Synchronized hybrid clamp force controller for lift truck attachment

The invention claimed is: 1 . A hydraulic control circuit comprising: an input port configured to receive pressurized fluid from a pump and return unpressurized fluid to a reservoir; a first output port connectable to a first hydraulic actuator and a second output port connectable to a second hydraulic actuator, each of the first output port and the second output port configured to receive pressurized fluid from the input port and also configured to simultaneously deliver said pressurized fluid to its respectively connected hydraulic actuator and receive fluid discharged therefrom; at least one selector together capable of selectively causing any fluid discharged from the first output port to pressurize the second output port; wherein the first output port and the second output port are each configured to deliver said pressurized fluid from the input port to a respectively connected hydraulic actuator regardless of the position of said at least one selector. 2 . The hydraulic control circuit of claim 1 where the selector selectively causes fluid discharged from the first hydraulic actuator to pressurize fluid delivered into the second hydraulic actuator automatically based upon the magnitude of fluid pressure provided to the hydraulic control circuit. 3 . The hydraulic control circuit of claim 1 where the selector selectively causes fluid discharged from the first hydraulic actuator to pressurize fluid delivered into the second hydraulic actuator automatically based upon which connection of an input port receives pressurized fluid. 4 . The hydraulic control circuit of claim 1 selectively connectable to a lift truck attachment having opposed clamps, where the selector is configured to selectively cause fluid discharged from the first hydraulic actuator to pressurize fluid delivered into the second hydraulic actuator automatically when the clamps engage a load. 5 . The hydraulic control circuit of claim 1 where the selector selectively causes fluid discharged from the first hydraulic actuator to pressurize fluid delivered into the second hydraulic actuator automatically during an opening movement of the hydraulic actuators. 6 . The hydraulic control circuit of claim 1 where the selector selectively causes fluid discharged from the first hydraulic actuator to pressurize fluid delivered into the second hydraulic actuator automatically during a portion of a closing movement of the hydraulic actuators and during an opening movement of the hydraulic actuators. 7 . The hydraulic control circuit of claim 1 where the selector alternates the control circuit between a first mode where the hydraulic actuators are linked in series and a second mode where the hydraulic actuators are not linked in series. 8 . The hydraulic control circuit of claim 7 where in the second mode, the hydraulic actuators are driven in parallel. 9 . The hydraulic control circuit of claim 8 including a second selector that controls the flow from a flow divider. 10 . The hydraulic control circuit of claim 7 where in the second mode, one hydraulic actuator is moved by the control circuit while the other hydraulic actuator is prevented from moving by the control circuit. 11 . A hydraulic control circuit connected to first hydraulic actuator and a second hydraulic actuator, the hydraulic control circuit comprising: an input port configured to receive pressurized fluid from a pump and return unpressurized fluid to a reservoir; a first output port connectable to the first hydraulic actuator and a second output port connectable to the second hydraulic actuator, each of the first output port and the second output port configured to receive pressurized fluid from the input port and also configured to simultaneously deliver said pressurized fluid to its respectively connected hydraulic actuator and receive fluid discharged therefrom; and at least one selector together capable of selectively causing fluid discharged from the first hydraulic actuator to be delivered into the second hydraulic actuator; and a pressure differential element that achieves synchronous extension and retraction movement of the first hydraulic actuator and the second hydraulic actuator when the selector does not cause fluid discharged from the first hydraulic actuator to be delivered into the second hydraulic actuator. 12 . The hydraulic control circuit of claim 11 where the pressure differential element is a flow divider that provides different fluid pressure at each output. 13 . The hydraulic control circuit of claim 11 where the pressure differential element is a pressure reducing valve. 14 . The hydraulic control circuit of claim 11 selectively connectable to a lift truck attachment having opposed clamps, where the selector is configured to selectively cause fluid discharged from the first hydraulic actuator to pressurize fluid delivered into the second hydraulic actuator automatically when the clamps engage a load. 15 . The hydraulic control circuit of claim 11 where the selector selectively causes fluid discharged from the first hydraulic actuator to pressurize fluid delivered into the second hydraulic actuator automatically during an opening movement of the hydraulic actuators. 16 . The hydraulic control circuit of claim 11 where the selector selectively causes fluid discharged from the first hydraulic actuator to pressurize fluid delivered into the second hydraulic actuator automatically during a portion of a closing movement of the hydraulic actuators and during an opening movement of the hydraulic actuators. 17 . The hydraulic control circuit of claim 11 where the selector alternates the control circuit between a first mode where the hydraulic actuators are linked in series and a second mode where the hydraulic actuators are not linked in series. 18 . The hydraulic control circuit of claim 17 where in the second mode, the hydraulic actuators are driven in parallel. 19 . The hydraulic control circuit of claim 18 including a second selector that controls the flow from a flow divider. 20 . The hydraulic control circuit of claim 17 where in the second mode, one hydraulic actuator is moved by the control circuit while the other hydraulic actuator is prevented from moving by the control circuit.