ITT IM213 Setting the Acceleration/Deceleration Switches, Setting the Minimum Frequency Switch

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Starting the System

Section 7 (continued)

Caution

Failure to properly set the Motor Overload Setting switches can result in loss of motor overload protection and will void the motor warranty. Nuisance tripping or motor damage can occur if these switches are not set properly.

Setting the Acceleration/Deceleration Switches

Switch 4 from bank 1 and switches 1 and 2 from bank 2 control the acceleration/deceleration ramp times. The acceleration/deceleration switches (ACCEL/DECEL RAMP SETTINGS) control how fast the controller will change the speed of the motor. The ramp setting is the time it takes the motor to change from minimum speed to maximum speed. For example, if the ramp setting is set to 1 second and the minimum speed is set to 30Hz, the motor will ramp up from 30Hz to 60Hz in 1 second. A faster ramp setting should be used in systems where the flow rate can change quickly. This means that the motor can react faster to maintain the set pressure. A slower ramp setting should be used in systems where the flow rate changes slowly or where fast changes in speed can cause water hammer or pressure surges.

Setting the No Water Restart Time Switches

Switches 3 and 4 from bank 2 control the no water restart time. The no water (dry well) restart time switches control the time between a no water (dry well) error and the restart of the system. For example, if the no water restart time switches are set to 30 minutes, the system will restart 30 minutes after a no water (dry well) error has been detected. For the 10 minute restart time, the controller will not restart if 5 faults are detected within 60 minutes. All other settings will continue to restart after the chosen restart time.

Note

Failure to properly set the motor overload switches can result in nuisance no water (dry well) faults.

Setting the Minimum Frequency Switch

Switch 1 from bank 3 controls the minimum frequency. The minimum frequency switch controls the slowest speed that the motor will run. For submersible pump/motor applications these switches must always be set to 30Hz minimum speed. For above ground applications with high suction pressure, the 15Hz setting can be used to prevent pressure oscillation at low speeds. In some cases the suction pressure may be high enough that the pump exceeds the pressure setting at 30Hz. In this case the 15Hz setting can be used.

Caution

Failure to properly set the minimum frequency switch can result in motor damage and will void the motor warranty. The minimum frequency must be set to 30Hz for submersible applications.

Setting the Carrier Frequency Switch

Switch 2 from bank 3 controls the carrier frequency. For model numbers without the F suffix, the switch can be used to change the output carrier frequency to avoid audible noise issues in above ground applications. For model numbers with the F suffix, this switch is disabled and the carrier frequency is always set to 2 kHz.

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Contents IM213 Commercial Water ITTIndex Death Safety InstructionsController Product Code Information System ComponentsHP = Volt =Fusible Disconnect System DesignSection Diagram #2 shows a set-up for municipal water connectionPiping Installing the Pressure SensorGeneral Pressure Tank, Pressure Relief Valve and Discharge PipingMounting the Controller Delta/Wye with grounded Wye neutral Power Supply and WiringPower Supply Ungrounded secondary Delta/Delta with grounded legFor Frame Size 1 Controllers Resistance grounding and ground fault protectionOpen Delta consult factory 460 Single Phase Connection208/230 20ºC 30ºC 40ºC 50ºC Conduit, Wire and Fuse SizingStarting the System Input Power and Line Transformer RequirementsOutput Power Connections Input Power Connections Chart below shows the motor overload setting for each model Setting the Motor Overload SwitchesSetting the No Water Restart Time Switches Setting the Acceleration/Deceleration SwitchesSetting the Minimum Frequency Switch Setting the Carrier Frequency SwitchSystem Status Setting the PressureMotor Rotation Direction Input and Output Functions Use the following table to help troubleshoot problems TroubleshootingSwitch StandbyPower. If the error persists, replace controller Constant Controller ErrorThis fault can be caused by Incorrect setting of Motor Overload Setting switchesSensor cable Set the meter to read DC current mAConnect the black lead from the meter to terminal Temperature reaches 104 ºF 40ºC Blinks Temperature This fault can be caused byMegger readings To 50% or lower10Hz for 5 minutes Greater than 275V for 230V units and 560V for 460V unitsController Dimensions Input Appendix Input Wire Sizing ChartsPage IM213 Revision Number November

IM213 specifications

ITT IM213 is a prominent electronic device designed for data acquisition and monitoring in various industrial applications. Known for its robust construction and versatile functionality, the IM213 series has gained significant traction in sectors such as manufacturing, environmental monitoring, and energy management.

One of the key features of the ITT IM213 is its advanced data logging capability. The device can record a wide range of signals, including temperature, pressure, and humidity, making it an essential tool for real-time monitoring. The intuitive user interface allows users to configure the device easily, adjusting parameters to suit specific monitoring needs.

The IM213 utilizes cutting-edge technologies to ensure accuracy and reliability. Its high-resolution analog-to-digital converters (ADCs) offer precise measurements with minimal noise interference, enhancing the overall performance of the device. Additionally, the device supports multiple communication protocols, including Modbus, RS-232, and RS-485, enabling seamless integration into existing systems.

Another noteworthy characteristic of the ITT IM213 is its robust build quality. Designed for use in harsh environments, it features an IP67-rated enclosure that protects it from dust, moisture, and other potential contaminants. This makes it particularly suitable for outdoor applications or locations with challenging conditions.

Furthermore, the IM213 is equipped with a range of connectivity options. Users can connect the device to cloud platforms for remote monitoring and data analytics, leveraging IoT technologies to enhance operational efficiency. This capability allows organizations to make data-driven decisions, improving their overall productivity.

The device also supports customizable alert systems, notifying users of any deviations from preset thresholds in real-time. This feature is crucial for preventing costly downtime and ensuring that processes remain within optimal operational parameters.

In terms of power consumption, the ITT IM213 is designed to be energy-efficient, ensuring long operational life and reduced running costs. Its low-power modes further contribute to sustainability, making it a responsible choice for environmentally conscious organizations.

In summary, the ITT IM213 is a versatile and durable data acquisition device that serves a wide range of industrial applications. Its advanced logging capabilities, high accuracy, robust construction, and connectivity options position it as a leading choice for professionals looking to improve their monitoring and data collection efforts. With these features, the IM213 is poised to play a vital role in enhancing productivity and operational efficiency in various sectors.