Multi-stage damping assembly

What is claimed is: 1. An assembly for multi-stage damping comprising; a damping unit ( 20 ) including a wall ( 22 ) defining an inner surface and an outer surface extending about an axis (A) between a base portion ( 24 ) and a top portion ( 26 ); a partition ( 28 ) spaced between said base portion ( 24 ) and said top portion ( 26 ) and extending from said inner surface of said wall ( 22 ) defining a first chamber ( 30 ) between said partition ( 28 ) and said top portion ( 26 ) and a second chamber ( 32 ) between said partition ( 28 ) and said base portion ( 24 ), said partition ( 28 ) having an internal holding wall ( 34 ) defining a holding chamber ( 35 ); a decoupler ( 36 ) is disposed within said holding chamber ( 35 ) and has a radius extending between a center point (C) and an outer ring ( 38 ), said outer ring ( 38 ) engaging said internal holding wall ( 34 ), said decoupler ( 36 ) having a first surface ( 40 ) opposite a second surface ( 42 ) for preventing fluid transfer between said chambers ( 30 , 32 ); said decoupler ( 36 ) defining a circular zone ( 68 ) extending about said center point (C) for flexing between said chambers ( 30 , 32 ); and said decoupler ( 36 ) defining an annular zone ( 70 ) surrounding said circular zone ( 68 ) extending inwardly from said outer ring ( 38 ) to define a ring shape whereby said annular zone ( 70 ) flexes between a first mode and a second mode with said first mode being defined as said annular zone ( 70 ) flexing with said circular zone ( 68 ) to maximize the potential volume of displacement and said second mode being defined as said annular zone ( 70 ) flexing independently of said circular zone ( 68 ) to decrease the potential volume of displacement of said decoupler ( 36 ) between said first chamber ( 30 ) and said second chamber ( 32 ). 2. An assembly as set forth in claim 1 wherein said decoupler ( 36 ) includes an interior ring ( 54 ) spaced between said outer ring ( 38 ) and said circular zone ( 68 ) and said interior ring ( 54 ) extends annularly about said center point (C) and extends axially from said first surface ( 40 ) and extends axially from said second surface ( 42 ). 3. An assembly as set forth in claim 2 wherein said outer ring ( 38 ) extends axially from said first surface ( 40 ) and extends axially from said second surface ( 42 ) a greater axial distance than said interior ring ( 54 ) extends axially for spacing said partition ( 28 ) from said interior ring ( 54 ) to define an axial travel limit of said interior ring ( 54 ). 4. An assembly as set forth in claim 3 wherein said decoupler ( 36 ) includes an intermediate ring ( 46 ) spaced between said outer ring ( 38 ) and said interior ring ( 54 ) and said intermediate ring ( 46 ) extends annularly about said center point (C) and extends axially from said first surface ( 40 ) and extends axially from said second surface ( 42 ). 5. An assembly as set forth in claim 4 wherein said interior ring ( 54 ) extends axially from said first surface ( 40 ) and extends axially from said second surface ( 42 ) a greater axial distance than said intermediate ring ( 46 ) extends axially. 6. An assembly as set forth in claim 5 wherein said intermediate ring ( 46 ) and said outer ring ( 38 ) define a first groove ( 50 ) therebetween on said first surface ( 40 ) and a second groove ( 52 ) therebetween on said second surface ( 42 ) with each of said first groove ( 50 ) and said second groove ( 52 ) having a semi-circular cross section for adding flexibility to said annular zone ( 70 ). 7. An assembly as set forth in claim 6 wherein said interior ring ( 54 ) and said intermediate ring ( 46 ) define a third groove ( 56 ) therebetween on said first surface ( 40 ) and a fourth groove ( 58 ) therebetween on said second surface ( 42 ) with each of said third groove ( 56 ) and said fourth groove ( 58 ) having a semi-circular cross section for adding flexibility to said annular zone ( 70 ). 8. An assembly as set forth in claim 7 including a vacuum source ( 80 ) in fluid communication with said first chamber ( 30 ) for depressurizing said first chamber ( 30 ) in said second mode ( 74 ) and pulling and keeping said circular zone ( 68 ) into said first chamber ( 30 ) at maximum displacement and pressing said interior ring ( 54 ) against said partition ( 28 ) to decrease the potential volume of displacement to said annular zone ( 70 ) between said outer ring ( 38 ) and said interior ring ( 54 ). 9. An assembly as set forth in claim 3 including a retainer ( 64 ) having an annular shape for securing said decoupler ( 36 ) in said holding chamber. 10. An assembly as set forth in claim 9 wherein said retainer ( 64 ) includes a plurality of arms ( 66 ) extending towards said axis (A) terminating at and extending along said interior ring ( 54 ) to define an axial travel limit of said interior ring ( 54 ) of said annular zone ( 70 ) along said axis (A) towards said second chamber ( 32 ). 11. An assembly for multi-stage damping comprising; a decoupler ( 36 ) having a radius extending between a center point (C) and an outer ring ( 38 ) and having a first surface ( 40 ) opposite a second surface ( 42 ), a central elastomer membrane ( 62 ) extending about said center point (C), said decoupler ( 36 ) defining a circular zone ( 68 ) extending about said center point (C) and an annular zone ( 70 ) including a plurality of rings ( 38 , 46 , 54 ) extending axially from said first surface ( 40 ) and extending axially from said second surface ( 42 ) and extending annularly about said central elastomer membrane ( 62 ) and separated by grooves ( 50 , 52 , 56 , 58 ) in said first surface ( 40 ) and said second surface ( 42 ) between said outer ring ( 38 ) and said central elastomer membrane ( 62 ), and wherein said annular zone ( 70 ) flexes between a first mode and a second mode with said first mode being defined as said annular zone ( 70 ) flexing with said circular zone ( 68 ) to maximize the potential volume of displacement and said second mode being defined as said annular zone ( 70 ) flexing independently of said circular zone ( 68 ) to decrease the potential volume of displacement of said decoupler ( 36 ) between said first chamber ( 30 ) and said second chamber ( 32 ). 12. An assembly as set forth in claim 11 wherein said plurality of rings ( 38 , 46 , 54 ) includes an interior ring ( 54 ) spaced between said outer ring ( 38 ) and said central elastomer membrane ( 62 ) and said interior ring ( 54 ) extends annularly about said center point (C) and extends axially from said first surface ( 40 ) and extends axially from said second surface ( 42 ). 13. An assembly as set forth in claim 12 wherein said outer ring ( 38 ) extends axially from said first surface ( 40 ) and extends axially from said second surface ( 42 ) a greater axial distance than said interior ring ( 54 ). 14. An assembly as set forth in claim 13 wherein said plurality of rings ( 38 , 46 , 54 ) includes an intermediate ring ( 46 ) spaced between said outer ring ( 38 ) and said interior ring ( 54 ) and said intermediate ring ( 46 ) extends annularly about said center point (C) and extends axially from said first surface ( 40 ) and extends axially from said second surface ( 42 ). 15. An assembly as set forth in claim 14 wherein said interior ring ( 54 ) extends axially from said first surface ( 40 ) and extends axially from said second surface ( 42 ) a greater axial distance than said intermediate ring ( 46 ). 16. An assembly as set forth in claim 15 wherein said interior ring ( 54 ) includes a lip ( 60 ) extending along said interior ring ( 54 ) towar