For musical instruments, vibration is a necessity. It’s what starts sound waves moving through the air. But in the manufacturing world, whether producing tennis rackets, automobiles or any number of other products, vibration can be detrimental to products’ performance and safety. That’s why some form of vibration control is essential.
For more aeolian vibration dampersinformation, please contact us. We will provide professional answers.
Two of the most common ways of controlling vibration is vibration isolation and vibration damping. While the terms are often used interchangeably, they’re two very different processes.
Vibration damping dissipates vibration energy. It absorbs or changes vibration energy, reducing the amount of energy transmitted through the equipment or structure. Understanding these processes — and when to use them — also requires understanding two concepts: transmissibility and natural frequency.
Transmissibility is the ratio of the vibrational force being measured in a system to the vibrational force entering a system. For example, if a material used for vibration isolation has a transmissibility of 75%, that means 75% of the vibrating force energy is being transmitted (or 25% transmission loss) through the materials and measured on the other side.
Natural frequency is the frequency (number of cyclic motions per unit time) at which an object or structure vibrates naturally or resonates. A structure vibrating at natural frequency will vibrate forever unless an outside force interferes with it. Thankfully, in nature, there’s always some force affecting a vibrating object, removing energy and eventually dissipating the vibration; these forces collectively are commonly referred to as vibration damping.
So how do all these concepts and definitions help determine if vibration damping or isolation is the way to go in controlling vibrations in various products? The first step is to identify the offending source and frequencies of concern, which in many cases arise from features outside of a product designer’s control. If the object or structure is simple enough, it may be possible to use isolation to shift a single critical natural frequency away from the excitation source frequency. However, for most practical product applications there are typically so many natural frequencies and dynamic loads that they all can’t be shifted; energy dissipation via damping is the only way control the dynamic response and reduce transmissibility.
Vibrations are both an essential phenomenon enabling us to interpret sounds and a potential detriment causing mechanical failures. Whether you’re building an engine, a cell phone, or a computer, vibrations can cause major mechanical problems. Unmanaged vibrations in a machine can lead to noise and ultimately breakdowns.
Contact us to discuss your requirements of preformed tension clamp. Our experienced sales team can help you identify the options that best suit your needs.
Vibrations are essentially back-and-forth type movements. Different objects and waves vibrate at varied frequencies, contributing to what engineers refer to as resonance, where specific frequencies trigger pronounced movements in objects or their parts. When certain objects or parts of objects encounter vibrations at these frequencies, it causes them to shake or move significantly.
Every object possesses one or more resonant frequencies. Engineering’s challenge is to ensure the natural frequencies of components don’t align with their resonant frequencies. When these frequencies match, it may result in accelerated wear or even complete failure of components. Thus, addressing resonance is paramount in engineering designs, especially in intricate constructs like cell phones and engines.
The job of an engineer is to ensure that the natural frequency of something is not the same as its resonant frequency. For instance, when you build an engine, you must make sure that its parts don’t vibrate at a frequency that will resonate with one or more other parts, making them move unnecessarily. An engine or other work of engineering that doesn’t take resonance into account can wear out quickly or even break down completely after a short time.
There are a couple of different ways to solve resonance problems. One way is to build an item differently so that its natural frequency and resonant frequency don’t match up. With some things, such as swinging bridges, this is essential and somewhat less complex, but with things like cell phones and engines, it can be terribly difficult. This is where vibration damping materials come in.
Vibration dampeners, often comprised of viscoelastic substances like Sorbothane®, have the properties of both a solid and a liquid. This kind of substance will absorb some of the energy from vibration, turning some of it into heat energy and storing some of it until the pressure is off. Since energy can’t be lost, it is transferred from one form to another.
This energy transfer is crucial in vibration damping. Substances like Sorbothane can act as a vibration dampener to absorb some of the vibration energy. Essentially it makes the frequency lower and reduces wear and tear on an engine or electronic part.
Learn more about how Sorbothane, Inc.’s solutions can meet your vibration damping needs. Contact us today to discuss your projects and products and explore the myriad of applications of our vibration damping solutions.
Want more information on tension clamp for earth wire? Feel free to contact us.