Device and method for the recovery, in particular in-situ recovery, of a carbonaceous substance from subterranean formations

The invention claimed is: 1. A device for extracting a hydrocarbon-containing substance from a reservoir, wherein thermal energy can be applied to the reservoir in order to reduce the viscosity of the substance, the device comprising: at least one conductor loop for inductively supplying electric current, to provide electric and/or electromagnetic heating, and a fluid conducting tube for transporting and introducing a solvent fluid into the reservoir, to further reduce the viscosity of the substance, and a pressurizing device, wherein the fluid conducting tube is perforated and is arranged in the reservoir such that when the solvent fluid is supplied the solvent fluid moves out of the fluid conducting tube into the reservoir only by way of a perforation, wherein the perforation has holes which are embodied in terms of shape and/or size and/or distribution in such a way that when the solvent fluid is supplied under a predetermined pressure applied by the pressurizing device, the solvent fluid is discharged in a distributed manner into the reservoir over a length of the fluid conducting tube through the perforation into an environment of the fluid conducting tube, wherein the applied predetermined pressure is dependent on a depth of the reservoir and is higher than a hydrostatic pressure corresponding to said depth of the reservoir, wherein the perforations are embodied in such a way that the same amount of fluid is discharged in each section over the entire length of the fluid conducting tube; and wherein the fluid conducting tube is internal to the conductor, wherein the perforation is embodied in such a way that an electrical insulation of holes of the perforation is provided with respect to the conductor. 2. The device as claimed in claim 1 , wherein a conductor of the conductor loop comprises a plurality of subconductors which surround the fluid conducting tube in at least one section. 3. The device as claimed in claim 1 , wherein the conductor and the fluid conducting tube are embodied separately from each other. 4. The device as claimed in claim 1 , wherein the fluid conducting tube is arranged approximately coaxially with respect to the conductor. 5. The device as claimed in claim 1 , wherein the perforation is embodied in such a way and/or an arrangement is provided so that an infiltration of solid bodies and/or sands from the reservoir into the fluid conducting tube is substantially prevented. 6. A method for extracting a hydrocarbon-containing substance from a reservoir, wherein thermal energy is applied to the reservoir in order to reduce the viscosity of the substance, the method comprising: providing at least one conductor loop for inductively supplying current, the conductor loop being operable to provide electric and/or electromagnetic heating, transporting a solvent fluid through a fluid conducting tube into the reservoir, and introducing the solvent into the reservoir to further reduce the viscosity of the substance, wherein the fluid conducting tube is perforated and is arranged in the reservoir such that when the solvent fluid is supplied the solvent fluid moves out of the fluid conducting tube into the reservoir only by way of a perforation, wherein the perforation has holes which are embodied in terms of shape and/or size and/or distribution in such a way that when the solvent fluid is supplied under an applied predetermined pressure the solvent fluid is discharged in a distributed manner into the reservoir over a length of the fluid conducting tube through the perforation into an environment of the fluid conducting tube, wherein the applied predetermined pressure is dependent on a depth of the reservoir and is higher than a hydrostatic pressure corresponding to said depth of the reservoir, wherein the perforations are embodied in such a way that the same amount of fluid is discharged in each section over the entire length of the fluid conducting tube; and wherein the fluid conducting tube is internal to the conductor, wherein the perforation is embodied in such a way that an electrical insulation of holes of the perforation is provided with respect to the conductor. 7. The method as claimed in claim 6 , further comprising conducting the solvent fluid under pressure into the fluid conducting tube such that a pressure greater than a pressure in the reservoir is present inside the fluid conducting tube in the region of the perforation in the environment of the perforation. 8. The method as claimed in claim 7 , further comprising adjusting the pressure of the solvent fluid to a predetermined perforation in such a way that when the solvent fluid is supplied under said pressure the solvent fluid is discharged into the reservoir in a distributed manner over a length of the fluid conducting tube into an environment of the fluid conducting tube. 9. The method as claimed in claim 6 , wherein a gas or a liquid or a multicomponent mixture is provided as the solvent fluid, comprising at least one constituents from the group consisting of: alkanes; water mixtures with wetting agents contained therein; water mixtures with polymers contained therein; acids; bases; SO 2 ; and CO 2 . 10. The method as claimed in claim 6 , further comprising: closing a valve of a producer well for conveying away the liquefied hydrocarbon-containing substance from the reservoir, and opening the valve at a later time, dependent on a predetermined time interval having elapsed or on a predetermined pressure having been reached within the reservoir. 11. The method as claimed in claim 6 , further comprising controlling an electrical property of the reservoir through introducing the solvent fluid into the reservoir. 12. A device for extracting a hydrocarbon-containing substance from a reservoir, wherein thermal energy can be applied to the reservoir in order to reduce the viscosity of the substance, the device comprising: at least one conductor loop for inductively supplying electric current, to provide electric and/or electromagnetic heating, and a fluid conducting device for transporting and introducing a solvent fluid into the reservoir, to further reduce the viscosity of the substance, wherein the fluid conducting device is perforated such that when the solvent fluid is supplied the solvent fluid permeates out of the fluid conducting device into the reservoir by way of a perforation, and wherein the fluid conducting device is internal to the conductor, wherein the perforation is embodied in such a way that an electrical insulation of holes of the perforation is provided with respect to the conductor.