By submitting this form, you are agreeing to the Terms of Use and Privacy Policy.
In industrial, electrical, structural, and ergonomic applications where resonance and vibration are present, vibration dampening material is utilized to minimize or eliminate noise. Our viscoelastic polymer, Sorbothane, has been employed in a variety of products, including small appliances and protective footwear.
In ergonomic, industrial, and electrical applications where it is necessary to reduce the amount of energy a system produces, the term “vibration damping” is employed. After a vibration has been dampened, energy is sent through the proper channels, which reduces the propagation of noise.
Numerous factors can make vibration undesirable. It could appear as a little irritation or as a potentially disastrous environmental component. Our solutions at Technicon Acoustics use a variety of dampening materials to ensure that vibration is stopped before it becomes a problem.
The details of their intended application dictate which material is acceptable for vibration damping. The following are some of the most popular vibration-damping materials: Rubber is the perfect material for applications requiring vibration dampening.
It swiftly isolates vibration by absorbing energy and then releasing it as heat back into the environment. Even though it lacks true damping properties by itself, it can be an effective tool when combined with other materials. Rubber is a great material for absorbing vibration energy since it absorbs energy and releases it as heat while also having low vibration dampening effects.
The Global Vibration damping materials market accounted for $XX Billion in 2022 and is anticipated to reach $XX Billion by 2030, registering a CAGR of XX% from 2023 to 2030.
Small satellites can be made better, faster, cheaper, and lighter by using whole-spacecraft. International Fabreeka, Inc. launch-vibration damping materials using vibration isolation technologies, which do this by lowering the design-load and vibration-test requirements for on-board components.
Using superelastic shape memory alloy technology, a three-axis passive launch-vibration isolation device was created in this work to drastically reduce the dynamic launch loads conveyed to a tiny satellite.
This results in a superior damping characteristic, which is made possible by multilayered thin plates of viscous lamina sticky acrylic tape stiffening superelastic SMA blades.
A static stress test was used to determine the fundamental properties of the proposed isolation system with different numbers of viscoelastic multilayers. Additionally, a launch environment simulating sine and random vibration tests was used to verify the design’s efficacy.
