If you have a suspended floor with standard joists, and you use an efficient isolation system there is something I’d like to share that I became aware of.
The suspended mass will cause some compression on the floor joists, and when there is energy against the isolation system, it will also cause the flexible floor to accept a portion of the energy. (foot falls, and speakers being major culprits)
The floor, and the isolation device of choice will share the energy between them, proportional to their spring rate or Young’s modulus.
The best results I have found is by using as close to a zero stiffness (in my case wire springs) device on a very rigid substrate, where the substrate doesn’t easily deform and the energy is mostly controlled by the isolator.
What is zero stiffness? This is the easier concept to digest that I could find, "a zero stiffness structure maintains a constant potential energy, which is continuously redistributed as the structure deforms, thus eliminating any preferred position under the applied load or self-stress."
Spring steel with an engineered geometry (a manufactured spring) is one of the most efficient means of achieving this. It is the most popular device used in platforms used under electron microscopes and imaging devices used in science and medicine today. 4Hz isolation devices using passive technology use varying types of spring structures.
The goal is to hold the load, but also have the ability to accept and change shape from vibration at the minutest amount and smooth out a broad range of both frequencies and amplitudes of those frequencies - just like springs used under vehicles of every type.
Mass loading under a sprung system on floor joists may help compress by loading the floor and reduce it’s percentage of the vibration sharing, pushing a higher percentage of the energy into the isolators (preferably springs), thus performing more of the work.
The smallest amount of energy that is possibly isolated with the broadest range of frequencies and amplitude is going to work best on as rigid a base structure and a rigid object that is being isolated.
The isolated object should move easily on the device it’s isolated upon, if not easily moved, like a bobble head toy, then you know it’s not flexible and also not as isolated as it could be.
www.minusk.com
The suspended mass will cause some compression on the floor joists, and when there is energy against the isolation system, it will also cause the flexible floor to accept a portion of the energy. (foot falls, and speakers being major culprits)
The floor, and the isolation device of choice will share the energy between them, proportional to their spring rate or Young’s modulus.
The best results I have found is by using as close to a zero stiffness (in my case wire springs) device on a very rigid substrate, where the substrate doesn’t easily deform and the energy is mostly controlled by the isolator.
What is zero stiffness? This is the easier concept to digest that I could find, "a zero stiffness structure maintains a constant potential energy, which is continuously redistributed as the structure deforms, thus eliminating any preferred position under the applied load or self-stress."
Spring steel with an engineered geometry (a manufactured spring) is one of the most efficient means of achieving this. It is the most popular device used in platforms used under electron microscopes and imaging devices used in science and medicine today. 4Hz isolation devices using passive technology use varying types of spring structures.
The goal is to hold the load, but also have the ability to accept and change shape from vibration at the minutest amount and smooth out a broad range of both frequencies and amplitudes of those frequencies - just like springs used under vehicles of every type.
Mass loading under a sprung system on floor joists may help compress by loading the floor and reduce it’s percentage of the vibration sharing, pushing a higher percentage of the energy into the isolators (preferably springs), thus performing more of the work.
The smallest amount of energy that is possibly isolated with the broadest range of frequencies and amplitude is going to work best on as rigid a base structure and a rigid object that is being isolated.
The isolated object should move easily on the device it’s isolated upon, if not easily moved, like a bobble head toy, then you know it’s not flexible and also not as isolated as it could be.
www.minusk.com