Fluid transport systems for use in a downhole explosive fracturing system

We claim: 1. An explosive unit for insertion into a borehole for use in fracturing a geologic formation surrounding the borehole, the explosive unit comprising: a casing comprising a body defining an internal chamber; a first component of an explosive positioned within the internal chamber of the casing; at least one inlet communicating with the internal chamber through which a second component of the explosive is deliverable into the internal chamber to comprise the explosive; wherein the casing comprises first and second opposed end caps and wherein at least one inlet tube extends from the at least one inlet through the first end cap, through the internal chamber, and through the second end cap, and wherein the at least one inlet tube delivers the second component of the explosive into the internal chamber. 2. The explosive unit of claim 1 , wherein the first component comprises a liquid permeable oxidizer. 3. The explosive unit of claim 1 , wherein the first component comprises a particulate solid material or a sponge-like material. 4. The explosive unit of claim 1 , further comprising at least one remotely actuated vent communicating with the internal chamber. 5. The explosive unit of claim 1 , wherein the at least one inlet tube comprises a tube with an inline outlet extending through the second end cap, an inlet extending through the first end cap and communicating with a source of the second component at a location that is remote from the explosive unit, and an internal outlet that communicates with the internal chamber. 6. An explosive system comprising an assembly of two or more elongated casings for insertion into a borehole for use in fracturing a geologic formation surrounding the borehole, the explosive system including: a first elongated casing having a tubular body, first and second longitudinal end caps, and defining a first internal chamber; a second elongated casing having a tubular body, first and second longitudinal end caps, and defining a second internal chamber, the first and second casings being mechanically coupled together in axial alignment; each of the first and second casings comprising a first component of an explosive located within the respective internal chamber of the casing; and at least one inlet tube communicating with the first and second internal chambers of the respective first and second casings, the at least one inlet tube being operable to deliver a second component of the explosive into the first and second internal chambers so as to combine with the first component of the explosive to comprise the explosive. 7. The system of claim 6 , wherein the first component comprises a liquid permeable oxidizer and the second component comprises a liquid fuel. 8. The system of claim 6 , wherein the at least one inlet tube comprises a first outlet communicating with the first internal chamber of the first casing and a second outlet communicating with the second internal chamber of the second casing. 9. The system of claim 6 , wherein the at least one inlet tube comprises a first section extending from the first casing, a second section extending into the second casing, and an inlet tube coupler that couples the first and second inlet tube sections together between the first and second casings. 10. The system of claim 7 , wherein a first end of the at least one inlet tube is coupled to a liquid fuel source configured to supply the liquid fuel through the at least one inlet tube into the first and second internal chambers. 11. The system of claim 10 , wherein the first end of the at least one inlet tube is further coupled to a vacuum pump configured to create a vacuum within the first and second internal chambers so as to draw the liquid fuel into the internal chambers. 12. The system of claim 6 , further comprising at least one outlet vent tube communicating with the first and second internal chambers and being operable to vent fluid from the first and second internal chambers when the second component of the explosive is delivered into the first and second internal chambers. 13. The system of claim 12 , wherein the at least one inlet tube has no outlet within the first casing and has an outlet within the second internal chamber of the second casing, and comprising a passageway communicating from the second internal chamber to the first internal chamber. 14. The system of claim 13 , wherein the second component of the explosive is configured to flow along the at least one inlet tube through the first casing, flow out of the outlet of the at least one inlet tube into the internal chamber of the second casing, flow into the passageway from the second internal chamber, and flow out of the passageway into the first internal chamber. 15. The system of claim 12 , wherein the outlet tube comprises a first section extending from the second casing, a second section extending into the first casing, and an outlet tube coupler that couples the first and second outlet tube sections together between the first and second casings. 16. The system of claim 14 , comprising at least one vent coupled to the internal chambers of the first and second casings, wherein the first component comprises a permeable oxidizer and the second component comprises a liquid fuel, and wherein the system comprises a pump that pumps the liquid through the at least one inlet tube, into the internal chamber of the second casing, and through the outlet tube into the first casing, and wherein the at least one vent tube vents the internal chambers as the liquid flows into the first and second chambers. 17. A method comprising: inserting an explosive assembly into a wellbore, the assembly comprising a first explosive unit and a second explosive unit, each explosive unit having a casing with a first component of an explosive within the casing; and then flowing a second component of the explosive into the inserted casings of the first and second explosive units using a common inlet tube extending through each casing to comprise the explosive within each explosive unit; detonating the explosive to fracture the geologic structure surrounding the borehole and the casings. 18. A method according to claim 17 , wherein the act of flowing the second component comprises flowing the second component into the first explosive unit from a location outside of the entrance opening to the wellbore. 19. A method according to claim 17 , wherein the act of flowing comprises venting the casings and pumping the second component into the vented casings, and the method further comprises closing at least one vent following flowing of the second component into the casings. 20. A method according to claim 17 , wherein the act of flowing comprises drawing a vacuum within the casings, coupling a supply of the second component to the casings, and using the vacuum in the casings to draw the second component into the casings.