Energy absorbing assembly for passenger seats

That which is claimed is: 1. A passenger seat assembly, comprising: a frame configured to attach rigidly to a passenger compartment floor; a seat bottom connected with the frame and comprising an articulating seat pan connected with the seat back below a pivot axis of the seat back, such that the seat bottom moves aft in response to forward tilting of the seat back; a seat back pivotally connected with the frame and operable to recline; and a linkage comprising a recline lock for locking a recline position of the seat back, the linkage mechanically connected with one of the seat back and the frame by a first attachment element, and to the other of the seat back and the frame by a second attachment element, the linkage connected to the seat bottom by one of the first or second attachment elements and connected to the frame by the other of the first or second attachment elements, the linkage comprising an extended portion that extends through the second attachment element; and a crushable energy absorbing element mounted to the extended portion of the linkage between the second attachment element and second end of the linkage, the energy absorbing element positioned to receive compressive force between the second end of the linkage and the second attachment element in response to forward motion of the seat back. 2. The passenger seat assembly of claim 1 , wherein the seat back further comprises a breakaway fuse pivotally connecting a lower portion of the seat back with the seat bottom, the breakaway fuse configured to break and mechanically delink the seat back from the seat bottom when subjected to force in excess of a threshold. 3. The passenger seat assembly of claim 1 , wherein the crushable energy absorbing element is a cylindrical energy absorber comprising an internal opening sized to accommodate the linkage, a crushable matrix surrounding the internal opening, and an external shell containing the crushable matrix. 4. The passenger seat assembly of claim 1 , wherein the crushable energy absorbing element is positioned to abut the second attachment element at a first end of the energy absorbing element and to abut a flanged element of the linkage at a second end of the energy absorbing element opposite the first end. 5. The passenger seat assembly of claim 1 , wherein the crushable energy absorbing element has an initial length of from 2.5-25 cm (1-10″) and can compress by at least 60% of its initial length while absorbing energy. 6. The passenger seat assembly of claim 1 , wherein the crushable energy absorbing element absorbs energy by plastic deformation when subjected to a crushing force of 6.67 kN (1500 lb. force) in compression. 7. The passenger seat assembly of claim 6 , wherein the crushable energy absorbing element has an initial resistance to compression that is higher than the crushing force. 8. The passenger seat assembly of claim 1 , wherein the assembly is operable to compress the crushable energy absorbing element by pulling the extended portion of the linkage through the second attachment element when a top portion of the seat back is pushed forward with a force of 1.5 kN (350 lb. force). 9. The passenger seat assembly of claim 1 , wherein the crushable energy absorbing element is configured to deform in a first stage at a first rate, and in a second stage at a second rate that is slower and absorbs more energy than the first stage, the first and second stages corresponding to an increasing resistance to compression by the energy absorbing element as the energy absorbing element is compressed. 10. The passenger seat assembly of claim 1 , wherein the crushable energy absorbing element comprises a first section of crushable matrix configured to deform in a first stage when the energy absorbing element is subjected to a first compressive force, and a second section of crushable matrix configured to further deform in a second stage when subjected to a second compressive force exceeding the first compressive force, the first and second stages corresponding to an increasing resistance to compression by the energy absorbing element as the energy absorbing element is compressed. 11. The passenger seat assembly of claim 1 , wherein the seat back is limited to a 20 degree forward tilt from vertical. 12. The passenger seat assembly of claim 1 , wherein the frame comprises an energy absorbing strut comprising: a strut rod comprising a flanged element; a strut housing that receives the strut rod and further comprising a collar that circumscribe the strut rod at a nonzero distance from the flanged element; and a second energy absorbing element connected with the strut rod within the strut housing and maintained between the flanged element and the collar such that, in response to extension of the energy absorbing strut, the flanged element and collar act in compression on the second energy absorbing element. 13. The passenger seat assembly of claim 12 , wherein the second energy absorbing element comprises a second cylindrical energy absorber comprising a second crushable matrix. 14. A method of installing an energy absorbing element in a passenger seat, the method comprising: connecting a first end of a linkage comprising a recline lock with a seat bottom of the passenger seat by a first attachment element, wherein the seat bottom comprises an articulating seat pan connected with the seat back below a pivot axis of the seat back, such that the seat bottom moves aft in response to forward tilting of the seat back; connecting a second end of the linkage with a rigid frame of the passenger seat by a second attachment element, wherein one of the first or second ends of the linkage protrudes through the first or second attachment element forming an extended portion of the linkage; mounting a crushable energy absorbing element to the extended portion of the linkage beyond the one of the first or second attachment elements with respect to a remainder of the linkage; and connecting a distal end of the crushable energy absorbing element to the extended portion of the linkage such that the crushable energy absorbing element is maintained abutting the one of the first or second attachment elements and such that the crushable energy absorbing element is configured to receive compressive force by the one of the first or second attachment elements when the seat back is pushed forward. 15. The method of claim 14 , further comprising: removing a breakaway fuse from a joint between the seat back and seat bottom of the passenger seat.