Method and a system for supporting a frame of a mineral material crusher and a crushing plant

The invention claimed is: 1. A method for supporting a frame of a mineral material crusher on a body of a crushing plant, the method comprising: supporting the frame of the crusher on the body of the crushing plant at two first support points with two first support devices; supporting the frame of the crusher is on the body of the crushing plant at two second support points with two second support devices, wherein the second support points are located a distance from the first support points; and performing adjustments to vertical position of the second support points relative to each other with an adjusting member of each of the second support devices to thereby reduce undesired twisting in the frame of the crusher; wherein each adjusting member comprises a cylinder and a piston adapted inside the cylinder, a mechanically acting adjusting member, or an electromechanically acting adjusting member. 2. The method according to the claim 1 , wherein the piston and the cylinder of each adjusting member define an adjusting volume therebetween in which a pressure is formed from a load acting on the adjusting member. 3. The method according to claim 2 , wherein each adjusting member of the second support devices supports the frame of the crusher. 4. The method according to claim 2 , further comprising: connecting the adjusting volumes to each other with a hydraulic channel configured to permit hydraulic liquid to flow between the adjusting volumes and thereby equalize the pressure in the adjusting volumes. 5. The method according to claim 4 , wherein the hydraulic channel is a first hydraulic channel, and further comprising: connecting the adjusting volumes to each other with the first hydraulic channel having a first end connected to one of the adjusting volumes and a second end connected to a pressure accumulator and a second hydraulic channel having a first end connected to the other of the adjusting volumes and a second end connected to the pressure accumulator. 6. The method according to claim 5 , further comprising: detecting pressure in each of the adjusting volumes, and controlling, based on the detected pressures, the pressure accumulator to thereby adjust the pressure in each of the adjusting volumes to a desired pressure. 7. The method according to claim 5 , further comprising: detecting a vertical ratio of the frame of the crusher and the body of the crushing plant and controlling, based on the vertical ratio, the pressure accumulator to thereby adjust each of the adjusting volumes to a desired volume and pressure, wherein each adjusting member contracts or expands to adjust a vertical height position of the frame of the crusher relative to the body of the crushing plant at the second support points. 8. The method according to claim 1 , wherein the first support devices inclinably support the crusher frame in relation to the body of the crushing plant. 9. A system for supporting a frame of a mineral material crusher on a body of a crushing plant, the system comprising: two first support devices configured to support the frame of the crusher on the body of the crushing plant at two first support points; and two second support devices configured to support the frame of the crusher on the body of the crushing plant at two second support points, wherein the second support points are located at a distance from the first support points, and wherein each of the second support devices has an adjusting member configured to be between the frame of the crusher and the body of the crushing plant and each of the adjusting members adjusts a vertical position of the second support points relative to each other to thereby reduce undesired twisting of the frame of the crusher; wherein each adjusting member is a cylinder and a piston adapted inside the cylinder, a mechanically acting adjusting member, or an electromechanically acting adjusting member. 10. The system according to claim 9 , wherein the piston and the cylinder define an adjusting volume therebetween in which a pressure is formed from a load acting on the adjusting member. 11. The system according to claim 9 , wherein the piston and the cylinder of each adjusting member define an adjusting volume therebetween in which a pressure is formed from a load acting on the adjusting member, and wherein the system further comprises a hydraulic channel connected to the adjusting volumes and configured to permit a hydraulic liquid to flow between the adjusting volumes to thereby equalize the pressure in the adjusting volumes. 12. The system according to claim 11 , wherein the hydraulic channel is a first hydraulic channel, and further comprising: a pressure accumulator; and a second hydraulic channel; wherein the first hydraulic channel has a first end connected to one of the adjusting volumes and a second end connected to the pressure accumulator and the second hydraulic channel has a first end connected to the other of the adjusting volumes and a second end connected to the pressure accumulator. 13. The system according to claim 9 , wherein the first support devices are connected to a front end of the frame of the crusher and the second support devices are connected to a rear end of the frame of the crusher. 14. The system according to claim 9 , wherein the second support devices are arranged to rest with a friction joint on the body of the crushing plant. 15. The system according to claim 11 , wherein when the second support points are vertically offset relative to each other, so that hydraulic liquid flows from one of the adjusting volumes through the hydraulic channel to the other of the adjusting volumes, one of the adjusting members contracts and the other of the adjusting members expands to thereby vertically adjust the second support points relative to each other. 16. The system according to claim 9 , wherein the crusher is one of the following: a jaw crusher, a horizontal shaft impactor, a vertical shaft impactor, a gyratory crusher, and a cone crusher. 17. A mineral material processing plant, wherein the mineral material processing plant comprises a system according to claim 9 . 18. The system according to claim 12 further comprising a control unit operable to detect the pressure in each of the adjusting volumes and control the pressure accumulator based on the pressure in each of the adjusting volumes. 19. The method according to the claim 12 further comprising a control unit operable to detect a vertical ratio of the frame of the crusher and the body of the crushing plant and control the pressure accumulator based on the vertical ratio such that each adjusting volume has a desired volume and pressure and each adjusting member contracts or expands to adjust the vertical position of the frame of the crusher.