Vibration isolator assemblies and methods for the manufacture thereof

What is claimed is: 1. A method for manufacturing a vibration isolator assembly, the vibration isolator assembly comprising at least one bellows component, a piston component, a shaft component, and a housing component, the method comprising: forming at least one of the at least one bellows component, the piston component, the shaft component, and the housing component using additive manufacturing techniques, wherein the at least one bellows component is defined as comprising a plurality of lengthwise-extending segments that alternate in succession lengthwise between: (1) a radially inwardly extending segment, and (2) a radially outwardly extending segment, wherein each radially inwardly extending segment is contiguously and physically connected to a radially outwardly extending segment at an apex that has an angle of curvature opening radially inwardly toward a longitudinal axis that passes centrally through the at least one bellows component, and wherein at least a portion of a first apex-connected radially inwardly extending segment/radially outwardly extended segment pairing has a wall thickness that is greater than a wall thickness of at least a portion of a second apex-connected radially inwardly extending segment/radially outwardly extended segment pairing such that the bellows comprises a gradually tapering wall thickness distribution for stress distribution in the bellows, wherein the at least one bellows component has a first longitudinal end and a second longitudinal end, and wherein a first bellows opening at the first longitudinal end has a diameter that is substantially the same as a diameter of a second bellows opening at the second longitudinal end, wherein the longitudinal axis passes through both of the first and second bellows openings; and assembling the at least one bellows component, the piston component, the shaft component, and the housing component into a complete vibration isolator assembly, wherein the at least one bellows component is formed using additive manufacturing techniques, and wherein the at least one bellows component is formed so as to comprise a variable radius of curvature, wherein variable radius of curvature is defined as the apex of one apex-connected radially inwardly extending segment/radially outwardly extended segment pairing having its radially inwardly opening angle of curvature being greater than the radially inwardly opening angle of curvature of another apex-connected radially inwardly extending segment/radially outwardly extended segment pairing. 2. The method of claim 1 , wherein the additive manufacturing techniques comprise direct metal laser sintering. 3. The method of claim 1 , wherein the at least one bellows component is formed so as to comprise a variable aspect ratio, wherein variable aspect ratio is defined as the lengthwise length of one apex-connected radially inwardly extending segment/radially outwardly extended segment pairing being greater than the lengthwise length of another apex-connected radially inwardly extending segment/radially outwardly extended segment pairing. 4. A vibration isolator assembly, comprising: a bellows component; a piston connected to the bellows component; a shaft connected to the piston component; and a housing component surrounding one or more of the bellows, piston, and shaft components, wherein the bellows component comprises a plurality of lengthwise-extending segments that alternate in succession lengthwise between: (1) a radially inwardly extending segment, and (2) a radially outwardly extending segment, wherein each radially inwardly extending segment is contiguously and physically connected to a radially outwardly extending segment at an apex that has an angle of curvature opening radially inwardly toward a longitudinal axis that passes centrally through the at least one bellows component, and wherein at least a portion of a first apex-connected radially inwardly extending segment/radially outwardly extended segment pairing has a wall thickness that is greater than a wall thickness of at least a portion of a second apex-connected radially inwardly extending segment/radially outwardly extended segment pairing such that the bellows comprises a gradually tapering wall thickness distribution for stress distribution in the bellows, wherein the bellows component has a first longitudinal end and a second longitudinal end, and wherein a first bellows opening at the first longitudinal end has a diameter that is substantially the same as a diameter of a second bellows opening at the second longitudinal end, wherein the longitudinal axis passes through both of the first and second bellows openings, wherein the bellows component is formed using additive manufacturing techniques, and wherein the bellows component comprises a variable radius of curvature, wherein variable radius of curvature is defined as the apex of one apex-connected radially inwardly extending segment/radially outwardly extended segment pairing having its radially inwardly opening angle of curvature being greater than the radially inwardly opening angle of curvature of another apex-connected radially inwardly extending segment/radially outwardly extended segment pairing. 5. The vibration isolator assembly of claim 4 , wherein the bellows component comprises a variable aspect ratio, wherein variable aspect ratio is defined as the lengthwise length of one apex-connected radially inwardly extending segment/radially outwardly extended segment pairing being greater than the lengthwise length of another apex-connected radially inwardly extending segment/radially outwardly extended segment pairing. 6. The vibration isolator assembly of claim 5 , wherein the bellows component and at least one of the piston component, the shaft component, and the housing component are formed as an integral structure using additive manufacturing techniques. 7. The vibration isolator assembly of claim 6 , wherein the bellows component and at least one of the piston component, the shaft component, and the housing component are formed as an integral structure using direct metal laser fusion. 8. The method of claim 3 , wherein a first portion of the at least one bellows component is formed with a first metallic material and a second portion of the at least one bellows component is formed with a second metallic material that is different from the first metallic material.