Spring isolators and suspension systems incorporating same

What is claimed is: 1. A spring isolator for a wheel suspension, comprising: a first side configured to rest on a spring plate of the suspension; and a second side, opposite the first side, configured to receive a last coil of a coil spring of the suspension to support the coil spring on the spring plate; wherein the first side has at least one cavity extending through a thickness of the isolator toward the second side, the at least one cavity having an opening configured to allow air to escape from the cavity when a force is applied to the spring isolator, or flow into the cavity upon removal of the force from the spring isolator, wherein an elasticity of the isolator between the first and second sides prevents the last coil from breaking contact with the second side during operation of the suspension, and wherein the elasticity of the isolator is defined by a length, width, and/or depth of the at least one cavity. 2. The spring isolator of claim 1 , wherein the spring isolator is made of a rubber material. 3. The spring isolator of claim 1 , wherein the at least one cavity comprises a plurality of cavities separated from each other by a partition. 4. The spring isolator of claim 3 , wherein the elasticity of the isolator is further defined by a length and/or thickness of the partition. 5. The spring isolator of claim 1 , wherein the first side includes a channel. 6. The spring isolator of claim 5 , wherein the elasticity of the isolator is further defined by a width and/or a depth of the channel. 7. The spring isolator of claim 1 , wherein the second side includes a channel configured to receive and at least partially surround the last coil. 8. The spring isolator of claim 7 , wherein the channel includes a wall at least partially along one side of the channel, the wall having a first face configured to receive and at least partially surround the last coil. 9. The spring isolator of claim 8 , wherein the wall has a second face, opposite the first face, the second face having a chamfered edge. 10. The spring isolator of claim 1 , wherein the spring isolator has a geometric design that, when placed on the spring plate, pretensions the first and second sides of the isolator in an axial direction of the coil spring. 11. The suspension of claim 1 , wherein the at least one cavity has an oval shape that is elongated along a circumferential direction of the spring isolator. 12. A wheel suspension, comprising: a coil spring; a spring plate; and a spring isolator positioned between the coil spring and the spring plate, the spring isolator comprising first and second opposite sides, wherein the first side rests on the spring plate and the second side supports a last coil of the coil spring, wherein the first side has at least one cavity extending through a thickness of the spring isolator toward the second side, the at least one cavity being configured to maintain contact between the last coil and the second side during operation of the suspension and having an opening configured to allow air to escape from the cavity when a force is applied to the spring isolator, or flow into the cavity upon removal of the force from the spring isolator, and wherein an elasticity of the spring isolator between the first and second sides is defined by a length, width, and/or depth of the at least one cavity. 13. The suspension of claim 12 , wherein the at least one cavity comprises a plurality of cavities separated from each other by a partition. 14. The suspension of claim 13 , wherein the elasticity of the isolator is further defined by a length and/or thickness of the partition. 15. The suspension of claim 12 , wherein the at least one cavity has an oval shape that is elongated along a circumferential direction of the spring isolator. 16. A method for maintaining contact between a coil spring and a spring isolator under a vertical force on the spring, the method comprising: during application of the force, expanding a material forming the spring isolator into a cavity within the isolator to increase an elasticity of the isolator; purging air from the cavity via an opening extending through a wall forming the cavity; and following spring movements of the coil spring with the spring isolator such that a contact surface area between the isolator and the spring remains constant. 17. The method of claim 16 , wherein expanding the material forming the spring isolator into the cavity comprises expanding a rubber material forming the spring isolator into the cavity. 18. The method of claim 17 , wherein following the movements of the coil spring with the spring isolator comprises bending the rubber material via the increased elasticity. 19. A spring isolator for a wheel suspension, comprising: a first side configured to rest on a spring plate of the suspension; and a second side, opposite the first side, configured to receive a last coil of a coil spring of the suspension to support the coil spring on the spring plate; wherein the first side has a plurality of cavities extending through a thickness of the isolator toward the second side, each of the plurality of cavities being elongated along a circumferential direction of the spring isolator such that a length of each cavity along the circumferential direction of the spring isolator is greater than a width of each cavity along a radial direction of the spring isolator, and wherein an elasticity of the isolator between the first and second sides prevents the last coil from breaking contact with the second side during operation of the suspension. 20. The spring isolator of claim 19 , wherein the plurality of cavities are separated from each other by a partition, wherein the elasticity of the isolator is defined by a length, width, and/or depth of each of the plurality of cavities and by a length and/or thickness of the partition. 21. The spring isolator of claim 19 , wherein at least one of the plurality of cavities has an oval shape. 22. A method of maintaining contact between a coil spring and a spring isolator, comprising: during application of a force to the spring: increasing an elasticity of the isolator by deforming a portion of the isolator into a cavity within the isolator; and purging air from the isolator via an opening extending through a wall forming the cavity, wherein increasing the elasticity maintains a substantially constant area of contact between the isolator and the spring.