Difference between revisions of "Pneumatic Actuators"
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[[File:Pneumatic actuators.jpg|thumb|right|Pneumatic Actuators]] | |||
* | '''Pneumatic Actuator''' converts energy into mechanical motion. The motion can be rotary or linear, depending on the type of [[Actuators]]. | ||
* | |||
==Applications== | |||
Some types of pneumatic actuators include: | |||
* Tie rod cylinders | |||
* Rotary actuators | |||
* Grippers | |||
* Rodless actuators with magnetic linkage or rotary cylinders | |||
* Rodless actuators with mechanical linkage | |||
* Pneumatic artificial muscles | |||
* Speciality actuators that combine rotary and linear motion—frequently used for clamping operations | |||
* Vacuum generators | |||
==Working Principle== | |||
A pneumatic actuator mainly consists of a piston, a cylinder, and valves or ports. The piston is covered by a diaphragm, or seal, which keeps the air in the upper portion of the cylinder, allowing air pressure to force the diaphragm downward, moving the piston underneath, which in turn moves the valve stem, which is linked to the internal parts of the actuator. Pneumatic actuators may only have one spot for a signal input, top or bottom, depending on action required. [[Valves]] require little pressure to operate and usually double or triple the input force. The larger the size of the piston, the larger the output pressure can be. Having a larger piston can also be good if air supply is low, allowing the same forces with less input. These pressures are large enough to crush object in the pipe. On 100 kPa input, you could lift a small car easily, and this is only a basic, small pneumatic valve. However, the resulting forces required of the stem would be too great and cause the valve stem to fail. | |||
This pressure is transferred to the valve stem, which is hooked up to either the valve plug , [[Butterfly Valves|butterfly valve]] etc. Larger forces are required in high pressure or high flow pipelines to allow the valve to overcome these forces, and allow it to move the valves moving parts to control the material flowing inside. | |||
Valves input pressure is the control signal. This can come from a variety of measuring devices, and each different pressure is a different set point for a valve. A typical standard signal is 20–100 kPa. For example, a valve could be controlling the pressure in a vessel which has a constant out-flow, and a varied in-flow . A pressure transmitter will monitor the pressure in the vessel and transmit a signal from 20–100 kPa. 20 kPa means there is no pressure, 100 kPa means there is full range pressure . As the pressure rises in the vessel, the output of the transmitter rises, this increase in pressure is sent to the valve, which causes the valve to stroke downard, and start closing the valve, decreasing flow into the vessel, reducing the pressure in the vessel as excess pressure is evacuated through the out flow. This is called a direct acting process. | |||
==Sources== | |||
[http://en.wikipedia.org/wiki/Pneumatic_Actuator Wikipedia Pneumatic Actuator] |
Latest revision as of 19:30, 5 December 2012
Pneumatic Actuator converts energy into mechanical motion. The motion can be rotary or linear, depending on the type of Actuators.
Applications
Some types of pneumatic actuators include:
- Tie rod cylinders
- Rotary actuators
- Grippers
- Rodless actuators with magnetic linkage or rotary cylinders
- Rodless actuators with mechanical linkage
- Pneumatic artificial muscles
- Speciality actuators that combine rotary and linear motion—frequently used for clamping operations
- Vacuum generators
Working Principle
A pneumatic actuator mainly consists of a piston, a cylinder, and valves or ports. The piston is covered by a diaphragm, or seal, which keeps the air in the upper portion of the cylinder, allowing air pressure to force the diaphragm downward, moving the piston underneath, which in turn moves the valve stem, which is linked to the internal parts of the actuator. Pneumatic actuators may only have one spot for a signal input, top or bottom, depending on action required. Valves require little pressure to operate and usually double or triple the input force. The larger the size of the piston, the larger the output pressure can be. Having a larger piston can also be good if air supply is low, allowing the same forces with less input. These pressures are large enough to crush object in the pipe. On 100 kPa input, you could lift a small car easily, and this is only a basic, small pneumatic valve. However, the resulting forces required of the stem would be too great and cause the valve stem to fail.
This pressure is transferred to the valve stem, which is hooked up to either the valve plug , butterfly valve etc. Larger forces are required in high pressure or high flow pipelines to allow the valve to overcome these forces, and allow it to move the valves moving parts to control the material flowing inside.
Valves input pressure is the control signal. This can come from a variety of measuring devices, and each different pressure is a different set point for a valve. A typical standard signal is 20–100 kPa. For example, a valve could be controlling the pressure in a vessel which has a constant out-flow, and a varied in-flow . A pressure transmitter will monitor the pressure in the vessel and transmit a signal from 20–100 kPa. 20 kPa means there is no pressure, 100 kPa means there is full range pressure . As the pressure rises in the vessel, the output of the transmitter rises, this increase in pressure is sent to the valve, which causes the valve to stroke downard, and start closing the valve, decreasing flow into the vessel, reducing the pressure in the vessel as excess pressure is evacuated through the out flow. This is called a direct acting process.