Tunnel machine having sealing units for sealing an annular gap around a drive shaft for a cutting wheel

The invention claimed is: 1. A tunnel boring machine having a driveshaft ( 103 ) for a cutting wheel, which is enclosed by a sealing wear ring ( 106 ) and by a seal carrier ( 112 ) arranged at a radial distance from the sealing wear ring ( 106 ) while forming an annular gap ( 109 ), and having a number of sealing units ( 115 ), which are arranged in succession in a sealing manner in the axial direction in the annular gap ( 109 ), wherein the sealing units ( 115 ) have a sealing ring holder ( 118 ) made of a rigid material, which is U-shaped in at least one receptacle region having two opposite side walls ( 303 , 306 ; 703 , 706 ; 903 , 906 ) and having a radial outside top wall ( 309 ; 709 ; 803 , 806 ; 909 ) extending between radial outside ends of the side walls ( 303 , 306 ; 703 , 706 ; 903 , 906 ), and having a sealing ring ( 121 ) made of a flexible material, which has a fixing region ( 209 ) and at least one sealing lip ( 212 ), wherein the sealing ring holder ( 118 ) is constructed in two parts having a first sealing ring holder part ( 803 ; 912 ) and having a second sealing ring holder part ( 806 ; 915 ), and in that the sealing ring holder parts ( 803 , 806 ; 912 , 915 ) are releasably connectable to one another via connecting means ( 809 , 918 ), wherein the fixing region ( 209 ) is enclosed by the side walls ( 303 , 306 ; 703 , 706 ; 903 , 906 ) and by the top wall ( 309 ; 709 ; 803 , 806 ; 909 ) of the sealing ring holder ( 118 ), so that each of these sealing units ( 115 ) is insertable into the annular gap ( 109 ) while the connecting means ( 809 , 918 ) locks the sealing ring holder parts ( 803 , 806 ; 912 , 915 ) together without risk of tilting of the sealing ring, wherein a force flow takes place via the sealing ring holders ( 118 ) pressing against one another in the axial direction, so that due to the displaceability of the seal ring holders ( 118 ) in the axial direction taking place substantially without frictional losses, pre-tensions forces are distributed uniformly over the sealing ring holders ( 118 ) and each sealing ring holder ( 118 ) absorbs loads exerted on the sealing ring ( 121 ) held by it, so that loads on the fixing region ( 209 ) of the sealing rings ( 121 ) are less than loads exerted on the sealing ring holder ( 118 ). 2. The tunnel boring machine as claimed in claim 1 , wherein the sealing ring holder ( 118 ) and the fixing region ( 209 ) have structures ( 312 , 315 ; 318 ; 403 ; 603 ) which interlock alternately in a form-fitting manner. 3. The tunnel boring machine as claimed in claim 1 , wherein the connecting means comprise screw connections ( 809 ). 4. The tunnel boring machine as claimed in claim 1 , wherein the connecting means comprise at least one detent connection ( 918 ). 5. A tunnel boring machine having a driveshaft ( 103 ) for a cutting wheel, which is enclosed by a sealing wear ring ( 106 ) and by a seal carrier ( 112 ) arranged at a radial distance from the sealing wear ring ( 106 ) while forming an annular gap ( 109 ), and having a number of sealing units ( 115 ), which are arranged in succession in a sealing manner in the axial direction in the annular gap ( 109 ), wherein the sealing units ( 115 ) have a one-piece sealing ring holder ( 118 ) made of a rigid material, which is U-shaped in at least one receptacle region having two opposite side walls ( 303 , 306 ; 703 , 706 ; 903 , 906 ) and having a radial outside top wall ( 309 ; 709 ; 803 , 806 ; 909 ) extending between radial outside ends of the side walls ( 303 , 306 ; 703 , 706 ; 903 , 906 ), and having a sealing ring ( 121 ) made of a flexible material, which has a fixing region ( 209 ) and at least one sealing lip ( 212 ), wherein the fixing region ( 209 ) is enclosed by the side walls ( 303 , 306 ; 703 , 706 ; 903 , 906 ) and by the top wall ( 309 ; 709 ; 803 , 806 ; 909 ) of the sealing ring holder ( 118 ), so that each of these sealing units ( 115 ) is insertable into the annular gap ( 109 ) without risk of tilting of the sealing ring, wherein a force flow takes place via the sealing ring holders ( 118 ) pressing against one another in the axial direction, so that due to the displaceability of the seal ring holders ( 118 ) in the axial direction taking place substantially without frictional losses, pre-tensions forces are distributed uniformly over the sealing ring holders ( 118 ) and each sealing ring holder ( 118 ) absorbs loads exerted on the sealing ring ( 121 ) held by it, so that loads on the fixing region ( 209 ) of the sealing rings ( 121 ) are less than loads exerted on the sealing ring holder ( 118 ). 6. The tunnel boring machine as claimed in claim 5 , wherein the or each sealing ring ( 121 ), in a relaxed arrangement in the axial direction, has an excess ( 1103 ) in relation to an end face ( 1106 ) of the sealing ring holder ( 118 ) holding the sealing ring ( 121 ). 7. The tunnel boring machine as claimed in claim 5 , wherein the or each sealing ring ( 121 ) has an annular hollow chamber ( 1803 ) which is fluid-mechanically connected to the outside of the sealing ring ( 121 ) via at least one connecting channel ( 1806 ). 8. The tunnel boring machine as claimed in claim 7 , wherein the sealing ring holder ( 118 ) has a through channel ( 1809 ) which extends through the sealing ring holder ( 118 ) and is in fluid-mechanical connection with the connecting channel ( 1806 ). 9. The tunnel boring machine as recited in claim 7 , wherein the fixing region is expanded into engagement with the sealing lip to press the sealing lip against the sealing wear ring in response to supplying pressurized fluid to the annular hollow chamber. 10. The tunnel boring machine as claimed in claim 5 , wherein the sealing ring ( 121 ) between the fixing region ( 209 ) and the or each sealing lip ( 212 ) has a joint region ( 215 ) having a material thickness that is reduced in comparison to the sealing lip ( 212 ). 11. The tunnel boring machine as claimed in claim 5 , wherein the fixing region ( 209 ) is arranged having a pre-tension in the sealing ring holder ( 118 ). 12. The tunnel boring machine as claimed in claim 5 , wherein the side walls ( 903 , 906 ) are inclined towards one another, pointing away from the top wall ( 909 ). 13. The tunnel boring machine as claimed in claim 5 , wherein a passage arrangement ( 236 ) is formed in the sealing ring holders ( 118 ), which is configured, in dependence on the axial position of the passage arrangement ( 236 ) along the annual gap ( 109 ) after completion of an installation process, to supply a chamber with supplied grease, oil, or corresponding media or to supply a pressurized fluid to carry out leak tests. 14. The tunnel boring machine as claimed in claim 13 , wherein a wedge-like centering aid ( 1003 ) is arranged at an insertion end of the annular gap ( 109 ). 15. The tunnel boring machine as claimed in claim 5 , wherein there are a number of block assembly bolts ( 1306 ) and/or individual assembly bolts ( 1403 ), via which a number of sealing units ( 115 ) can be assembled in blocks and/or individually. 16. The tunnel boring machine as claimed in claim 5 , wherein there is at least one annular leak test tool ( 1603 , 1703 ) which can be connected in a pressure-tight manner to the sealing units ( 115 ) arranged axially on the outside. 17. The tunnel boring machine as claimed in claim 5 , wherein at least one of the sealing ring holders associated with one of the sealing rings includes a counter lug that extends into engagement with the fixing region of an adjacent sealing ring.