Seal to prevent lubricant escaping, and rolling stand having said seal

The invention claimed is: 1. A rolling stand ( 200 ), comprising: at least one roller ( 210 ) with two roll journals ( 212 ) and a roller body ( 214 ) for rolling a rolled material; at least one chock ( 220 ) for rotatably supporting the roller ( 210 ) in the rolling stand ( 200 ), wherein the chock ( 220 ) forms a receiving opening for receiving one of the roll journals ( 212 ), wherein an inner diameter of the receiving opening is larger than an outer diameter of the roll journal in such a manner that, between the chock and the roll journal an annular gap ( 300 ) for receiving a lubricant ( 320 ) is formed; and a seal for sealing the annular gap, which represents a lubricant space of a bearing, at least in a predetermined circumferential angular range, arranged in a non-rotatable manner relative to the rotatable roller at an end proximal to the roller body and/or at an end remote from the roller body of the chock ( 220 ); wherein the seal ( 100 ) is at least partially formed from an elastic material, wherein the seal has at least two cavities ( 110 ) which are separated from each other in a circumferential direction and which are independently open towards the lubricant space of the bearing for feeding the lubricant ( 320 ) from the lubricant space ( 300 ) of the bearing to be sealed into the cavities whereby the at least two cavities ( 110 ) can expand independently depending on different lubricant pressure in each of the at least two cavities ( 110 ), wherein a groove ( 230 ) that is open towards the roll journal ( 212 ) and into which the seal ( 100 ) can be inserted is formed at the end proximal to the roller body and/or at the end remote from the roller body of the chock ( 220 ). 2. The rolling stand according to claim 1 , wherein the seal ( 100 ) is formed as a ring segment and has a predetermined limited length (L) to which the following applies: L <total circumference of the annular gap. 3. The rolling stand according to claim 1 , wherein the seal ( 100 ) is designed in the form of a ring seal. 4. The rolling stand according to claim 3 , wherein an outer diameter (DD) of the ring seal in its unloaded state is essentially equal to a diameter of the groove ( 240 ) at its bottom. 5. The rolling stand according to claim 3 , wherein an inside diameter (dD) of the ring seal ( 100 ) is larger than an outside diameter (DZ) of the roll journal ( 212 ) at an axial height of the ring seal. 6. The rolling stand according to claim 1 , wherein an axial outer side of the groove is formed by a perforated disk ( 240 ) that can be detachably connected to the chock. 7. The rolling stand according to claim 1 , wherein the seal ( 100 ) has at least one superelevation ( 130 ) on its end face turned away from and/or turned towards the chock. 8. The rolling stand according to claim 1 , wherein the seal ( 100 ) has a rectangular cross-section; and in that the sealing surface of the seal is turned towards the roll journal. 9. The rolling stand according to claim 3 , wherein the at least two cavities ( 110 ) on the surface of the ring seal are also designed to be open towards the chock ( 220 ). 10. The rolling stand according to claim 9 , wherein the chock ( 220 ) has, on its end face turned towards the seal, pins ( 228 ) projecting in an axial or radial direction for engaging in the at least two cavities ( 110 ) on the surface of the seal ( 100 ). 11. The rolling stand according to claim 10 , wherein a volume of the at least two cavities ( 110 ) into which the pins project is greater than a volume of the pins ( 228 ) engaging in the at least two cavities. 12. The rolling stand according to claim 1 , wherein the seal does not include a circumferential groove to connect the at least two cavities ( 110 ). 13. The rolling stand according to claim 1 , wherein the seal ( 100 ) extends radially beyond the groove ( 230 ) with a bottom face ( 112 ) of the seal being arranged outside the groove ( 230 ), and wherein each of the at least two cavities ( 110 ) is open towards the groove and in fluid communication with the lubricant space only through a dedicated feed channel ( 120 ) that opens towards the lubricant space on an inside face of the seal outside of the groove. 14. The rolling stand according to claim 1 , wherein pins ( 228 ) extend from the chock ( 220 ) into the cavities ( 110 ). 15. The rolling stand according to claim 1 , wherein in an unloaded state, an axial width (a) of the seal ( 100 ) is greater than a width (A) of the groove ( 230 ) in the axial direction (R). 16. The rolling stand according to claim 1 , further comprising a bearing bush ( 222 ) arranged in a non-rotatable manner in the chock ( 220 ). 17. The rolling stand according to claim 1 , further comprising a journal bush ( 216 ) drawn on the one of the roll journals ( 212 ).