NOVUS N1050 Temperature Controller User Manual

NOVUS N1050 Temperature Controller

The N1050 Controller is a device designed to control and monitor processes in industrial applications. It offers various features such as input type selection, user-configurable output channels, control mode, and alarm outputs.

Safety Alerts

Important operational and safety information is highlighted using symbols throughout the document and on the equipment. All safety instructions in the manual must be observed to ensure personal safety and prevent damage to the instrument or system. Using the instrument in a manner not specified by the manufacturer may impair the protection provided by the equipment.

Installation/Connections

The controller must be secured on a panel following the sequence of steps described below:

Electrical Connections

The back panel layout of the controller is shown in Figure 1 and Figure 2. The recommended installation steps must be followed to avoid damage to the equipment.

Installation Recommendations

The controller must be installed on a panel using the recommended installation steps to avoid damage to the equipment.

Features

The N1050 Controller offers various features such as input type selection, user-configurable output channels, control mode, and alarm outputs.

Input Type Selection

The input type used by the controller is defined in the device configuration. Table 1 shows the available input options.

Outputs

The controller offers 2, 3, or 4 output channels depending on the model requested. The output channels are user-configurable as Control Output, Alarm Output, SP or PV Retransmission, and LBD (Loop Break Detect) function. The details of each output channel are shown below:

Pulse type output. 5 Vdc / 50 mA max. Available on terminals 4
and 5.| Relay SPST-NO. Available on terminals 6 and 7.| Relay SPST-NO. Available on terminals 13 and 14.| Analog Output or Current Output. 0-20 / 4-20 mA, 500 R maximum.
Available on terminals 13 and 14.
| | Relay SPDT. Available on terminals 10, 11, and 12.|

Control Output

The output that will command the Process Actuator (Heating Resistance, Refrigeration Compressor, etc.). The control output can be directed to a relay, an analog output, or even a Pulse type output, according to the availability and user’s desire.

Control Mode

The N1050 Controller offers analog output of electric current that can perform the following functions:

• As a control output, it relates the MV range (0 to 100 %) to the current range: 4 to 20 mA or 0 to 20 mA.
• As the PV / SP relay output of the process, the electrical current applied to the analog output will be proportional to the ratio between the value of the variable (PV or SP) and the retransmission range defined by parameters rtLL and rtHL. The analog output is electrically isolated from the other controller circuits.
• It has a measurement accuracy of 0.25 % of the Operating Range or 0.4 mA.

Alarm Output

The N1050 Controller has 2 alarms (Alarm 1 (A1) and Alarm 2 (A2)) that can be directed (assigned) to any output channel. These alarms can be configured to operate in distinct functions, as described in Table 2:

Note 1: The figures are also valid for Alarm 2 (SP.A2). Note 2: Alarms configured with the Hi, diF, and diF.H functions also trigger their associated output when a sensor fault is identified and signaled by the controller. A relay output, for example, configured to function as a High Alarm (Hi), will operate when the SPAL value is exceeded and when the sensor connected to the controller input is broken.

Initial Blocking of Alarm

The Initial Blocking option inhibits the alarm from being recognized if an alarm condition is present when the controller is first energized. The alarm will be enabled only after the occurrence of a non-alarm condition followed by a new occurrence for the alarm.

Product Usage Instructions

Follow the below instructions to use the N1050 Controller:

1. Install the N1050 Controller on a panel using the recommended installation steps to avoid damage to the equipment.
2. Define the input type to be used by the controller in the device configuration. Refer to Table 1 for available input options.
3. Configure the output channels as per your requirement. Refer to the Outputs section for details on available output channels and their functions.
4. Assign Alarm 1 (A1) and Alarm 2 (A2) to any output channel. Configure them to operate in distinct functions as described in Table 2.
5. If required, enable the Initial Blocking option to inhibit an alarm from being recognized when an alarm condition is present during the controller’s first energization.

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.

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 / CONNECTIONS

The controller must be fastened on a panel, following the sequence of steps described below:

• Prepare a panel cut-out, according to 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

The layout of the features on the back panel of the controller is shown in Figure 1 and Figure 2:

INSTALLATION RECOMMENDATIONS

• 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

The input type to be used by the controller is defined in the device configuration. Table 1 shows the available input options:

OUTPUTS
The controller offers 2, 3, or 4 output channels, depending on the model requested. The output channels are user configurable as Control Output, Alarm Output, SP or PV Retransmission, and LBD (Loop Break Detect) function.

• OUT1
  Pulse type output. 5 Vdc / 50 mA max. Available on terminals 4 and 5.

• OUT2
  Relay SPST-NO. Available on terminals 6 and 7.

• OUT3
  Relay SPST-NO. Available on terminals 13 and 14.
  Analog Output or Current Output. 0-20 / 4-20 mA, 500 R maximum. Available on terminals 13 and 14.

• OUT4
  Relay SPDT. Available on terminals 10, 11, and 12.

CONTROL OUTPUT
The output that will command the Process Actuator (Heating Resistance, Refrigeration Compressor, etc.). The control output can be directed to a relay, an analog output, or even a Pulse type output, according to the availability and user’s desire

CONTROL MODE

• The controller has two modes: Manual Mode or Automatic Mode. The CtL parameter allows you to select one or the other control mode.
• In Manual mode (MAN), you determine the MV value applied to the Control Output.
• In Automatic mode (Auto), the controller is in control of the process, automatically setting the MV value to be applied to the output defined as the Control Output.
• In Automatic mode there are two distinct control strategies: ON/OFF Control and PID Control.
• The ON/OFF Control, obtained when you set the Proportional Band (Pb) parameter to 0.0, acts on the Control Output, based on the simple relation between SP and PV (measured temperature).
• The PID Control action is based on a mathematical control algorithm, which, considering the correlation between SP and PV, acts on the Control Output and on the values set for parameters Pb, ir and dt.
• The determination of parameters Pb, ir and dt is described in the PID PARAMETERS DEFINITION section.

ANALOG OUTPUT OR CURRENT OUTPUT
The controller has an analog output of electric current that can perform the following functions:

• Process control output
• Process PV retransmission output
• Process SP retransmission output

As a control output, it relates the MV range (0 to 100 %) to the current range: 4 to 20 mA or 0 to 20 mA.

• 0 % MV determines 4 mA (or 0 mA) on the Analog Output
• 100 % MV determines 20 mA on the Analog Output

As the PV / SP relay output of the process, the electrical current applied to the analog output will be proportional to the ratio between the value of the variable (PV or SP) and the retransmission range defined by parameters rtLL and rtHL.
The analog output is electrically isolated from the other controller circuits.
It has a measurement accuracy of 0.25 % of the Operating Range or 0.4 mA.

ALARM OUTPUT
The controller has 2 alarms (Alarm 1 (A1) and Alarm 2 (A2)) that can be directed (assigned) to any output channel.
These alarms can be configured to operate in distinct functions, as described in Table 2:

Note 1: The figures are also valid for Alarm 2 (SP.A2).
Note 2: Alarms configured with the Hi, diF, and diF.H functions also trigger their associated output when a sensor fault is identified and signaled by the controller. A relay output, for example, configured to function as a High Alarm (Hi), will operate when the SPAL value is exceeded and when the sensor connected to the controller input is broken.

INITIAL BLOCKING OF ALARM
The Initial Blocking option inhibits the alarm from being recognized if an alarm condition is present when the controller is first energized. The alarm will be enabled only after the occurrence of a non-alarm condition followed by a new occurrence for the alarm.
The Initial Blocking is useful, for instance, when one of the alarms is configured as a minimum value alarm, causing the activation of the alarm soon upon the process start-up, an occurrence that may be undesirable.
The Initial Blocking is disabled for the i.Err function.

RUN FUNCTION

• The RUN function allows you to enable and disable the device operation. It works like a general key.
• When in the on condition (RUN = YES), the controller is enabled to operate, and the control outputs and the alarm are acting normally.
• When in the off condition (RUN = No), the controller does not act on the process, summarily switching off its outputs. No function is performed and only the measured temperature indication remains operative.
• Function available in the RUN parameter in the controller Operation cycle. The RUN indicator on the frontal panel of the controller turns on when the control is enabled (RUN = YES).

SAFE OUTPUT FUNCTION WITH SENSOR FAILURE

• Function that ensures that the control output is in a safe condition for the process when an error in the sensor input is identified.
• When a fault is identified in the sensor, the controller will determine the percentage value set in the parameter iE.ou for the control output. The controller will remain in this condition until the sensor failure disappears.
• When in ON/OFF mode, the values for iE.ou are only 0 and 100%. When in PID mode, any value between 0 and 100% will be accepted.

LBD FUNCTION – LOOP BREAK DETECTION
The parameter Lbdt defines a time interval, in minutes, within which the PV is expected to react to a control output signal. If the PV does not react properly within the time interval configured, the controller will signal the occurrence of the LBD event, which indicates control loop problems, in its display. An LBD event may be sent to any output channel. To do so, just configure the desired output channel with the Lbd function which, in this event, will be triggered. The LDB function is disabled when the parameter is programmed with 0 (zero). This function is useful in detecting system failures, such us defective sensors or actuators, loads and power supply, among others.

OFFSET

• This feature allows a small adjustment to the PV indication. Also allows you to correct measurement errors that appear, for example, during the replacement of a temperature sensor.

TIMERS

• The controller has two timers (T1 and T2), which operate independently of the temperature control actuation.
• The parameters that define the operation mode of these timers are presented in the Timer Cycle.
• The time count always starts with T1 and, at the end of it, starts the T2 count. The time base can be set as HH:MM or MM:SS in the parameter t.tb.
• Any of the controller outputs can be linked to the timers.
• The special parameter (t.RUN) allows disabling the temperature controller at the end of the timer.
• The A3 and A4 indicators on the front of the controller are linked to the conditions of the T1 and T2 timers, respectively.

TIMER T1
T1 is the main timer. Its operating mode is set with the configuration of two parameters:
Timer trigger.
Behavior of the output timer
Note 3: The T1 adjustment parameter can also be shown in the Operation Cycle of the controller by parameter t1.E.

TIMER T1 TRIGGER
There are three Timer T1 trigger, available in parameter t.Str:

Note 5: The timer trigger via the key is linked to the control condition enabled (RUN = YES).
Note 6: In the t.Str parameter, the oFF option disables the T1 and T2 timers and hides all parameters related to this feature.

BEHAVIOR OF OUTPUT T1 DURING T1
The T1 output has two different behavior possibilities during T1 timer. The parameter t.End allows its definition. The A3 indicator on the controller frontal indicates the timer current step.

Note 7: When the timer is interrupted by pressing the key, the indicator (A3 or A4) will flash quickly.

TEMPERATURE CONTROL BEHAVIOR AT THE END OF THE TIMER
During the timing of T1 and T2 intervals, the temperature control acts according to its configuration and in an independent way. However, at the end of the T1 + T2 interval, it is possible to set the controller to disable the temperature control, changing the condition of the parameter RUN to NO.
In the Timer Cycle of the controller, the parameter t.RUN allows you to create the desired configuration:

TIMER T2
T2 is the secondary timer. T2 always start its timer at the end of T1. T2 can also be linked to any available output of the controller. The linked output always turns on at the beginning of T1 and turns off at its end.
The A4 indicator shows the timer T2 condition:

• T2 in progress = A4 is flashing.
• T2 do not start or is already finished = A4 is off.

TIMER DIRECTION
For both timers, time counting can be set in ascending or descending mode. In UP mode, the countdown starts at zero and goes up to the value of the programmed time interval (T1 T2). In the DOWN mode, the countdown starts at the programmed time interval value and goes down to zero.
The timer direction is defined in parameter t.dir.

TIMERS TIME BASE
The parameter t.tb in the Timer Cycle set the time base to be used. The options are:

• HH: MM – The T1 and T2 time intervals are displayed in hours and minutes.
• MM: SS – The T1 and T2 time intervals are displayed in minutes and seconds.

USB INTERFACE
The USB interface is used to CONFIGURE, MONITOR or UPDATE the controller FIRMWARE. You 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 you 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, you 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).
You must use QuickTune software or consult the DEVICE MANAGER on the Windows Control Panel to identify the COM port assigned to the controller.
You should consult the mapping of the MODBUS memory in the controller’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:

1. 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.
2. 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).
3. Run the QuickTune software, configure the communication and start the device recognition.

OPERATION

The front panel of the controller is shown in the Figure 3:

• Display: Displays the measured variable, symbols of the configuration parameters and their respective values/conditions.
• Tx/RX Indicators: Flashes when the controller exchanges data with the RS485 communication network.
• AT Indicator: On while the controller is in automatic tuning.
• MAN Indicator: On while the controller is in manual mode. RUN Indicator: On with control enabled (RUN = YES). When flashing, it indicates that a program has stopped running.
• OUT Indicator: Indicates the instantaneous state of the control output(s).
• A1 and A2 Indicators: Indicate the occurrence of an alarm condition.
• A3 Indicator: Indicates the condition of timer T1.
• A4 Indicator: Indicates the condition of timer T2.
• °C / °F Indicators: Identify the temperature unit.
• Key: Key used to advance to successive parameters and parameter cycles.
• Increment Key and Decrement Key: Keys used to change the parameter values.
• Key: Keys used to retrocede parameters when in configuration mode and performs special functions.

INITIALIZATION
When the controller is energized, the number of its current software version will be displayed in the first 3 seconds, and then the value of the measured process variable (temperature) will be displayed on the upper display. The value of SP is displayed in the lower display. This is the Indication Screen.
To be used in a process, the controller needs to be preconfigured. The configuration consists of the definition of each of the several parameters presented. You must understand the importance of each parameter and determine a valid condition or a valid value for each one.

The configuration parameters are gathered into groups of affinities, called Parameter Cycles. The 7 parameter cycles are:
1 – Operation / 2 – Tuning / 3 – Programs / 4 – Alarms /
5 – Input / 6 – Timer / 7 – Calibration
The key gives access to the cycles and their parameters:
When you hold the key down, the controller will cycle from one cycle to another every 2 seconds, displaying the first parameter of each cycle: To enter the desired cycle, simply release the key when your first parameter is displayed. To advance on the parameters of this cycle, use the key with short touches. To return parameters, use the key.
Each parameter has its symbol displayed in the upper display. Its respective value/condition is shown in the lower display.
Depending on the Configuration Protection adopted, the PASS parameter is displayed as the first parameter of the cycle where the protection starts (See CONFIGURATION PROTECTION chapter).

PARAMETERS DESCRITION

OPERATION CYCLE

TUNING CYCLE

PROGRAM CYCLE

ALARM CYCLE

INPUT CYCLE

TIMER CYCLE

Note 8: In the t.Str parameter, the oFF option disables completely the T1 and T2 timers and hides all parameters related to this function.

CALIBRATION CYCLE
All types of input are calibrated in the factory. In case a recalibration is required. It shall be conducted by a specialized professional. In case this cycle is accidentally accessed, do not perform alteration in its parameters.

CONFIGURATION PROTECTION

The controller allows you to protect the configuration made, preventing undue changes.
In the Calibration Cycle, the Protection parameter (Prot) determines the protection level to be adopted, limiting access to the cycles, according to the table below:

protected.
7| All cycles, except SP screen in Operation Cycle, are protected.
8| All cycles, including SP, are protected.

Table 3 – Protection levels

ACCESS PASSWORD

• When accessed, the protected levels request the Access Password for granting permission to change the configuration of the parameters on these levels.
• 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.
• You can set the Access Password in the parameter Password Change (PAS.C), present in the Calibration Cycle.
• The factory default for the password code is 1111.

PROTECTION ACCESS PASSWORD

• The protection system built into the controller blocks for 10 minutes the access to protected parameters after 5 consecutive frustrated attempts of guessing the correct password.

MASTER PASSWORD

• The Master Password allows you to define a new password in the event of it being forgotten. The Master Password does not grant access to all parameters, only to the Password Change parameter (PASC). 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.

RAMP AND SOAK PROGRAMS

Feature that allows you to create a behavior profile for the process. Each program consists of a set of up to 4 segments, called RAMP AND SOAK PROGRAM, defined by SP values and time intervals.
Up to 5 different ramp and soak programs can be created. The figure below displays a profile model:

Once the program is defined and executed, the controller automatically generates the SP according to the program.
To execute a program with several segments smaller than 4 (four), simply program 0 (zero) for the next segment time to the last desired segment.
The program tolerance function P.toL defines the maximum deviation between PV and SP during program execution. If this deviation is exceeded, the time count is interrupted until the deviation is within the programmed tolerance (gives SP priority). If zero is set in the tolerance, the controller executes the defined program without considering any deviations between PV and SP (gives priority to time).
The configured time limit for each segment is 5999 and can be displayed in seconds or minutes, depending on the time base configured.

RESTORE PROGRAM AFTER POWER FAILURE
Function that defines the behavior of the controller when it resumes from a power failure during a program execution of ramps and soaks. The restore options are:

• ProG Returns at the beginning of the program
• P.SEG Returns the beginning of the segment.
• t.SEG Returns to the point of the previous program segment the power failure (*).
• oFF Returns with control disabled (RUN = No).

(*) In the option Returns to the point of the previous program segment (t.SEG), you must consider uncertainties of up to 1 minute between the time of the segment at the moment of the power outage and the time of the segment adopted to resume the execution of the program at the moment of the power supply return.
The t.SEG option has its performance related to the configuration adopted by the parameter P.toL. Thus, it also has the following functions:

1. With P.toL set to zero, the controller resumes the execution of the program immediately after the energy return (from the point and segment where it stopped), regardless of the PV value at that time.
2. With P.toL non-zero, the controller waits until PV enters the deviation range defined by the value of P.toL and then resumes the program execution.

PROGRAM LINK
It is possible to create a large, more complex program with up to 20 segments connecting the 5 programs. Thus, at the end of the execution of a program, the controller immediately starts executing another program.
When creating a program, it was defined in the screen LP whether there will be connection to another program.
For the controller to be able to run a certain program or programs continuously, simply connect a program to itself or the last program to the first one.

EVENT ALARM
The Event Alarm function allows you to program the triggering of alarms in specific segments of a program. For this function to operate, the alarms to be triggered must have their function set to rS and are configured in parameters PE1 to PE4.

HOLD PROGRAM FUNCTION
This function stops program execution when the key is pressed.
The H.PrG parameter of the Calibration Cycle enables the key to perform this function.
Pressing the key for 1 second will immediately stop the program. A new press, also of 1 second, resumes its execution. While the program is stopped, the RUN indicator on the controller frontal remains flashing.

PID PARAMETERS DEFINITION

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:

• Select the process Setpoint.
• Enable auto-tuning at the parameter Atun, 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.
The sign TUNE remains lit during the whole tuning phase. You must wait for the tuning to be completed before using the controller.
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 4 for guidelines on how to correct the process behavior:

Derivative Time

| Slow answer or instability| Decrease
Great oscillation| Increase

Table 4 – Guidance for manual adjustment of the PID parameters

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 you identify problems.

configuration.

Table 5 – Error messages

Other error messages may indicate hardware problems requiring maintenance service.

INPUT CALIBRATION
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.
The calibration steps are:

1. Configure the input type to be calibrated in the tYPE parameter.
2. Configure the lower and upper limits of indication for the maximum span of the selected input type.
3. Go to the Calibration Cycle.
4. Enter the access password.
5. Enable calibration by setting YES in CALb parameter.
6. Using an electrical signals simulator, apply a signal a little higher than the low indication limit for the selected input.
7. Access the parameter in.LC. With the keys and adjust the display reading such as to match the applied signal. Then press the key.
8. Apply a signal that corresponds to a value a little lower than the upper limit of indication.
9. Access the parameter in.HC. With the keys and adjust the display reading such as to match the applied signal.
10. Return to the Operation Cycle.
11. Check the resulting accuracy. If not good enough, repeat the procedure.

Note 9: 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.

ANALOG OUTPUT CALIBRATION

1. Set the retransmission type in the OUT3 parameter.
2. Connect a milliampere meter to terminals 13 and 14 of the analog output.
3. Enter the Calibration Cycle.
4. Select parameter Ao.LC.
5. Press the and keys and observe the value displayed by the milliampere meter.
6. Use the and keys to change the controller display to the value of the current indicated on the milliampere meter.
7. Select the screen Ao.LC.
8. Press the and keys and observe the value shown by the milliampere meter.
9. Use the and keys to change the controller display to the value of the current indicated on the milliampere meter.
10. Exit the Calibration Cycle.
11. Validate the calibration performed.

SERIAL COMMUNICATION

The controller can be supplied with an asynchronous RS485 digital communication interface for master-slave connection to a host computer (master).
The controller works as a slave only and all commands are started by the computer which sends a request to the slave address. The addressed unit sends back the requested reply.
The controller also accepts Broadcast commands.

FEATURES

• Signals compatible with RS485 standard. MODBUS (RTU) Protocol. Two wire connection between 1 master and up to 31 (addressing up to 247 possible) instruments in bus topology. The communication signals are electrically insulated from the rest of the device.
• Maximum connection distance: 1000 meters.
• Time of disconnection for the controller: Maximum 2 ms after last byte.
• Selectable speed; 8 data bits; 1 stop bit; selectable parity (no parity, pair or odd).
• Time at the beginning of response transmission: maximum 100 ms after receiving the command.

The RS485 signals are:

PARAMETERS CONFIGURATION FOR SERIAL COMMUNICATION

Three parameters must be configured for using the serial type:

• bAud Communication speed.
• PrtY Communication parity.
• Addr Communication address for the controller.

COMMUNICATION PROTOCOL
The MOSBUS RTU slave is implemented. All configurable parameters can be accessed for reading or writing through the communication port. Broadcast commands are supported as well (address 0).
The available Modbus commands are:

03 – Read Holding Register
05 – Write Single Coil
06 – Write Single Register
16 – Write Multiple Register

The most used registers are listed below. For complete information, see the Registers Table for Serial Communication, available in the N1050 section of our website www.novusautomation.com. All registers are 16-bit signed integers.

Table 7 – Table registers

IDENTIFICATION

• A: Available outputs:
• PR: OUT1 = Pulse / OUT2 = Relay
• PRRR: OUT1 = Pulse / OUT2 = OUT3 = OUT4 = Relay
• PRAR: OUT1 = Pulse / OUT2 = Relay / OUT3 = 0-20 / 4-20 mA OUT4 = Relay
• B: Serial communication:
• (Blank): (basic version, without serial communication)
• 485: (RS485 serial version, Modbus protocol)

C: Power supply:

(Blank): ………………………………………………..Model standard
………………………….. 100~240 Vac / 48~240 Vdc; 50~60 Hz
24 V: ……………………………………………………….. Model 24 V ………………………………………………………12~24 Vdc / 24 Vac

SPECIFICATIONS

• DIMENSIONS: …………………………………………….. 48 x 48 x 80 mm (1/16 DIN)
• Panel cutout: ………………………………………………… 46 x 46 mm (+0.5 -0.0 mm)
• Approximate weight: ………………………………………………………………………..75 g

POWER SUPPLY:

• Standard model: ………………………………….100 to 240 Vac (±10 %), 50/60 Hz …………………………………………………………………………. 48 to 240 Vdc (±10 %)
• 24 V model: ………………………………….. 12 to 24 Vcc / 24 Vca (-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.

TIMER

• Timer ranges: ……………………………………………………. 00:00 to 99:59 (mm:ss) ………………………………………………………………………….00:00 to 99:59 (hh:mm)
• Delay when turning on the device: ……………………………………………….200 ms
• Accuracy: ……………………………………………………..0.5% of the measured value
• OUTPUT RESPONSE TIME: …………………………………..10 ms for relay output …………………………………………………………………………..0.3 ms for pulse output
• INPUT: ……………………………………J, K, T, S and Pt100 (according to Table 1)
• Internal resolution: …………………………………………………. 32767 levels (15 bits)
• Display resolution: ………………………….. 12000 levels (from -1999 up to 9999)
• Input reading rate: ……………………………………………………up 10 per second (*)
• Accuracy: ……………………..Thermocouples J, K, T: 0.25 % of the span ±1 °C ……………………………………………..Thermocouple S: 0.25 % of the span ±3 °C ………………………………………………………………………..Pt100: 0.2 % of the span
• Input impedance: ………………………………Pt100 and thermocouples: > 10 MΩ
• Pt100 measurement: ………………………………………. 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.

OUTPUTS:

• OUT1: …………………………………………………..Voltage pulse, 5 V / 50 mA max.

• OUT2: …………………………………………..Relay SPST; 1.5 A / 240 Vac / 30 Vdc

• OUT3 (PRRR): ………………………………..Relay SPST; 1.5 A / 240 Vac / 30 Vdc

• OUT3 (PRAR): ………………………………………………………..0-20 mA or 4-20 mA ……………………………………………………500 Ohms max.; 12000 levels; Isolated
  ……………………………………………………………………… Accuracy: 0.25% F.S. (**)

• OUT4: ……………………………………………..Relay SPDT; 3 A / 240 Vac / 30 Vdc

FRONT PANEL: ……………………………… IP65, Polycarbonate (PC) UL94 V-2
HOUSING :………………………………………………………. IP20, ABS+PC UL94 V-0

SPECIFIC CONNECTIONS FOR TYPE PIN TERMINAL.

• DISPLAY: LCD type, alphanumeric with 11 segments.
• PROGRAMMABLE CYCLE OF PWM: From 0.5 up 100 seconds.
• START-UP OPERATION: After 3 seconds connected to the power supply.
• CERTIFICATIONS: CE, UKCA, and UL.
  (**) F.S. = Full scale. Maximum range of the sensor used.

1295 Morningside Avenue, Unit 16-18
Scarborough, ON M1B 4Z4 Canada
Phone: 416-261-4865
Fax: 416-261-7879
www.scigiene.com

References

• NOVUS Automation Inc. - Controllers, Thermostats, Data Loggers, Solid State Relays, Sensors, Transmitters, SCADA, Data Acquisition and Temperature Controllers

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