Double-acting shock damper for a downhole assembly

What is claimed is: 1. A downhole assembly, including: a downhole tool; a downhole force-creating device; and a shock damper including: a hollow housing including an annular housing shoulder near each end and extended radially inward from the housing; a mandrel located at least partially inside the housing to form an annulus between the mandrel and the housing, the mandrel including an annular mandrel shoulder near each end and extended radially outward from the mandrel; a spring located in an annular cavity defined by the annulus and between both the annular housing shoulders and the annular mandrel shoulders; a first annular piston located in the annular cavity between a first end of the spring and one annular housing shoulder, wherein the first annular piston is configured to seal against the housing and the mandrel; a second annular piston located in the annular cavity between a second end of the spring and the other annular housing shoulder, wherein the second annular piston is configured to seal against the housing and the mandrel; the mandrel being movable relative to the housing to an expanded position in one direction and to a compressed position in the other direction; the spring being compressible by one of the annular housing shoulders on one end and one of the annular mandrel shoulders on the opposite end as the mandrel moves between the expanded and compressed positions, the compression of the spring resisting relative movement between the mandrel and the housing and absorb the force moving the mandrel; wherein the first annular piston or the second annular piston includes a check valve configured to allow one way fluid communication through the first annular piston or the second annular piston into the annular cavity; and wherein the first annular piston or the second annular piston includes a port configured to allow fluid communication into and out of the annular cavity. 2. The downhole assembly of claim 1 , wherein the annular housing shoulders are formed by shoulder ends attached to each end of the housing, the shoulder ends having a smaller internal dimension than the housing. 3. The downhole assembly of claim 1 , wherein one annular mandrel shoulder is formed on the mandrel itself and another annular mandrel shoulder is formed on a mandrel extension attached to the mandrel. 4. The downhole assembly of claim 1 , wherein the spring includes a stack of Belleville springs. 5. The downhole assembly of claim 1 , wherein the annular cavity is fluid-filled and a piston includes a port that can control the flow of fluid through the piston into and out of the cavity so as to affect the dynamic response of the spring. 6. The downhole assembly of claim 5 , wherein the pressure of the fluid in annular cavity is balanced with hydrostatic pressure. 7. A method of dampening a shock transferred to a downhole assembly, including: transferring a force from the shock to a mandrel located at least partially inside a hollow housing to move the mandrel relative to the housing between an expanded position in one direction and to a compressed position in the other direction; resisting the movement of the mandrel between both the expanded position and the compressed position by compressing a spring to dampen the shock transferred to the downhole assembly; resisting the movement of the mandrel in both the expanded position and the compressed position by flowing a fluid through a port extending through a first annular piston located in the housing between an end of the spring and an annular shoulder of the housing, wherein the first annular piston is configured to seal against the housing and the mandrel; and allowing one way fluid communication through a check valve of a second annular piston located in the housing, wherein the second annular piston is configured to seal against the housing and the mandrel. 8. The method of claim 7 , wherein the force is created by activating a downhole force-creation device. 9. The method of claim 7 , wherein the spring is located in a fluid-filled cavity, the method further including balancing the fluid in the cavity with hydrostatic pressure. 10. The method of claim 9 , further comprising controlling the rate of fluid flow into and out of the cavity as the spring compresses to affect the dynamic response of the spring. 11. The method of claim 7 , further including transferring the force from actuating a downhole force-creating device. 12. The method of claim 7 , further including: positioning the mandrel and housing coaxially; and resisting the movement of the mandrel as it moves axially in both directions between the expanded and compressed positions. 13. A shock damper for a downhole force-creating device, the shock damper including: a hollow housing including an annular housing shoulder near each end and extended radially inward from the housing; a mandrel located at least partially inside the housing to form an annulus between the mandrel and the housing, the mandrel including an annular mandrel shoulder near each end and extended radially outward from the mandrel; a spring located in an annular cavity defined by the annulus and between both the annular housing shoulders and the annular mandrel shoulders; a first annular piston located in the annular cavity between a first end of the spring and one annular housing shoulder, wherein the first annular piston is configured to seal against the housing and the mandrel a second annular piston located in the annular cavity between a second end of the spring and the other annular housing shoulder, wherein the second annular piston is configured to seal against the housing and the mandrel; the mandrel being movable relative to the housing to an expanded position in one direction and to a compressed position in the other direction; the spring being compressible by one of the annular housing shoulders on one end and one of the annular mandrel shoulders on the opposite end as the mandrel moves between the expanded and compressed positions, the compression of the spring resisting relative movement between the mandrel and the housing and absorb the force moving the mandrel; wherein one of the annular pistons includes a check valve configured to allow one way fluid communication through the annular piston into the annular cavity; and wherein one of the annular pistons includes a port configured to allow fluid communication into and out of the annular cavity. 14. The shock damper of claim 13 , wherein the annular housing shoulders are formed by shoulder ends attached to each end of the housing, the shoulder ends having a smaller internal dimension than the housing. 15. The shock damper of claim 13 , wherein one annular mandrel shoulder is formed on the mandrel itself and another annular mandrel shoulder is formed on a mandrel extension attached to the mandrel. 16. The shock damper of claim 13 , wherein the spring includes a stack of Belleville springs. 17. The shock damper of claim 13 , wherein the annular cavity is fluid-filled and a piston includes a port that can control the flow of fluid through the piston into and out of the cavity so as to affect the dynamic response of the spring. 18. The shock damper of claim 17 , wherein the pressure of the fluid in annular cavity is balanced with hydrostatic pressure.