A Programmable Logic Controller, or PLC, is more or less a tiny computer with a built-in operating system (OS).
This OS is highly specialized to handle incoming events in real time, i.e. at the time of their occurrence. The PLC has input lines where sensors are connected to notify upon events (e.g. temperature above/below a certain level, liquid level reached, etc.), and it has output lines to signal any reaction to the incoming events (e.g. start an engine, open/close a valve, etc.) The system is user programmable. It uses a language called “Relay Ladder” or “Relay Ladder Logic”. The name of this language implies the fact that the control logic of the earlier days, which was built from relays, is being simulated.
The PLCs purpose in life
The PLC is primarily used to control machinery. A program is written for the PLC which turns on and off outputs based on input conditions and the internal program. In this aspect, a PLC is similar to a computer. However, a PLC is designed to be programmed once, and run repeatedly as needed. In fact, a crafty programmer could use a PLC to control not only simple devices such as a garage door opener, but their whole house, including turning lights on and off at certain times, monitoring a custom built security system, etc.
Most commonly, a PLC is found inside of a machine in an industrial environment. A PLC can run an automatic machine for years with little human intervention. They are designed to and withstand most harsh environments a PLC will encounter.
History of PLCs
When the first electronic machine controls were designed, they used relays to control the machine logic (i.e. press “Start” to start the machine and press “Stop” to stop the machine). A basic machine might need a wall covered in relays to control all of its functions. There are a few limitations to this type of control.
The delay when the relay turns on/off.
There is an entire wall of relays to design/wire/troubleshoot.
A PLC overcomes these limitations ,it is a machine controlled operation.
PLCs are becoming more and more intelligent. In recent years PLCs have been integrated into electrical networks i.e. all the PLCs in an industrial environment have been plugged into a network which is usually hierarchically organized. The PLCs are then supervised by a control center. There exist many proprietary types of networks. One type which is widely known is SCADA (Supervisory Control and Data Acquisition).
How the PLC operates
The PLC is a purpose-built machine control computer designed to read digital and analog inputs from various sensors, execute a user defined logic program, and write the resulting digital and analog output values to various out put elements like hydraulic and pneumatic actuators,indication lamps,hooters, solenoid coils etc.
Exact details vary between manufacturers, but most PLCs follow a ‘scan-cycle’ format.
Overhead includes testing I/O module integrity, verifying the user program logic hasn’t changed, that the computer itself hasn’t locked up (via a watchdog timer), and any necessary communications. Communications may include traffic over the PLC programmer port, remote I/O racks, and other external devices such as HMIs (Human Machine Interfaces).
A ‘snapshot’ of the digital and analog values present at the input cards is saved to an input memory table.
The user program is scanned element by element, then rung by rung until the end of the program, and resulting values written to an output memory table.
Values from the resulting output memory table are written to the output modules.
Once the output scan is complete the process repeats itself until the PLC is powered down.
The time it takes to complete a scan cycle is, appropriately enough, the “scan cycle time”, and ranges from hundreds of milliseconds (on older PLCs, and/or PLCs with very complex programs) to only a few milliseconds on newer PLCs, and/or PLCs executing short, simple code.
Be aware that specific nomenclature and operational details vary widely between PLC manufacturers, and often implementation details evolve from generation to generation.
Often the hardest part, especially for a beginning PLC programmer, is practicing the mental ju-jitsu necessary to keep the nomenclature straight from manufacturer to manufacturer.
Positive Logic (most PLCs follow this convention)
True = logic 1 = input energized.
False = logic 0 = input NOT energized.
True = logic 0 = input NOT energized
False = logic 1 = input energized.
(XIC) – eXamine If Closed.
This instruction is true (logic 1) when the hardware input (or internal relay equivalent) is energized.
(XIO) – eXamine If Open.
This instruction is true (logic 1) when the hardware input (or internal relay equivalent) is NOT energized.
(OTE) – OuTput Enable.
This instruction mimics the action of a conventional relay coil.
(TON) – Timer ON.
Generally, ON timers begin timing when the input (enable) line goes true, and reset if the enable line goes false before setpoint has been reached. If enabled until setpoint is reached then the timer output goes true, and stays true until the input (enable) line goes false.
(TOF) – Timer OFf.
Generally, OFF timers begin timing on a true-to-false transition, and continue timing as long as the preceding logic remains false. When the accumulated time equals setpoint the TOF output goes on, and stays on until the rung goes true.
(RTO) – Retentive Timer On.
This type of timer does NOT reset the accumulated time when the input condition goes false.
Rather, it keeps the last accumulated time in memory, and (if/when the input goes true again) continues timing from that point. In the Allen-Bradley construction this instruction goes true once setpoint (preset) time has been reached, and stays true until a RES (RESet) instruction is made true to clear it.
(OTL) – OuTput Latch.
(OTU) – OuTput Unlatch.
Generally, the unlatch operator takes precedence. That is, if the unlatch instruction is true then the relay output is false even though the latch instruction may also be true. In Allen-Bradley ladder logic (and others) latch and unlatch relays are seperate operators.
However, other ladder dialects opt for a single operator modeled after RS (Reset-Set) flip-flop integrated circuit chip logic.