Expandable reamer assemblies, bottom hole assemblies, and related methods

What is claimed is: 1. An expandable reamer assembly for reaming a subterranean borehole, the expandable reamer assembly comprising: an expandable reamer module comprising: a first tubular body having a longitudinal axis; at least one blade configured to move between a retracted position and an extended position; and a sleeve disposed within the first tubular body and coupled to the at least one blade, the sleeve configured to axially move relative to the first tubular body to move the at least one blade into the extended position; an activation module comprising: a second tubular body coupled to the first tubular body of the expandable reamer module; and an activation member movably coupled to the second tubular body of the activation module, a longitudinal end of the activation member coupled to the sleeve to axially move the sleeve toward the activation module responsive to axial movement of the activation member; and wherein the expandable reamer module is a slave unit configured to not be activated without the activation module. 2. The expandable reamer assembly of claim 1 , wherein the activation module comprises an electronic and hydraulic activation module configured to receive a signal and respond to the signal by causing hydraulic fluid to move the activation member between an activated position and a deactivated position. 3. The expandable reamer assembly of claim 1 , wherein the activation module comprises a mechanical activation module configured to be activated without use of an electrical signal. 4. The expandable reamer assembly of claim 1 , wherein the activation module is configured to move the sleeve between an activated position and a deactivated position repeatedly. 5. The expandable reamer assembly of claim 1 , wherein the expandable reamer module further comprises a yoke coupled to the sleeve, wherein the yoke comprises a surface proximate the at least one blade, the surface extending at an angle to the longitudinal axis toward the at least one blade. 6. The expandable reamer assembly of claim 1 , wherein the expandable reamer module further comprises at least one nozzle extending through the first tubular body. 7. The expandable reamer assembly of claim 6 , wherein the sleeve comprises at least one hole extending through a sidewall thereof, and wherein the at least one hole is configured to provide continuous drilling fluid flow between the sleeve and the at least one nozzle. 8. The expandable reamer assembly of claim 7 , wherein the sleeve is configured to provide a lower rate of drilling fluid flow when the sleeve is in a deactivated position compared to an activated position. 9. The expandable reamer assembly of claim 1 , further comprising a joint structure joining the sleeve of the expandable reamer module to the activation member of the activation module, the joint structure configured to transmit a motive force from the activation module to the sleeve. 10. A bottom-hole assembly, comprising: an expandable reamer module comprising a first tubular body, at least one reamer blade, and a sleeve coupled to the at least one reamer blade such that axial movement of the sleeve within the first tubular body results in movement of the at least one reamer blade; and an activation module comprising a second tubular body coupled to the first tubular body and an activation member coupled to the sleeve, the activation member configured to pull the sleeve into an activated position resulting in movement of the at least one reamer blade into an expanded position and to push the sleeve into a deactivated position resulting in movement of the at least one reamer blade into a retracted position; wherein the expandable reamer module is a slave unit configured to not be activated without the activation module. 11. The bottom-hole assembly of claim 10 , further comprising a pilot bit coupled to the expandable reamer module. 12. The bottom-hole assembly of claim 11 , wherein the pilot bit is coupled to the expandable reamer module by a linking module. 13. The bottom-hole assembly of claim 10 , wherein the expandable reamer module lacks any mechanism configured to provide motive force to axially move the sleeve between the activated position and the deactivated position. 14. The bottom-hole assembly of claim 10 , wherein the activation member is configured to pull the sleeve into the activated position and to push the sleeve into the deactivated position repeatedly. 15. The bottom-hole assembly of claim 10 , wherein the activation module comprises an electronic and hydraulic activation module configured to receive a signal and respond to the signal by causing hydraulic fluid to move the activation member between the activated position and the deactivated position. 16. The bottom-hole assembly of claim 10 , wherein the activation module comprises a mechanical activation module configured to be activated without use of an electrical signal. 17. A method of using an expandable reamer assembly, the method comprising: coupling a first tubular body of an expandable reamer module to a second tubular body of an activation module wherein the expandable reamer module is a slave unit configured to not be activated without the activation module; disposing the expandable reamer module and the activation module in a borehole of a subterranean formation; and pulling, with the activation module, an axially movable sleeve at least partially within the first tubular body of the expandable reamer module to engage at least one reamer blade of the expandable reamer module with the subterranean formation. 18. The method of claim 17 , wherein pulling, with the activation module, the axially movable sleeve comprises activating the activation module with a first activation means, and further comprising: removing the expandable reamer module and the activation module from the borehole of the subterranean formation; uncoupling the expandable reamer module from the activation module; and coupling the expandable reamer module to another, different activation module comprising a second activation means different from the first activation means; wherein the first and the second activation means comprise at least one of the group consisting of an electronic and hydraulic activation module and a mechanical activation module. 19. The method of claim 17 , wherein coupling the first tubular body of the expandable reamer module to the second tubular body of the activation module further comprises joining the axially movable sleeve to a first longitudinal end of a joint structure and an activation member of the activation module to a second longitudinal end of the joint structure. 20. The method of claim 17 , further comprising: pushing, with the activation module, the axially movable sleeve to disengage the at least one reamer blade from the subterranean formation; and repeating at least once the pulling, with the activation module, the axially movable sleeve to engage the at least one reamer blade with the subterranean formation and the pushing, with the activation module, the axially movable sleeve to disengage the at least one reamer blade from the subterranean formation.