IC693CPU331 | IC693CPU374 | Single-socket modular CPU
Model: IC693CPU331
Category: Single-socket modular CPU
Finish: New/not new
Warranty: One year
Discrete output: 512
Discrete input point - %I: 512
Operating temperature: 32 to 140 degrees Fahrenheit
Discrete output point - %Q: 512
Analog input -% AI 128 words
Analog output - %AQ 64 words
Built-in serial port: 1 (using connector on PLC power supply). Supports SNP slave and SNP-X slave protocols
Timer/counter: 680
Interrupt: No
Shift register: Yes
Current load: 350 MA
Bus voltage: +5 volts DC
The C693CPU331 is a 90-30 series component manufactured by GE Fanuc. This is a single-slot modular CPU. It was equipped with an 80188 processor, a clock speed of 10MHz, and a maximum user program memory of 16 KB. It supports 512 discrete inputs, 512 discrete outputs, 128 analog input words, and 64 analog output words. It has one (1) serial port SNP/SNP-X slave protocol. The processor's typical scan rate is 0.4 milliseconds per 1K of Boolean logic.
Definition: Single-slot modular cpus are those CPU modules that can be installed and configured in a single slot, and they are often designed for industrial automation, embedded systems, servers, and many other fields.
Features:
Modular design: IC693CPU331 allows users to select and replace CPU modules according to needs, improving the flexibility and scalability of the system.
Easy to upgrade: With the development of technology, users can easily upgrade CPU modules to adapt to higher performance requirements.
Space saving: The single-slot design reduces the physical space required, making the system more compact.
Cost reduction: With modular design, users can purchase only the CPU modules they need, thus reducing costs.
Application scenario
Industrial automation: IC693CPU331 In the field of industrial automation, single-slot modular cpus are widely used in programmable logic controllers (PLCS) to achieve precise control of production processes.
Embedded systems: In embedded systems, single-slot modular cpus provide powerful computing power while maintaining system compactness and low power consumption.
