NOVUS N1040T Temperature Controller User Manual
- June 8, 2024
- Novus
Table of Contents
- NOVUS N1040T Temperature Controller
- SAFETY ALERTS
- INSTALLATION / CONECTIONS
- FEATURES
- TIMERS
- OPERATION
- DESCRIPTION OF THE PARAMETERS
- CONFIGURATION PROTECTION
- DETERMINATION OF PID PARAMETERS
- SPECIFICATIONS
- IDENTIFICATION
- MAINTENANCE
- WARRANTY
- References
- Read User Manual Online (PDF format)
- Download This Manual (PDF format)
NOVUS N1040T Temperature Controller
SAFETY ALERTS
The symbols below are used on the equipment and throughout this document to draw the user’s attention to important operational and safety information.
|
---|---
CAUTION:
Read the manual thoroughly before installing and operating
the equipment.
|
CAUTION OR DANGER:
Electrical shock hazard
All safety related instructions that appear in the manual must be observed to ensure personal safety and to prevent damage to either the instrument or the system. If the instrument is used in a manner not specified by the manufacturer, the protection provided by the equipment may be impaired.
INSTALLATION / CONECTIONS
The controller must be fastened on a panel, following the sequence of steps described below:
- Prepare a panel cut-out according Specifications;
- Remove the mounting clamps from the controller;
- Insert the controller into the panel cut-out;
- Slide the mounting clamp from the rear to a firm grip at the panel.
ELECTRICAL CONNECTIONS
below shows the electrical terminals of the controller:
RECOMMENDATIONS FOR THE INSTALLATION
- All electrical connections are made to the screw terminals at the rear of the controller.
- To minimize the pick-up of electrical noise, the low voltage DC connections and the sensor input wiring should be routed away from high-current power conductors. If this is impractical, use shielded cables. In general, keep cable lengths to a minimum.
- All electronic instruments must be powered by a clean mains supply, proper for instrumentation.
- It is strongly recommended to apply RC’S FILTERS (noise suppressor) to contactor coils, solenoids, etc. In any application it is essential to consider what can happen when any part of the system fails. The controller features by themselves cannot assure total protection.
FEATURES
INPUT TYPE SELECTION
Table 01 shows the sensor types accepted and their respective codes and
ranges. Access the parameter TYPE in the INPUT cycle to select the appropriate
sensor
TYPE | CODE | RANGE OF MEASUREMENT |
---|---|---|
Thermocouple J | Tc j | Range: -110 to 950 °C (-166 to 1742 °F) |
Thermocouple K | Tc k | Range: -150 to 1370 °C (-238 to 2498 °F) |
Thermocouple T | Tc t | Range: -160 to 400 °C (-256 to 752 °F) |
Pt100 | Pt | Range: -200 to 850 °C (-328 to 1562 °F) |
DIGITAL INPUT (DIG IN)
Available at terminals 15th and 16th on the back panel of the controller.
Detects the closing of dry contact switches. The A3 indicator lamp shows the
condition of the Digital Input:
- On = DI Actioned (contact closed)
- Off = DI Not Actioned (contact open)
OUTPUTS
The controller offers two or four output channels, depending on the loaded
optional features. The output channels are user configurable as Control
Output, Output Timers (T1), Output Timers (T2), Alarm Output 4.
- OUT1 – Pulse type output of electrical voltage, 5 Vdc / 50 mA max. Available on terminals 4 and 5 of the controller.
- OUT2 – Relay SPST-NA. Available at terminals 6 and 7.
- OUT3 – Relay SPST-NA. Available at terminals 13 and 14.
- OUT4 – Relay SPDT, available at terminals 10, 11 and 12.
TEMPERATURE CONTROL OUTPUT
The process control output can operate in ON/OFF mode or in PID mode. To
operate in ON/OFF, mode the value defined in the parameter PB should be 0.0.
The control strategy can be ON/OFF (when PB = 0.0) or PID. The PID parameters
can be automatically determined enabling the auto-tuning function (ATvN).
ALARM OUTPUT
The controller has an alarm that can be configured to operate on any of the
output channels. It can be configured to operate in one of the different
functions as detailed in Table 02.
Important note : Alarms configured with the ki, dif, and difk functions also trigger their associated output when a sensor fault is identified and signaled by the controller. A relay output, for example, configured to act as a High Alarm (ki,), will operate when the SPAL value is exceeded and also when the sensor connected to the controller input is broken.
INITIAL BLOCKING OF ALARM
The option to Block initial alarms inhibits the alarms in the case that there
is an alarm condition present on startup. The alarm will be enabled only after
the occurrence of a non-alarm condition. Initial Blocking is useful, for
example, in the initialization of process control operations when the value of
the PV is still far from the SP value. Hence the system waits for alarm
situations and unwanted alarms are avoided. The initial blocking is disabled
for the sensor break alarm function ierr.
OFFSET
Allows fine adjustments to the PV reading for compensation of sensor error.
Offset allows measurements errors to be corrected when the occur, for example
after the substitution of a temperature sensor.
FUNCTION LBD – LOOP BREAK DETECTION
The parameter defines a time interval, in minutes, within which the PV is
expect to react to a control output signal. If the PV does not react properly
within the time interval configured in lbd.t, the controller interprets this
as a control loop break and signals this occurrence in the display. If the
lbd.t parameter is set to 0 (zero) then this function is disabled. This
function allows the user to detect problems in the installation, for example
an actuator with a defect, a failure of supply power, etc. A LBD event may be
sent to any output channel. Simply configure the LDB function to the desired
output channel (OUT1 or OUT2): the selected output will be activated when a
LDB condition is detected. When the Lbd.t parameter is programmed with 0
(zero), the LDB function is disabled. The LBD is useful in detecting system
failures, such us defective sensors or actuators, loads and power supply,
among others.
SAFE OUTPUT VALUE WITH SENSOR FAILURE
This function defines an output value (user defined) to be assigned to the
control output in the event of a sensor failure. When the input sensor is
identified as broken, the controller switches the control mode to MANUAL while
forcing MV to assume the user configured value in the 1E.ov parameter. This
function requires that one of the alarms be configured as 1Err and the 1E.ov
parameter (control output percentage) programmed with a value other then 0
(zero). Once this function is triggered, the controller remains in SAFE mode
(MANUAL control output) even after the sensor failure appears to be fixed. The
operator intervention is required for switching back to AUTO mode. 1E.ov
values are only 0 and 100 % when in ON/OFF control mode. For PID control mode
any value in the range from 0 to 100 % is accepted.
USB INTERFACE
The USB interface is used to CONFIGURE, MONITOR or UPDATE the controller
FIRMWARE. The user should use QuickTune software, which offers features to
create, view, save and open settings from the device or files on the computer.
The tool for saving and opening configurations in files allows the user to
transfer settings between devices and perform backup copies. For specific
models, QuickTune allows to update the firmware (internal software) of the
controller via the USB interface. For MONITORING purposes, the user can use
any supervisory software (SCADA) or laboratory software that supports the
MODBUS RTU communication over a serial communication port. When connected to a
computer’s USB, the controller is recognized as a conventional serial port
(COM x). The user must use QuickTune software or consult the DEVICE MANAGER on
the Windows Control Panel to identify the COM port assigned to the controller.
The user should consult the mapping of the MODBUS memory in thecontroller’s
communication manual and the documentation of the supervision software to
start the MONITORING process. Follow the procedure below to use the USB
communication of the device:
- Download QuickTune software from our website and install it on the computer. The USB drivers necessary for operating the communication will be installed with the software.
- Connect the USB cable between the device and the computer. The controller does not have to be connected to a power supply. The USB will provide enough power to operate the communication (other device functions may not operate).
- Run the QuickTune software, configure the communication and start the device recognition
The USB interface IS NOT SEPARATE from the signal input (PV) or the controller’s digital inputs and outputs. It is intended for temporary use during CONFIGURATION and MONITORING periods. For the safety of people and equipment, it must only be used when the piece of equipment is completely disconnected from the input/output signals. Using the USB in any other type of connection is possible but requires a careful analysis by the person responsible for installing it. When MONITORING for long periods of time and with connected inputs and outputs, we recommend using the RS485 interface
TIMERS
This controller contains two timers that can operate independently of the control output.
T1 TIMER
The T1 timer is the main timer. Its time interval is defined in minutes:
seconds (MM:SS) and allows various operating modes:
There are four starting modes for T1
- RUN T1 starts when the control outputs are enabled (RUN= YES). SP T1 starts when the PV value reaches the SP value.
- F starts upon pressing the F key. Once the timer is initiated, pressing again the F key stops and resets the timer. Pressing the F key once more, a new timer cycle takes place.
- DI T1 starts upon command of the Digital Input (dry contact). The timer is triggered on a high signal from the
- DI (closed contact) and the timing starts. If the DI goes low (open contact) before the end of the timer, the timer is interrupted and a new cycle will start when a new high signal is received on the DI. Releasing the Digital Input while the timer is running causes T1 to stop and reset. Closing again the Digital Input initiates a new timer cycle.
Note: If the run parameter has been manually set to NO (control disabled), the options to trigger via the F key and DI do not permit the reactivation of control (RUN= YES). If RUN=NO (control output disabled), the timer remains disabled regardless of the F key and Digital Input commands.
Operating Modes of Timer T1
The T1 timer has three different modes of operation. The modes of operation
define the behavior of the outputs associated with the timer. The T1 timer can
be associated to any of the outputs OUT1, OUT2, OUT3 and OUT4, whose behavior
can be configured to work in three distinct modes:
- off The output of T1 is turned Off the end of T1. Output turns on when timer starts and turns off when the time defined in T1 has elapsed. The A1 sign remains lit while the timer is running and flashes after the T1 interval is completed.
- On The output of T1 is turned On at the end of T1. Output remains off during the timer interval and turns on at its end, remaining so until the start of a new timer cycle. The A1 sign flashes during the whole timer duration and it is turned on continuously after the timer is elapsed, indicating that the Output is ON.
- On.x The output of T1 Stays On at the end of T1. Output is turned on at the beginning of the timer cycle and remains in this state even after the timer has elapsed. The A1 sign is lit during the time counting and flashes at the end of the temporization, indicating that the output is ON.
T2 TIMER
T2 is the secondary timer and is activated at the end of T1. The T2 output can
be associated to any free controller output. This output remains ON during the
whole T2 duration. The indicator A2 indicates the condition of timer T2: T2 is
running, A2 is on. T2 has not started or has already finished, A2 is off.
UP/DOWN TIMER COUNTING
Both timers can be configured to display the counting in incrementing (UP) or
decrementing (DOWN) modes. In UP mode, the counting starts at zero and counts
up until the time setting is reached. In DOWN mode, the display starts showing
the time setting and counts down to zero.
TEMPERATURE CONTROL OUTPUT DURING TIMER OPERATION
During the T1 and T2 operation the control output works normally. However, the
behavior of the control output can be configured to stop after the time T1 +
T2 has elapsed, forcing RUN=NO. See the description of the parameter T.E.(.0.
in the timing cycle of the controller.
TIME BASE OF THE TIMERS
The parameter TBAS at the end of the timing cycle defines the time base that
will be used. The options are:
- Sec MM : SS. The intervals of T1 and T2 are presented in minutes and seconds.
- Min HH: MM. The intervals of T1 and T2 are presented in hours and minutes
OPERATION
The controller’s front panel, with its parts, can be seen in the
- Display : Shows the measured variable, symbols of the configuration parameters and their values / conditions.
- TUNE Indicator : Stays ON while the controller is in tuning process.
- RUN Indicator: Controller On.
- OUT Indicator : For relay or pulse control output; it reflects the actual state of the output.
- Indicator A1 : Indicates the T1 Timer Output Condition.
- Indicator A2 : Indicates the T2 Timer Output Condition.
- Indicator A3 : Indicates the Digital Input Condition.
- Indicator A4 : Indicates the Alarm 4 status.
- Key : Used to walk through the menu parameters.
- Increment key and – Decrement key : Allow altering the values of the parameters.
- Key: Key used to move backwards the parameter list during setup.
STARTUP
When the controller is powered up, it displays its firmware version for 3
seconds, after which the controller starts normal operation. The value of PV
and SP is then displayed and the outputs are enabled. . It is in the lower
display that the value of SP is displayed. This is the Indication Screen. In
order for the controller to operate properly in a process, its parameters need
to be configured first, such that it can perform accordingly to the system
requirements. The user must be aware of the importance of each parameter and
for each one determine a valid condition. The parameters are grouped in levels
according to their functionality and operation easiness. Operation / Tuning /
Timers / Alarms / Input / Calibration The “P” key is used for accessing the
parameters within a level. Keeping the “P” key pressed, at every 2 seconds the
controller jumps to the next level of parameters, showing the first parameter
of each level: PV >> atvn >> t1 >> fva4 >> type >> pass >> PV … To enter the
desired cycle, just drop the P key as its first parameter show up. To move
forward on the parameters of this cycle, use the P key with short touches. At
the end of each cycle, the controller returns the Indication Screen. Each
parameter has its symbol on the upper display while its value / condition is
on the lower display.
DESCRIPTION OF THE PARAMETERS
OPERATION CYCLE
PV + SP| PV Indication screen. On the higher display (red) the value of
the measured variable (PV) temperature is shown. On the lower display (green),
the control setpoint (SP) is shown.
---|---
PV + TM| Display PV and decreasing time. The upper display (red)
shows the measured temperature value (PV).
In the lower display (green) the current count of the timer defined as Timer 1 is displayed. You cannot set this display.
T1
Timer 1
| Set the T1 time interval. From 00:00 to 99:59 (HH:MM or MM:SS).
Parameter showed in this cycle when defined in T.en.
SP.A4| Alarm SP: Value that defines the point of activation of the alarm outputs. For the alarms programmed with the functions of the type Differential , these parameters represent the deviations.
Parameter shown in this level only when enabled in the parameter sp4.e.
Rvn
Run
| Display for enable or disable the controller’s action on the process. It acts like a switch, turning the controller on or off.
YES Outputs enabled
NO Output disabled
Parameter showed in this cycle when defined in
rvn.e.
TUNING CYCLE
Atvn
Auto-tune
| AUTO-TUNE : enables the auto-tuning function for the PID parameters ( pb , ir , dt ). Consult the chapter Determination of PID Parameters in this manual and on the website www.novusautomation.com for more details. Defines the control strategy to be taken:
off – Turned off. (no PID tuning)
Fast – Automatic tuning.
Fv11 – More accurate automatic tuning.
---|---
PB
Proportional Band
| Proportional Band – Value of the term P of the control mode PID, in percentage of the maximum span of the input type. Adjust of between 0 and 500.0 %.
When set to zero (0), control action is ON/OFF.
ir
Integral Rate
| Integral Rate – Value of the term I of the PID algorithm, in
repetitions per minute (Reset). Adjustable between 0 and 24.00. Displayed only
if proportional band ¹ 0.
dt
Derivative Time
| Derivative Time – Value of the term D of the control mode PID, in
seconds. Adjustable between 0 and 250 seconds. Displayed only if proportional
band ¹ 0.
---|---
(t
Cycle Time
| Cycle time: Pulse Width Modulation (PWM) period in seconds. Adjustable between 0.5 and 100.0 seconds.
Displayed only if proportional band ¹ 0.
kyst
Hysteresis
| Control hysteresis: Is the hysteresis for ON/OFF control. This parameter is only used when the controller is in ON/OFF mode. Adjustable between 0 and the bandwidth of measurement of the input type selected.
Displayed only if proportional band Pb = 0.
A(t
Action
| Action Control:
re Control with Reverse Action. Appropriate for heating. Turns control output on when PV is below SP.
dir Control with Direct Action. Appropriate for cooling. Turns control output on when PV is above SP.
sfst
Softstart
| Soft Start Function – Time interval, in seconds, while the controller limits the control output (MV) rising rate. From 0 to 9999 s.
(Zero value disables the Soft Start function).
0vt1 0vt2 0vt3 0vt4| Assign functions to the Output channels OUT1, OUT2, OUT3 e OUT4:
O f f **** Not used.
(trl Acts as a temperature controller. Control output.
a4 Alarm 4 output.
Lbd Acts as an output for the LBD function.
Loop Break Detect Alarm.
t1 T1 timer output.
t2 T2 timer output.
TIMER CYCLE
T1 | T1 time interval setting, 00:00 to 99:59 (MM:SS or HH:MM). |
---|
T.en
Timer Enable
| Allows the display of the T1 parameter in the main (operating) cycle.
Yes Shows T1 in the operating cycle.
no Hides T1 from the operating cycle.
T.dir| Counting direction of T1 timer.
up – Up counting, starting from zero.
Dn – Down counting.
T.str
Timer Start
| Defines starting mode for T1 timer.
di Starts and resets timer through the Digital Input.
f Starts, stops and resets timer using the F
key.
sP When PV reaches SP
Rvn By toggling run to YES
T.end
Timer End
| Output behavior of T1 timer:
off Output is turned off at the end of the time interval.
On Output is turned on at the end of the time interval
On.x Output remains on after the timer has elapsed.
T.e.(.0
Timer End Control Off ?
| Control output behavior after the interval T1 + T2.
yes Control output is deactivated at the end of the timer (RUN= no). Control output is disabled.
no Control output remains active.
T2
Timer 2
| T2 time interval setting, 00:00 to 99:59 (MM:SS or HH:MM). T2 is
activated at the end of T1. Interval of time where the output T2
remains on after the end of timer T1.
---|---
tbas
time base
| Time base for the timers T1 and T2.
Min Hours and Minutes (HH:MM)
Sec Minutes and Seconds (MM:SS)
ALARMS CYCLE
Fva4
Function
Alarm
| Functions of Alarms. Defines the functions for the alarms among the options
of the Table 02.
---|---
Sp.a4| Alarm SP: Value that defines the point of activation of the alarm
outputs.
For the alarms programmed with the functions of the type Differential , these parameters represent the deviations.
For the ierr alarm function, this parameter has no meaning.
Sp4.e| SP Enable. Configures display of SP.A4 also in the Operation Cycle.
YES – SP.A4 is displayed in the Operation Cycle.
NO – SP.A4 is not displayed in the Operation Cycle.
Bla4
Blocking Alarm
| Initial Blocking of Alarm 4. Blocking Alarms.
YES Enables initial blocking
NO Inhibits initial blocking
Xya4
Hysteresis of Alarm
| Alarm Hysteresis. Defines the difference between the value of PV at which
the alarm is triggered and the value at which it is turned off.
flsh
Flash
| Allows visual signalization of an alarm occurrence by flashing the indication of PV in the operation level.
YES Enables alarm signaling flashing PV
NO Disables alarm signaling flashing PV
INPUT CYCLE
Type
Type
| Input Type: Selects the input signal type to be connected to the process variable input.
J: Tc J -110 to 950 ºC / -166 to 1742 ºF
K: Tc k -150 to 1370 ºC / -238 to 2498 ºF
T: Tc t -160 to 400 ºC / -256 to 752 ºF
Pt100: Pt -200 to 850 ºC / -328 to 1562 ºF
---|---
fltr
Filter
| Digital Input Filter – Used to improve the stability of the measured signal
(PV). Adjustable between 0 and 20. In 0 (zero) it means filter turned off and
20 means maximum filter. The higher the filter value, the slower is the
response of the measured value.
Dp.po
Decimal Point
| Selects the decimal point position to be viewed in both PV and SP.
vn i t
Unit
| Selects display indication for degrees Celsius or Fahrenheit:
° f Indication in Fahrenheit.
° ( Indication in Celsius.
0ffs
Offset
| Parameter that allows the user to make adjustments to the PV value indicated.
Sensor Offset: Offset value to be added to the PV reading to compensate sensor error. Default value: zero.
Spll
SP Low Limit
| Defines the SP lower limit of.
Spxl
SP High Limit
| Defines the upper limit for adjustment of SP.
Lbd.t
Loop break detection time
| Time interval for the LBD function. Defines the maximum interval of time
for the PV to react to a control command. In minutes.
---|---
1e.ov| Percentage value to be applied to the output on any failure of
the sensor that is connected to the controller input.
CALIBRATION CYCLE
All types of input are calibrated in the factory. In case a recalibration is
required; it shall be carried out by a specialized professional. In case this
cycle is accidentally accessed, do not perform alteration in its parameters.
pass| Password. This parameter is presented before the protected cycles.
See item Protection of Configuration.
---|---
(alib| Calibration . Enables the possibility for calibration of the
indicator. When the calibration is not enabled, the related parameters are
hidden.
inL(| Input Low Calibration . Enter the value corresponding to the low
scale signal applied to the analog input.
ink(| Input High Calibration . Enter the value corresponding to the
full scale signal applied to the analog input.
rstr| Restores the factory calibration of the input, discarding all
alterations made by the user.
(j| Cold Junction. Temperature of the Cold Junction of the controller.
This screen is for information purpose only.
Pas.(| Password Change. Allows defining a new access password, always
different from zero.
Prot| Protection. Sets up the Level of Protection. See Table 04.
Rvn.e
RUN Enable
| Shows the parameter RUN (rvn) also in the Operation Cycle.
Yes Releases RUN for the operation cycle
no Does not release RUN for the operation cycle
Rvn
Run
| Display for enable or disable the controller’s action on the process. It acts like a switch, turning the controller on or off.
YES Outputs enabled
NO Output disabled
Snk
Serial Number
| Shows the first four digits electronic serial number of the controller.
Snl
Serial Number
| Shows the last four digits electronic serial number of the controller.
CONFIGURATION PROTECTION
The controller provides means for protecting the parameters configurations, not allowing modifications to the parameters values, avoiding tampering or improper manipulation. The parameter Protection (PROt), in the Calibration level, determines the protection strategy, limiting the access to particular levels, as shown by the Table 04..
PROTECTION LEVEL | PROTECTION LEVELS |
---|---|
1 | Only the Calibration level is protected. |
2 | Calibration and Input levels are protected. |
3 | Calibration, Input and Alarms levels are protected. |
4 | Calibration, Input, Alarms and Tuning levels are protected. |
5
| Tuning cycles, Timers, Alarming, Input and Calibration are protected. All
levels are protected, but the SP screen in the operation level.
---|---
6| All levels are protected, including SP.
ACESS PASSWORD
The protected levels, when accessed, request the user to provide the Access
Password for granting permission to change the configuration of the parameters
on these levels. The access password is entered in the parameter PASS that is
show in the first protected cycle. The prompt PASS precedes the parameters on
the protected levels. If no password is entered, the parameters of the
protected levels can only be visualized. The Access Password is defined by the
user in the parameter Password Change (PAS.(), present in the Calibration
Level. The factory default for the password code is 1111.
PROTECTION ACCESS PASSWORD
The controller provides a system of security that helps to prevent the
entering of many passwords in the hope of finding the correct one. The
protection system built into the controller blocks for 10 minutes the access
to protected parameters after 5 consecutive incorrect attempts at guessing the
correct password.
MASTER PASSWORD
The Master Password is intended for allowing the user to define a new password
in the event of it being forgotten. The Master Password doesn’t grant access
to all parameters, only to the Password Change parameter (PAS(). After
defining the new password, the protected parameters may be accessed (and
modified) using this new password. The master password is made up by the last
three digits of the serial number of the controller added to the number 9000.
As an example, for the equipment with serial number 07154321, the master
password is 9 3 2 1. Controller serial number is displayed by pressing for 5
seconds.
DETERMINATION OF PID PARAMETERS
During the process of determining automatically the PID parameters, the system is controlled in ON/OFF in the programmed Setpoint. The auto-tuning process may take several minutes to be completed, depending on the system. The steps for executing the PID autotuning are:
- Adjust the desired SP of the process. Select the process Setpoint.
- Enable auto-tuning at the parameter Atvn, selecting FAST or FULL.
The option FAST performs the tuning in the minimum possible time, while the option FULL gives priority to accuracy over the speed. During automatic tuning the indicator TUNE remains lit on the faceplate of the controller. The sign TUNE remains lit during the whole tuning phase. The user must wait for the tuning to be completed before using the controller. During the execution of automatic tuning, PV oscillations can be introduced into the process around the setpoint. During auto tuning period the controller will impose oscillations to the process. PV will oscillate around the programmed set point and controller output will switch on and off many times. If the tuning does not result in a satisfactory control, refer to Table 05 for guidelines on how to correct the behavior of the process.
PARAMETER | VERIFIED PROBLEM | SOLUTION |
---|
Band Proportional
| Slow answer| Decrease
Great oscillation| Increase
Rate Integration
| Slow answer| Increase
Great oscillation| Decrease
Derivative Time
| Slow answer or instability| Decrease
Great oscillation| Increase
For further details on PID tuning, visit our web site: www.novusautomation.com
SPECIFICATIONS
- DIMENSION: …………………………………….. 48 x 48 x 80 mm (1/16 DIN)
- Cutout in the panel: …………………. 45.5 x 45.5 mm (+0.5 -0.0 mm)
- Approximate weight: ……………………………………………………….75 g
- POWER SUPPLY: ……………….100 to 240 Vac (50/60 Hz) / 48 to 240 Vdc / ±10 %
- Optional 24 V: ………………. 12 to 24 Vdc / 24 Vac (-10 % / +20 %)
- Maximum consumption: ……………………………………………….. 6 VA
- ENVIRONMENTAL CONDITIONS: Operation temperature: ………………………………………… 0 to 50 °C
- Relative humidity: …………………………………………… 80 % @ 30 °C
- For temperatures above 30 °C, reduce 3 % for each °C
- Internal use; Category of installation II, Degree of pollution 2; altitude < 2000 meters.
- INPUT: Accepted types: ………………………………………….. J, K, T and Pt100
- Internal resolution: ………………………………… 32767 levels (15 bits)
- Resolution of display: ……………………………………. 0.1 / 1 (°C / °F)
- Rate of input reading: ……………………………… up 10 per second (*)
- Accuracy: ……. Thermocouples J, K, T: 0.25 % of the span ±1 °C ………………………………………….. Pt100: 0.2 % of the span ±0.1 °C
- Input impedance: ……………………………………………………. > 10 MΩ
- Measurement of Pt100: ……………………. 3-wire type, (α=0.00385)
- With compensation for cable length, excitation current of 0.170 mA.
- (*) Value adopted when the Digital Filter parameter is set to 0
- (zero) value. For Digital Filter values other than 0, the Input Reading Rate value is 5 samples per second.
- DIGITAL INPUT (DIG IN): …………….. dry contact / open collector NPN
- OUT1: ………………………………….. Voltage pulse, 5 V / 50 mA max.
- OUT2: ………………………….. Relay SPST; 1.5 A / 240 Vac / 30 Vdc
- OUT3: ………………………….. Relay SPST; 1.5 A / 240 Vac / 30 Vdc
- OUT4: …………………………….. Relay SPDT; 3 A / 240 Vac / 30 Vdc
- FRONT PANEL: ……………………. IP65, Polycarbonate (PC) UL94 V-2
- ENCLOSURE: ………………………………………. IP30, ABS+PC UL94 V-0
SPECIFIC CONNECTIONS FOR TYPE FORK TERMINALS; PROGRAMABLE CYCLE OF PWM: FROM 0.5 UP 100 SECONDS; STARTS UP OPERATION: after 3 seconds connected to the power supply. CERTIFICATIONS: CE, UKCA and UL.
IDENTIFICATION
N1040T-PRRR| Standard Model.
Power supply 100~240 Vac / 48~240 Vdc
---|---
N1040T-PRRR-24V| Version with power supply 12~24 Vdc / 24 Vac
MAINTENANCE
PROBLEMS WITH THE CONTROLLER
Connection errors and inadequate programming are the most common errors found
during the controller operation. A final revision may avoid loss of time and
damages. The controller displays some messages to help the user identify
problems.
MESSAGE | DESCRIPTION OF THE PROBLEM |
---|---|
—- | Open input. No sensor or signal. |
Err1 Err6 | Connection and/or configuration problems. Check the wiring |
and the configuration.
Other error messages may indicate hardware problems requiring maintenance service.
INPUT CALLIBRATION
All inputs are factory calibrated and recalibration should only be done by
qualified personnel. If you are not familiar with these procedures do not
attempt to calibrate this instrument. In the case that it is necessary to
recalibrate an input proceed as described in the following steps:
- Set the type parameter according to the input type.
- Configure the lower and upper limits of indication for the maximum span of the selected input type.
- Access the calibration cycle.
- Enter the password.
- Enable the calibration setting YES in the parameter (Alib.
- Using a function generator, apply to the input terminals a signal level close to the lower limit of the configured input range. With the aid of an electrical signals simulator, apply a signal level close the lower limit of the measuring range of the input, on the corresponding terminals.
- Access the parameter inLC. With the keys and adjust the display reading such as to match the applied signal. Then press the key.
- Inject a signal that corresponds to a value a little lower than the upper limit of indication.
- Access the parameter ink(. With the keys and , adjust the display reading such as to match the applied signal. Then press the key until return to the Display PV screen.
- Validate the calibration performed.
Note : When checking the controller calibration with a Pt100 simulator, pay attention to the simulator minimum excitation current requirement, which may not be compatible with the 0.170 mA excitation current provided by the controller.
WARRANTY
Warranty conditions are available on our website www.novusautomation.com/warranty.
References
Read User Manual Online (PDF format)
Read User Manual Online (PDF format) >>