Name: GE IS215UCVEH2AF Mark VIe Control System Module
SKU: 18805
Price: 166.00 USD
Availability: InStock

The GE IS215UCVEH2AF integrates a range of system functions to support efficient and reliable industrial control operations, as detailed below:

Integrated Control Architecture: It operates within a cohesive control framework, often serving as a critical node in GE’s Mark VIe or similar control systems. This integration allows it to synchronize with other system components—such as I/O modules, human-machine interfaces (HMIs), and supervisory control systems—to execute unified control strategies. Whether regulating gaseous engine performance or managing industrial process variables, the architecture ensures seamless data flow and coordinated action across the system.

Real-Time Data Handling System: A core function is its ability to manage real-time data streams. It continuously acquires sensor data (e.g., temperature, pressure, flow rates) through supported communication protocols (Modbus RTU, CANopen), processes this data using on-board computing resources (Intel Celeron processor, 32 MB DRAM), and distributes actionable insights to other system elements. This real-time processing ensures that control decisions are based on up-to-the-moment information, enabling rapid responses to dynamic industrial conditions.

Redundant and Fault-Tolerant Mechanisms: To enhance system reliability, it may incorporate fault-tolerant features. These include error-checking protocols for data transmission, self-diagnostic routines to identify hardware or software anomalies, and compatibility with redundant power supplies or communication paths. In the event of a component failure or data corruption, these mechanisms help prevent system-wide disruptions, ensuring continuous operation and minimizing downtime in critical applications.

Scalable Configuration Capabilities: The system supports scalable configurations to adapt to varying industrial requirements. It can be integrated into small-scale control setups (e.g., standalone machinery) or expanded to operate within large, complex systems (e.g., multi-unit industrial plants). This scalability is achieved through flexible communication interfaces, modular software architecture, and compatibility with a wide range of peripherals, allowing users to customize the system based on specific operational needs.
Time-Synchronized Operation: Leveraging real-time clock synchronization, it ensures that all interconnected devices within the control system operate on a unified time reference. This is vital for coordinating time-sensitive processes, such as sequential manufacturing steps or synchronized actuation of multiple components. By aligning timestamps for data acquisition and control actions, the system eliminates timing discrepancies that could lead to inefficiencies or errors in industrial operations.

Operating System: It often operates on a pre – emptive multi – tasking system, such as the one built on the QNX platform. This enables efficient handling of multiple tasks simultaneously within the industrial control environment.

Microprocessor and Memory: Some models may be equipped with an Intel Celeron 300 MHz microprocessor and 32 MB of DRAM. The microprocessor’s processing power and the available memory are crucial for smooth data handling and execution of control algorithms.

Power Requirements: Usually, it requires a +5 V DC power supply. The typical current consumption is around 6 A, with a maximum of 8 A. Stable power input is essential for its reliable operation.

Communication Protocols: It supports various communication protocols like Modbus RTU and CANopen. These protocols facilitate seamless data exchange with other devices in the industrial network, whether it’s sensors, actuators, or other control units.

Operating Temperature and Humidity: It can operate in a relatively wide temperature range, typically from – 20 °C to + 70 °C. The humidity range it can withstand is 0% to 95% non – condensing, making it suitable for different industrial environments.

Dimensions: Generally, it has compact dimensions. For example, it might be around 125 mm in length, 90 mm in width, and 45 mm in height (125 x 90 x 45 mm). These dimensions are designed to fit into standard industrial control cabinets without taking up excessive space.

Weight: It is relatively lightweight, with an approximate weight of 0.25 kg. This light weight not only makes it easy to install but also reduces the overall load on the mounting structures within the control system.

High Reliability: It is engineered to operate stably in harsh industrial settings. With its ability to withstand a wide range of temperatures, humidity, and electromagnetic interference, it ensures continuous operation, minimizing system downtime.

Excellent Compatibility: It has good compatibility with other components in the GE control system family, such as those in the Mark VI series. Additionally, it can often integrate with some third – party devices, which broadens its application scope and simplifies system integration.

Precise Control: In applications like gaseous engine operations, it can provide precise control. For example, as an actuator and driver, it can accurately throttle the air supply, optimizing combustion efficiency and enhancing engine performance.

Fast Data Processing: Equipped with a capable microprocessor and sufficient memory, it can quickly process incoming data from sensors and execute control commands, enabling real – time responses to changes in the industrial process.

Master Control Function: In a VME bus system, it functions as a master controller. This means it can initiate communication with other devices on the bus, coordinate data transfer, and control the overall operation sequence of the connected devices.

Data Acquisition: It is responsible for collecting real – time data from various sensors. This data can include parameters such as temperature, pressure, and flow rate in an industrial process. The collected data is then processed and transmitted to other parts of the control system for further analysis and decision – making.

Control Signal Output: Based on the received control algorithms or commands from the main control unit, it can output control signals to actuators. For example, it can control the opening and closing of valves or the speed of motors in an industrial process.

Real – Time Clock Synchronization: It may support real – time clock synchronization, ensuring that all devices in the control system are operating in a coordinated manner with respect to time. This is crucial for applications where precise timing is required, such as in complex manufacturing processes or power generation systems.