Quiz: AME Unit 11 Q1
Next Study Notes:AME Unit 11 Q2
With reference to Discontinuous or On Off control systems:
(a) sketch the response of a basic heater control, showing temperature against time and labelling the key points;(4)
(b) state THREE methods of improving the accuracy/speed of response(6)
Discontinuous or On-Off Control System
A discontinuous or on-off control system is a type of controller that has only two states: on or off. The output signal is switched between these two states depending on whether a measured process variable is above or below a preset setpoint.
How it Works:
- Setpoint: This is the desired value for the process variable.
- Process Variable: This is the actual measured value of the controlled quantity.
- Controller: Compares the process variable to the setpoint.
- Output: Either fully on or fully off, depending on the comparison.
Example:
- Thermostat: A common example is a thermostat. If the room temperature falls below the setpoint, the heater turns on. When the temperature reaches the setpoint, the heater turns off.
Characteristics:
- Simple: Easy to understand and implement.
- Economical: Often less expensive than more complex control systems.
- Oscillations: Tends to produce oscillations around the setpoint due to the abrupt on/off switching.
- Limited Accuracy: Not suitable for applications requiring precise control. 1. Process Control: A Comprehensive Guide to Implementation and Understanding in Industrial Systems – Wevolver www.wevolver.com
Applications:
- Simple heating and cooling systems: Homes, small commercial buildings.
- Pump control: Starting and stopping pumps based on level or pressure.
- Lighting control: Turning lights on and off based on light levels.
Image:
Opens in a new windowx-engineer.org onoff control system
In summary, on-off control is a basic control strategy that can be effective for simple systems but may not be suitable for applications requiring precise control or high performance.
1. On-off Vs PID Temperature Controller: Differences You Need To Know – GoSwitchgear
Response of a Discontinuous or On-Off Control System
A discontinuous or on-off control system generates a bang-bang response. This means the output switches abruptly between two states: fully on or fully off.
1. On/off Control (Bang-bang Control) | Closed-loop Control Systems | Textbook
2. Bang–bang control – Wikipedia
Key characteristics of the response:
- Oscillations: The system tends to oscillate around the setpoint due to the abrupt changes in the output.
- Over-shoot and under-shoot: The process variable often overshoots or undershoots the setpoint before stabilizing.
- Steady-state error: There’s often a steady-state error, meaning the process variable doesn’t settle exactly at the setpoint.
Visual representation:
Opens in a new windowwww.researchgate.net bangbang control response
Factors affecting the response:
Hysteresis: Adding hysteresis (a delay in the controller’s response) can also help dampen oscillations.
System dynamics: The characteristics of the system being controlled (e.g., mass, inertia, time constants) significantly influence the response.
Dead band: Introducing a dead band (a range of values around the setpoint where no action is taken) can reduce oscillations but may increase steady-state error.
Improving Accuracy and Speed of On-Off Control Systems
While on-off control systems are simple and often sufficient for basic applications, their inherent limitations in accuracy and speed can be addressed through several techniques:
Improving Accuracy:
- Deadband: Introducing a deadband, a range of values around the setpoint where no action is taken, can reduce the frequency of switching and thus reduce oscillations. 1. Deadband – Wikipedia en.wikipedia.org
- Hysteresis: Implementing hysteresis, where the on and off setpoints are different, can also help to dampen oscillations and improve accuracy.
- Proportional Band: While not strictly an on-off control, a proportional band can be introduced to modulate the output based on the error between the setpoint and the process variable, improving accuracy.
Improving Speed of Response:
- System Optimization: Improving the dynamics of the system being controlled can directly affect how quickly it responds to changes. This might involve reducing mass, inertia, or time constants.
- Faster Actuators: Using faster actuators can also improve response time. However, this often comes with increased cost and energy consumption.
Limitations and Considerations:
- Trade-offs: Improving accuracy or speed often comes at the expense of the other. For example, increasing the deadband can reduce oscillations but may also increase steady-state error.
- Complexity: Introducing more sophisticated techniques like proportional bands or hysteresis can increase the complexity of the system.
- Alternative Control Strategies: For applications demanding high accuracy and speed, more advanced control strategies like PID (Proportional-Integral-Derivative) control might be necessary.
In conclusion, while on-off control systems are simple and cost-effective, their performance limitations can be partially addressed through techniques like deadband, hysteresis, and system optimization. However, for demanding applications, more advanced control strategies should be considered.