Air Tool Parts

Pneumatic Cylinders Bounce Back

Pneumatic cylinders perform an array of functions in electronics, automotive, and packaging industries. Their basic function is always the same — linear advancement of loads by attachment to a metal piston, pushed to and fro by columns of air. At some point in every application, however, a cylinder must slow down, stop, and change direction. Exactly how that happens determines how well the cylinder will perform in cycling applications.

Air throttle
When an uncushioned piston reaches one end of its stroke, it slams into the end cap, creating a hard metal-to-metal impact. The impact is often so loud that its exceeds OSHA standards for workplace noise. After the impact, the piston may bounce, during which time, the cylinder’s motion is technically uncontrolled. The high amplitude, high-frequency impact can also damage the cylinder, as well as surrounding equipment.

Avoiding such problems and decelerating piston rods in a controlled manner requires external or internal cushioning. External cushioning employs a shock-absorbing mechanism outside the cylinder’s body to absorb piston impact. The drawback is that it increases the footprint of the cylinder and adds weight and moving parts. Internal cushioning, on the other hand, operates within the cylinder footprint and tends to be simpler in function.

Here’s how internal cushioning works: At end-of-stroke, a piston rod approaches the cylinder end and squeezes air out; a flow vent meters air for controlled velocity. Just before impact, a cushion spear or sleeve jumps into action, blocking the cushion seal and eliminating the exhaust path. The controlled volume quickly decreases, compressing the gas. Exhaust is then metered out even more slowly, through a cushion needle, completely decelerating the piston before it contacts the cylinder end.

The air cushion itself is adjustable, so the volume of air released can be metered during compression. A threaded needle screw piercing an orifice on the end cap provides the adjustment. Turning the screw further into the orifice decreases the amount of air that can escape in a given time. This diminished exhaust creates backpressure for an even more dramatically decelerated piston.

Physics makes it possible
The physics involved in a cushioned air cylinder is relatively straightforward. The laws of physics require that a negative force act on a piston to decelerate it. This occurs when air is squeezed or compressed in the end cap, and can be mathematically understood.

Two things actually prevent pistons from colliding with end caps. One is the deceleration of the piston with an auxiliary (cushion) system. The other is drag. Pistons (and loads attached to them) slow down quickly when — prior to hitting any air cushion — the actuator reaches equilibrium between the net driving and frictional force:

Once the piston reaches the air-cushioned zone, it compresses the controlled volume of air, producing an elevated backpressure. In turn, this provides a negative force component to decelerate the load:

Some assistance
So, how do we avoid piston and end cap contact, bouncing, and noise, while also maintaining reasonable cycle times? By extending the cushion seal and changing its attachment to the piston. Rubber seals that extend beyond the face of the piston assist in cylinder deceleration. These extended seals are usually made of nitrile-based rubber, press-fit into a machined groove on the piston. As a cylinder completes its stroke, the seal absorbs 80% of the energy, reducing pneumatic bounce, and effectively, noise. In this way, all the cushioning isn’t done by the air cushion. Less time is spent draining air, so cycle times are maximized.

A cylinder that includes an energy-absorbing seal allows for a larger cushion orifice. With this, a piston can travel through the air cushion in one-fourth the time of a conventionally cushioned cylinder. Plus, extended piston seals can accelerate out of air cushions faster. One reason is that the larger cushion orifice doubles as a larger bleed orifice in the reverse stroke, letting air into the cylinder at a faster rate while exiting the air cushion at the other end. Another reason is the seal acts as a compressed spring, providing an initial force of 80 psi to push or accelerate the cylinder.

Hydraulic Cylinders

Hydraulic cylinders come in all shapes and sizes, so you will need to know what you are going to use them for in order to know where to start looking for the type you need. For instance, if you are going to make use of a hydraulic cylinder on your car you will go to a car parts store or auto repair supplier in order to find the piece for your car.

This is to say that all the cylinders out there are made differently, because they are made to do specific things, so you need to be sure that you are buying the right part for the job at hand. The first thing that most people will look is the yellow pages. This is a good place to start, but you need to know that there are online yellow pages too, and the internet is the perfect place to start looking, especially if you want to know how to rebuild hydraulic cylinders.

There are a number of guides online for just about anything, but if you are going to pay for one you will need to make sure that you are getting the one that you need. Make sure that the title specifies what type of hydraulic cylinder it shows you. If the title does not specify, be sure to send the seller of the guide an email to find out.

While you are waiting for the reply to your mail be sure to check out the blogs. There are a number of people out there sharing information about services and tools they have bought online. If you were to find a mechanics blogs you may come across an article or two about the person you have emailed about that guide you were going to buy.