Air or pneumatic motors use linear or rotational motion to transfer compressed air energy to mechanical work. There are several designs available, the most popular of which are vane, piston, and turbine motors. When dealing with big weights at low speeds and precise control is required, the piston air motor is suitable.
A compressed air motor, often referred to as a pneumatic motor, is a kind of motor that produces mechanical work from the potential energy contained in compressed air. These motors are frequently employed in a variety of settings, such as dangerous locations or areas with volatile chemicals, where using electricity or other power sources may not be feasible or safe.
Here’s how a compressed air motor typically operates:
1. Compression: Air is compressed with a compressor to increase pressure and store potential energy.
2. Conversion to Mechanical Energy: The compressed air is then sent into the air motor, where it expands and exerts force on the motor’s components.
3. Rotational Motion: The force created by the expanding air rotates the motor’s rotor, resulting in mechanical work.
4. Exhaust: After the air has expanded and done its job, it is exhausted by the motor, and the cycle can be repeated.
The piston air motor functions similarly to a hydraulic motor. But it transforms hydraulic energy into mechanical energy by converting the linear motion of multiple pistons into a rotating motion with the help of a swash plate or crank.
A piston air motor contains 4 to 6 cylinders placed axially or radially within a housing. The air pressure retained in each cylinder generates power. Which is dependent on the input pressure, the number of pistons, the piston area, stroke, and speed. At any given air pressure, a motor with a greater speed, a bigger piston diameter, more pistons, or a longer stroke can provide more power.
Air motors may be classified into various categories, including:
1. Vane Motors: These motors employ vanes placed on a rotor to produce a rotational motion as air rushes over them.
2. Piston Motors: Piston air motors employ reciprocating pistons to transform the energy of expanding air into rotational motion.
3. Gear Motors: Gear motors employ gears to transform the expanding air’s linear motion into spin.
4. Turbine Motors: Turbine motors, like wind turbines, have a rotor with blades that are spun by expanding air
A piston air motor, as previously stated, uses reciprocating pistons to transfer the energy of expanding air into rotating motion. These motors generally have a cylinder with one or more pistons within. Compressed air enters the cylinder and pushes the piston(s) outward. This movement is turned into rotational motion via a crankshaft mechanism.
Axial piston air motors position their pistons axially, connected to a swash plate, which in turn links to the motor shaft via bevel gears. Compressed air prompts the pistons to rotate the swash plate, transmitting the motion to the motor shaft through the bevel gears. Thanks to this design, they can operate both clockwise and counterclockwise.
Radial piston air motors position their pistons radially and connect them to the motor shaft through piston rods. The force of the piston rods causes the motor shaft to turn. The radial piston air motor is an ideal choice for continuous and uninterrupted operation, finding extensive use in mining machinery. Additionally, it powers conveyor belt motors and various related applications. They have the highest starting torque of any air motor, which is advantageous in circumstances with high starting loads.
Both the air motors have one significant limitation. They are internally lubricated, which means that oil and grease levels need to be monitored. They are more compact than the radial piston motor, making them the best choice for installation in cramped areas. In comparison to the more prevalent vane air motor, the design of the piston air motor is more complex and costly. On the other hand, it runs smoother and delivers maximum power at much lower speeds.
The efficiency of a compressed air motor is determined by a number of factors, including the motor’s design, the compressor’s efficiency, and the overall system configuration. Compressed air systems are known to be less efficient than electrical or hydraulic systems. This is due to energy losses in the compression, transmission, and conversion operations. However, technological breakthroughs and improved system designs have enabled compressed air motors to become more efficient over time. Compressed air systems typically have an efficiency range of 10% to 40%, depending on the application and system design.
The piston air motor offers a powerful starting torque combined with great speed control. It is best suited for heavy tools or hydraulic systems that operate at low speeds and require high power.
Check out here the piston air motors models .