation
n(0) –Y(1)
LAU
n
Pr2
AUX Synchronisation
n(0) –Y(1)
LES
n
Pr2
Energy Saving Synchronisation
n(0) –Y(1)
LSd
n
Pr2
Remote probe displaying
n(0) –Y(1)
LPP
n
Pr2
Pressure value sent in LAN
n(0) –Y(1)
StM
n
Pr2
Cooling request from LAN enable
compressor relay
n(0) –Y(1)
Probe Configurations
P1C
NtC
Pr2
P1 configuration
nP(0) - Ptc(1) - ntc(2) - PtM(3)
ot
0.0
Pr2
P1 calibration
[-12,0°C ÷ 12,0°C] [-21°F ÷
21°F]
P2C
NtC
Pr2
P2 configuration
nP(0) - Ptc(1) - ntc(2) - PtM(3)
oE
0.0
Pr2
P2 calibration
[-12,0°C ÷ 12,0°C] [-21°F ÷
21°F]
P3C
NtC
Pr2
P3 configuration
nP(0) - Ptc(1) - ntc(2) - PtM(3)
o3
0.0
Pr2
P3 calibration
[-12,0°C ÷ 12,0°C] [-21°F ÷
21°F]
P4C
NtC
Pr2
P4 configuration
nP(0) - Ptc(1) - ntc(2) - PtM(3)
o4
0.0
Pr2
P4 calibration
[-12,0°C ÷ 12,0°C] [-21°F ÷
21°F]
P5C
420
Pr2
P5 configuration
nP(0) - Ptc(1) - ntc(2) - PtM(3) -
420(4) - 5Vr(5)
o5
0.0
Pr2
P5 calibration
[-12,0°C ÷ 12,0°C] [-21°F ÷
21°F]
P6C
PtM
Pr2
P6 configuration
nP(0) - Ptc(1) - ntc(2) - PtM(3)
o6
0.0
Pr2
P6 calibration
[-12,0°C ÷ 12,0°C] [-21°F ÷
21°F]
Service
CLt
- - -
Pr1
ON/OFF percentage (C.R.O.)
(read only)
tMd
- - -
Pr1
Time remaining before next
defrost activation (only for interval
defrost)
(read only)
LSn
- - -
Pr1
Number of devices in LAN
1 ÷ 8 (read only)
LAn
- - -
Pr1
List of address of LAN devices
1 ÷ 247 (read only)
Other
Adr
1
Pr1
Modbus address
1 ÷ 247
rEL
4.2
Pr1
Firmware release
(read only)
Ptb
-
Pr1
Parameter table
(read only)
Pr2
- - -
Pr1
PR2 menu access
(read only)
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