System and method for measuring a force on a jack assembly

What is claimed is: 1. A jack assembly, comprising: a body; a lifting piston positioned at least partially above the body and configured to move up and down with respect to the body; a lock collar positioned at least partially around the lifting piston, wherein the lifting piston and the lock collar are configured to move up such that a first gap is formed between the lock collar and the body; a load cell positioned at least partially around the lifting piston and between the body and the lock collar, wherein the load cell is positioned in the first gap between the lock collar and the body; and a load distribution plate positioned at least partially around the lifting piston, wherein the load distribution plate is positioned above the body and below the lock collar, wherein a second gap is present between the load distribution plate and the load cell when the load cell is positioned at least partially around the lifting piston, wherein the jack assembly is configured to support an object, which exerts a downward force onto the lifting piston, and wherein the downward force is transferred from the lifting piston to the lock collar to the load cell to the body, wherein the load cell measures the downward force, and wherein the load cell is not able measure the downward force of the object when the second gap is present. 2. The jack assembly of claim 1 , wherein the lifting piston and the lock collar are configured to move vertically while the body and the load cell remain vertically stationary. 3. The jack assembly of claim 1 , wherein the load cell is substantially U-shaped and includes a circumferential gap. 4. The jack assembly of claim 1 , wherein the load cell is configured to be moved into position at least partially around the lifting piston while the jack assembly supports the object. 5. The jack assembly of claim 1 , wherein a vertical gap is present between the lock collar and the load cell when the load cell is moved into position at least partially around the lifting piston, and wherein the load cell is not able to measure the downward force when the vertical gap is present. 6. The jack assembly of claim 5 , wherein the lock collar is configured to move down into contact with the load cell after the load cell is moved into position, and wherein the load cell is configured to measure the downward force when the lock collar is in contact with the load cell. 7. The jack assembly of claim 1 , wherein the load cell is configured to be removed from the lifting piston while the jack assembly supports the object. 8. The jack assembly of claim 1 , wherein the load cell does not comprise inner threads that engage with the outer threads of the lifting piston. 9. The jack assembly of claim 1 , wherein the load distribution plate does not comprise inner threads that engage with the outer threads of the lifting piston. 10. A jack assembly configured to support an object, the jack assembly comprising: a body comprising: a central cylinder defining a vertical bore therein; and a plurality of legs that are circumferentially offset around the central cylinder; a lifting piston positioned at least partially in the vertical bore of the central cylinder, wherein the lifting piston defines a vertical bore therein, and wherein the lifting piston is configured to hydraulically move up and down with respect to the body; an extension screw positioned at least partially in the vertical bore of the lifting piston, wherein the extension screw comprises outer threads that are engaged with inner threads of the lifting piston, and wherein the extension screw is configured to mechanically move up and down with respect to the lifting piston in response to rotating the extension screw with respect to the lifting piston; a lock collar positioned at least partially around the lifting piston, wherein the lock collar comprises inner threads that are engaged with outer threads of the lifting piston, and wherein the lock collar is configured to mechanically move up and down with respect to the lifting piston in response to rotating the lock collar with respect to the lifting piston; a load distribution plate positioned at least partially around the lifting piston and between the body and the lock collar, wherein the load distribution plate comprises a single annular plate or two or more plate portions that are configured to be coupled together; and a load cell positioned at least partially around the lifting piston and between the body and the load distribution plate, wherein the load cell comprises a single annular cell, a single substantially U-shaped cell, or two or more cell portions that are configured to be coupled or hinged together; wherein, in response to the object exerting a downward force onto the lifting piston, the extension screw, or both, the downward force is transferred from the lifting piston to the lock collar to the load distribution plate to the load cell to the body, and wherein the load cell measures the downward force. 11. The jack assembly of claim 10 , wherein the load cell is substantially U-shaped and includes a circumferential gap, and wherein the load cell is configured to be positioned at least partially around the lifting piston while the lock collar and the load distribution plate are positioned at least partially around the lifting piston. 12. The jack assembly of claim 10 , further comprising a housing positioned at least partially between the body and the load distribution plate, wherein the housing comprises: a first plate; a second plate positioned below the first plate; and a lifting device configured to lift the first plate with respect to the second plate, which lifts the load distribution plate and thereby creates a vertical gap between the body and the load distribution plate, and wherein the load cell is configured to be introduced into the vertical gap, removed from the vertical gap, or both. 13. The jack assembly of claim 10 , wherein the load cell is configured to be positioned at least partially around the lifting piston while the jack assembly supports the object. 14. The jack assembly of claim 10 , wherein the load cell is configured to be removed from the lifting piston while the jack assembly supports the object. 15. A method for measuring a downward force exerted by an object on a jack assembly, the method comprising: positioning a lock collar at least partially around a lifting piston; raising the lifting piston and the lock collar such that a first gap is formed between the lock collar and a body; positioning a load cell at least partially around the lifting piston, wherein the load cell is positioned in the first gap between the lock collar and the body; and positioning a load distribution plate at least partially around the lifting piston, wherein the load distribution plate is positioned above the body and below the lock collar, wherein a second gap is present between the load distribution plate and the load cell when the load cell is positioned at least partially around the lifting piston, and wherein the load cell is not able measure the downward force of the object when the second gap is present. 16. The method of claim 15 , further comprising lowering the lifting piston, the lock collar, and the load distribution plate after the load cell is positioned at least partially around the lifting piston until the load distribution plate is in contact with the load cell. 17. The method of claim 16 , further comprising: supporting the object with the lifting piston such that the object exerts the downward force on the lifting piston, w