Pressure-controlled downhole actuators

What is claimed is: 1. An apparatus comprising: an actuator housing configured for incorporation in a tool to be located in a downhole environment exposed to ambient wellbore fluid, the housing defining an activation chamber, a fluid passage connecting the activation chamber to an exterior of the housing, and a deactivation passage connecting the compression chamber to the exterior of the housing; an actuated member displaceably mounted on the housing and configured for hydraulically actuated movement in an activation direction relative to the housing in response to exposure of the activation chamber to pressurized ambient wellbore fluid via the fluid passage, wherein a hollow interior of the actuator housing and the actuated member together define the activation chamber and a complementary compression chamber sealingly separated from the activation chamber, such that displacement of the actuated member in the activation direction corresponds to expansion of the activation chamber and compression of the compression chamber; an activation chamber closure device obstructing the fluid passage and isolating the activation chamber from ambient wellbore fluid exterior to the housing, the activation chamber closure device being configured for automatically opening in response to ambient wellbore fluid conditions that exceed a predefined activation threshold, thereby to place the activation chamber in flow connection with ambient wellbore fluid for actuation of the actuated member by hydraulic action of the wellbore fluid; and a compression chamber closure device sealingly closing off the deactivation passage and being configured for automatically opening in response to ambient wellbore fluid pressures exceeding a predefined deactivation threshold. 2. The apparatus of claim 1 , wherein the activation chamber closure device is a frangible closure configured for automatic failure in response to exposure to ambient wellbore fluid pressures exceeding an activation pressure corresponding to the activation threshold. 3. The apparatus of claim 2 , wherein the frangible closure is removably and replaceably mounted on the housing. 4. The apparatus of claim 1 , further comprising a cushioning mechanism configured for exerting on the actuated member resistance to movement thereof in the activation direction, such that the resistance increases in magnitude with an increase in displacement of the actuated member in the activation direction. 5. The apparatus of claim 1 , wherein the compression chamber is a substantially sealed volume containing a compressible fluid. 6. The apparatus of claim 5 , wherein in the compression chamber is the air-filled. 7. The apparatus of claim 5 , wherein in the compression chamber is filled with an noncorrosive gas. 8. The apparatus of claim 1 , further comprising a stopping mechanism configured for mechanically stopping movement of the actuated member in the activation direction beyond a predetermined deployment stroke limit. 9. The apparatus of claim 1 , further comprising a deactivation mechanism configured for, subsequent to opening of the activation chamber closure device, automatically displacing the actuated member in a deactivation direction, opposite to the activation direction, in response to establishment of a flow connection between the compression chamber and ambient wellbore fluid via opening of the compression chamber closure device. 10. The apparatus of claim 9 , wherein the deactivation mechanism comprises a bias mechanism configured for urging the actuated member in the deactivation direction. 11. The apparatus of claim 10 , wherein the bias mechanism comprises an elastically deformable spring element operatively connected to the actuated member and configured for exerting on the actuated member a bias force that increases in magnitude with an increase in displacement thereof in the activation direction. 12. A system comprising: an actuator mechanism configured for incorporation in a tool to be employed in a downhole drilling environment in which the actuator mechanism is exposed to ambient wellbore fluid, the actuator mechanism comprising a housing and an actuated member that is mounted on the housing and that is configured for hydraulically actuated movement relative to the housing in response to establishment of a flow connection, via an activation conduit defined by the housing, between ambient wellbore fluid and an activation volume defined by the housing, the actuator mechanism is further configured for deactivation, subsequent to switching of the activation closure device to the opened state, in response to establishment of a flow connection between the ambient wellbore fluid and a deactivation volume of the actuator mechanism via a deactivation conduit defined by the actuator mechanism; a plurality of different activation closure devices configured for interchangeable, removable and replaceable mounting on the actuator mechanism, each activation closure device being configured for, when mounted on the actuator mechanism, substantially closing off the activation conduit at below-threshold wellbore fluid pressures, and for automatically switching, in response to ambient wellbore fluid pressures greater than a corresponding activation threshold, to an opened state in which the activation volume is in flow connection with ambient wellbore fluid via the activation conduit; and a plurality of different deactivation closure devices configured for interchangeable, removable and replaceable mounting on the actuator mechanism, each deactivation closure device being configured for, when mounted on the actuator mechanism, substantially closing off the deactivation volume at below deactivation-threshold wellbore fluid pressures, and for automatically switching, in response to ambient wellbore fluid pressures greater than a corresponding deactivation threshold, to an opened state in which the deactivation volume is in flow connection with ambient wellbore fluid via the deactivation conduit. 13. The system of claim 12 , wherein two or more of the plurality of different activation closure devices have different respective activation thresholds, allowing operator modification of an operative activation threshold for the actuator mechanism by removal of one activation closure device from the actuating mechanism and replacement thereof by another activation closure device having a different corresponding activation threshold. 14. The system of claim 12 , wherein respective mounting formations provided by the actuator mechanism to receive closure devices for the activation conduit and the deactivation conduit respectively are compatible with the plurality of deactivation closure devices and the plurality of activation closure devices. 15. A method comprising: providing an actuator mechanism at a downhole location such that the actuator mechanism is exposed to ambient wellbore fluid, the actuator mechanism comprising a housing that defines an activation volume an activation conduit leading into the activation volume, a deactivation volume, and a deactivation conduit leading into the deactivation volume, an actuated member mounted on the housing and configured for hydraulically actuated movement relative to the housing in response to flow of wellbore fluid into the activation volume, an activation closure device mounted on the housing to isolate the activation volume from the ambient wellbore fluid by closing off the activation conduit, the activation closure device being configured to open the activation conduit in response to wellbore fluid pressures exceeding a predetermined activation threshold level, and