Flow distribution assemblies for preventing sand screen erosion

What is claimed is: 1. A flow distribution assembly, comprising: a bulkhead arranged about a base pipe having one or more flow ports defined therein, the bulkhead defining a plurality of flow conduits in fluid communication with the one or more flow ports; at least one sand screen arranged about the base pipe and extending axially from the bulkhead, a flow annulus being defined between the at least one sand screen and the base pipe; and a plurality of flow tubes fluidly coupled to the plurality of flow conduits and extending axially from the bulkhead within the flow annulus, the plurality of flow tubes being configured to place an interior of the base pipe in fluid communication with the flow annulus via the one or more flow ports, wherein the plurality of flow tubes exhibit at least two different axial lengths extending within the flow annulus beneath the at least one sand screen to distribute a fluid through the at least one sand screen at a plurality of axial locations within the flow annulus. 2. The flow distribution assembly of claim 1 , further comprising a plurality of ribs extending longitudinally from the bulkhead within the flow annulus and being configured to radially support the at least one sand screen. 3. The flow distribution assembly of claim 2 , wherein at least one of the plurality of flow tubes is arranged between angularly adjacent ribs of the plurality of ribs. 4. The flow distribution assembly of claim 1 , wherein the plurality of flow tubes are angularly offset from each other about a circumference of the base pipe and thereby distribute the fluid through the at least one sand screen at a plurality of angular locations about the circumference of the base pipe. 5. The flow distribution assembly of claim 1 , wherein a cross-sectional shape of one or more of the plurality of flow tubes is circular, polygonal, oval, or kidney-shaped. 6. The flow distribution assembly of claim 1 , wherein the plurality of flow tubes exhibit at least two inner flow areas that are different from each other. 7. The flow distribution assembly of claim 1 , further comprising one or more nozzles arranged in a corresponding one or more of the plurality of flow conduits. 8. The flow distribution assembly of claim 1 , wherein one or more of the plurality of flow tubes is made of an erosion resistant material selected from the group consisting of a carbide, a ceramic, and any combination thereof. 9. The flow distribution assembly of claim 1 , wherein one or more of the plurality of flow tubes is cladded with an erosion resistant material. 10. The flow distribution assembly of claim 1 , wherein the plurality of flow tubes radially supports the at least one sand screen. 11. The flow distribution assembly of claim 10 , wherein each flow tube provides first and second legs that contact the base pipe. 12. The flow distribution assembly of claim 11 , further comprising one or more circumferential perforations defined in one or both of the first and second legs, the one or more circumferential perforations facilitating fluid communication between an interior of a corresponding flow tube and the at least one sand screen. 13. The flow distribution assembly of claim 11 , further comprising: a crossbar that extends between the first and second legs; and one or more radial perforations defined in the crossbar and facilitating fluid communication between an interior of a corresponding flow tube and the at least one sand screen. 14. A method, comprising: introducing a flow distribution assembly into a wellbore that penetrates a subterranean formation, the flow distribution assembly being arranged on a base pipe and comprising: a bulkhead arranged about the base pipe and defining a plurality of flow conduits in fluid communication with one or more flow ports defined in the base pipe; at least one sand screen arranged about the base pipe and extending axially from the bulkhead, a flow annulus being defined between the at least one sand screen and the base pipe; and a plurality of flow tubes fluidly coupled to the plurality of flow conduits and extending axially from the bulkhead within the flow annulus; conveying a fluid to the flow distribution assembly and into the plurality of flow tubes via the one or more flow ports; injecting the fluid into the flow annulus from the plurality of flow tubes at a plurality of axial locations within the flow annulus; and flowing the fluid through the at least one sand screen and to the subterranean formation at the plurality of axial and angular locations. 15. The method of claim 14 , wherein individual flow tubes of the plurality of flow tubes exhibit at least two inner flow areas, the method further comprising restricting a flow of the fluid through the individual flow tubes having a smaller inner flow area. 16. The method of claim 14 , wherein individual flow tubes of the plurality of flow tubes exhibit at least two different axial lengths, and wherein ejecting the fluid into the flow annulus from the plurality of flow tubes further comprises distributing a flow of the fluid through the at least one sand screen at the at least two different axial lengths. 17. The method of claim 14 , further comprising radially supporting the at least one sand screen with the plurality of flow tubes. 18. The method of claim 17 , wherein at least one of the plurality of flow tubes provides first and second legs that contact the base pipe and one or more circumferential perforations are defined in one or both of the first and second legs, and wherein ejecting the fluid into the flow annulus from the plurality of flow tubes further comprises flowing the fluid through the one or more circumferential perforations from an interior of the at least one of the plurality of flow tubes. 19. The method of claim 17 , wherein at least one of the plurality of flow tubes provides first and second legs, a crossbar extending between the first and second legs, and one or more radial perforations defined in the crossbar, and wherein ejecting the fluid into the flow annulus from the plurality of flow tubes further comprises flowing the fluid through the one or more radial perforations from an interior of the at least one of the plurality of flow tubes. 20. The method of claim 14 , further comprising radially supporting the at least one sand screen with a plurality of ribs extending longitudinally from the bulkhead within the flow annulus. 21. The method of claim 14 , wherein the plurality of flow tubes are angularly offset from each other about a circumference of the base pipe, the method further comprising: ejecting the fluid into the flow annulus from the plurality of flow tubes at a plurality of angular locations about the circumference of the base pipe; and flowing the fluid through the at least one sand screen and to the subterranean formation at the plurality of angular locations. 22. A method, comprising: introducing a flow distribution assembly into a wellbore that penetrates a subterranean formation, the flow distribution assembly being arranged on a base pipe and comprising: at least one sand screen arranged about the base pipe and extending axially along an exterior of the base pipe, a flow annulus being defined between the at least one sand screen and the base pipe; and a plurality of flow tubes in fluid communication with one or more flow ports defined in the base pipe and extending axially along the exterior of the base pipe within the flow annulus, wherein the plurality of