Tunnel boring machine having a device for detecting a content of critical gas

The invention claimed is: 1. A tunnel boring machine with a device for detecting a content of critical gas in a cavity ( 118 ) rearward of a cutting wheel ( 106 ) with an extraction line ( 124 ) that extends between a mining chamber ( 118 ) as a cavity and the device, with a separation module ( 224 ) for separating the gas to be detected from a fluid and with a gas analysis unit ( 133 ) downstream of the separation module ( 224 ), wherein a metering module ( 240 ) for controlled charging of a gas analysis unit ( 133 ) with separated gas is arranged downstream of the separation module ( 224 ), that the metering module ( 240 ) has a pressure reducer ( 239 ) and a flow control valve ( 251 ) downstream of the pressure reducer ( 239 ), and that a double diaphragm pump ( 245 ) is provided downstream of the pressure reducer ( 239 ). 2. The tunnel boring machine of claim 1 , wherein two diaphragms of the double diaphragm pump ( 245 ) are forcibly coupled to one another and that the diaphragms can be controlled alternately via a control air line ( 244 ) by a magnetic control switch ( 243 ) with pressurized control air. 3. The tunnel boring machine of claim 2 , wherein the double diaphragm pump ( 245 ) is connected to a first throttle valve ( 241 ) and to a second throttle valve ( 242 ), the opening degrees of which can be adjusted to a relatively small value in such a way that the escaping service air of the diaphragm escapes into an environment with a great deal of delay. 4. The tunnel boring machine of claim 1 , wherein there is a pressure stabilizer ( 248 ) which is arranged between the double diaphragm pump ( 245 ) and the flow control valve ( 251 ). 5. The tunnel boring machine of claim 1 , wherein the flow control valve ( 251 ) is a needle valve. 6. The tunnel boring machine of claim 1 , wherein there is a volumetric flow measuring module ( 266 ) which is arranged downstream of the flow control valve ( 251 ). 7. The tunnel boring machine of claim 1 , wherein downstream of the pressure reducer ( 239 ) there is a Y-junction ( 254 ) which is asymmetrical with regard to the divided volumetric flows and has a downstream main arm ( 257 ) and a downstream secondary arm ( 260 ) and that the volumetric flow measuring module ( 266 ) is arranged in the main arm ( 257 ) downstream of the Y-junction ( 254 ). 8. The tunnel boring machine of claim 7 , wherein a secondary arm filter module ( 269 ) is arranged in the secondary arm ( 260 ). 9. The tunnel boring machine of claim 7 , wherein the flow control valve ( 251 ) is arranged between the pressure reducer ( 239 ) and the Y-junction ( 254 ). 10. The tunnel boring machine of claim 7 , wherein the flow control valve ( 251 ) is arranged downstream of the Y-junction ( 254 ) in the main arm ( 257 ). 11. The tunnel boring machine of claim 10 , wherein a main flow filter module ( 403 ) is present in the main arm ( 257 ) between the Y-junction ( 254 ) and the flow control valve ( 251 ). 12. The tunnel boring machine of claim 7 , wherein a gas analysis unit ( 133 ) is arranged downstream of the secondary arm ( 260 ) and is set up to detect explosive gas.