Big gap element sealing system

What is claimed is: 1. A sealing system for use in a downhole tool, the sealing system comprising: a packing element including a groove in a surface thereof, the packing element adapted to form a double hump configuration upon compression and adapted to seal a gap between a casing string and the packing element in an uncompressed configuration that is greater than a cross sectional thickness of the packing element, wherein a ratio of the cross-sectional thickness of the gap to the pre-set cross-sectional thickness of the sealing element is from about 1.05 to about 2.0; a first ring member disposed on a mandrel and at a first end of the packing element; a second ring member disposed on the mandrel and at a second end of the packing element, wherein the first ring member and the second ring member each comprise a laterally outward surface disposed at an angle between 5 degrees to 20 degrees relative to perpendicular to the mandrel, the laterally outward surface of each of the first ring member and the second ring member extending from the mandrel to a respective radially-outward end of the first ring member and the second ring member; a first seal ring disposed laterally outward of the first ring member, wherein the laterally outward surface of the first ring member is adjacent the first seal ring; a second seal ring disposed laterally outward of the second ring member, wherein the laterally outward surface of the second ring member is adjacent the second seal ring; a first inner back-up ring disposed laterally outward of the first seal ring, the first inner back-up ring having slots; and a first outer back-up ring having slots, the first outer back-up ring disposed adjacent the first inner back-up ring, wherein the slots in the first outer back-up ring are offset from the slots in the first inner back-up ring. 2. The sealing system of claim 1 , further comprising: a second inner back-up ring disposed laterally outward of the second seal ring, the second inner back-up ring having slots; and a second outer back-up ring having slots, the second outer back-up ring disposed adjacent the second inner back-up ring, wherein the slots in the second outer back-up ring are offset from the slots in the second inner back-up ring. 3. The sealing system of claim 2 , further comprising: a fastener coupling the first inner back-up ring to the first outer back-up ring to prevent rotational movement therebetween. 4. The sealing system of claim 2 , wherein the slots in each of the first inner back-up ring, the second inner back-up ring, the first outer back-up ring, and the second outer back-up ring are disposed circumferentially therearound. 5. The sealing system of claim 2 , wherein the first inner back-up ring and the second inner back-up ring include shoulders disposed therearound, and wherein the shoulder of the first inner back-up ring has a first thickness greater than a thickness of the remaining portions of the first inner back-up ring. 6. The sealing system of claim 2 , further comprising: a first cone member coupled to the first inner back-up ring and the first outer back-up ring by a first shearable fastener; and a second cone member coupled to the second inner back-up ring and the second outer back-up ring by a second shearable fastener. 7. A liner string, comprising: the sealing system of claim 6 disposed along the mandrel, the mandrel having a profile formed in an inner surface thereof for releasable connection to a running tool; a liner hanger disposed along the mandrel; and a polished bore receptacle connected to the first cone member. 8. A method of hanging a liner string of claim 7 from a tubular string cemented in a wellbore, comprising: running the liner string into a wellbore using a workstring having a deployment assembly, wherein the deployment assembly comprises a setting tool, a running tool, a catcher, and a plug release system: setting the liner hanger against the tubular string by pumping a setting plug to the catcher; after setting the hanger, releasing the running tool from the mandrel; after releasing the running tool, pumping cement slurry through the workstring followed by a release plug, wherein the release plug engages a wiper plug of the plug release system and drives the cement slurry through the liner string and into an annulus formed between the liner string and the wellbore; and raising the deployment assembly and setting weight on the polished bore receptacle using the setting tool, thereby: radially expanding a packing element and sealing a gap formed between the sealing system and the tubular string, wherein radially expanding the packing element results in the packing element forming a double hump configuration, and wherein a distance of the gap is greater than a cross sectional thickness of the packing element; and radially expanding the back-up rings into contact with the tubular string. 9. The method of claim 8 wherein: the groove in the packing element causes upper and lower sections of the packing element to expand into the gap. 10. The sealing system of claim 2 , wherein the first outer backup ring and the second outer back up ring are configured to contact the casing upon compression. 11. The sealing system of claim 2 , wherein the first inner backup ring, the second inner backup ring, the first outer backup ring, and the second outer backup ring each include a shoulder, wherein the shoulder of the first inner backup ring has a thickness greater than the shoulder of the first outer backup ring, and wherein the shoulder of the second inner backup ring has a thickness greater than the shoulder of the second outer backup ring. 12. The sealing system of claim 2 , wherein the first inner backup ring, the second inner backup ring, the first outer backup ring, and the second outer backup ring each include a shoulder, and wherein the shoulder of the first inner backup ring has a thickness greater than remaining portions of the first inner backup ring, and wherein the shoulder of the first outer backup ring has a thickness greater than remaining portions of the first outer backup ring. 13. The sealing system of claim 12 , wherein the shoulder of the second inner backup ring has a thickness greater than remaining portions of the second inner backup ring, and wherein the shoulder of the first outer backup ring has a thickness greater than remaining portions of the first outer backup ring. 14. The sealing system of claim 1 , wherein the first inner back-up ring extends axially towards the packing element further than the first outer back-up ring. 15. The sealing system of claim 1 , wherein the packing element has a lower durometer than the first seal ring and the second seal ring. 16. The sealing system of claim 1 , wherein the first outer backup ring is configured to contact the casing upon compression. 17. The sealing system of claim 1 , wherein the first ring member is spaced from both the first inner back-up ring and the first outer back-up ring when the packign element is in an uncopmressed configuration, and the second ring member is spaced from both the second inner back-up ring and the second outer back-up ring when the packign element is in an uncopmressed configuration. 18. A sealing system for use in a downhole tool, the downhole tool being disposed in a casing such that a gap is formed between the downhole tool and the casing, the sealing system comprising: a packing element with a first end and a second end, the packing element disposed on a mandrel and having a pre-set cross-sectional thickness t