A pump jack controller is provided that can harness the potential energy generated during the operation of one pump jack amongst a plurality of pump jacks located at a well site and convert that potential energy into electrical energy that can be used to provide electrical power generated by the pump jack to power the other pump jacks located at the well site.

A pump jack controller is provided that can harness the potential energy generated during the operation of one pump jack amongst a plurality of pump jacks located at a well site and convert that potential energy into electrical energy that can be used to provide electrical power generated by the pump jack to power the other pump jacks located at the well site.

A generator (100) and/or machine (110) generating mechanical energy and functioning on the principle of exploitation of an energy allowing the existence of centrifugal forces (Fc) on masses (M) being displaced in rotation along an eccentric trajectory (150) within a system (130, 132, 166, 170, 190, 210) driving a progressive or sudden variation of their radius of rotation, principle of a generator of centrifugal forces from an eccentric with variable radius (100).

A generator (100) and/or machine (110) generating mechanical energy and functioning on the principle of exploitation of an energy allowing the existence of centrifugal forces (Fc) on masses (M) being displaced in rotation along an eccentric trajectory (150) within a system (130, 132, 166, 170, 190, 210) driving a progressive or sudden variation of their radius of rotation, principle of a generator of centrifugal forces from an eccentric with variable radius (100).

The Conveyor1 will take the object vertically to the top of the device with speed control by the lifting unit (1), then the object will get transferred from Conveyor1 to Conveyor2. The Conveyor2 will carry the object to the free falling unit (2) area with speed control. The object will fall in the free falling area with the help of permanent magnets; the object will get attached on Conveyor3, which will give drive to the rotating wheel. The object gets detached from Conveyor3 and gets transferred to Conveyor4. Conveyor4 will take the object back to Conveyor1 with speed control. The falling object is again carry on the top and same cycle is continuously rotating the rotational wheel which further generate the electricity. By such way multiple devices are synchronized to give continuous power to the respective rotating wheel of each machine, wherein one main shaft passing through the rotating wheel of multiple machines.

The Conveyor1 will take the object vertically to the top of the device with speed control by the lifting unit (1), then the object will get transferred from Conveyor1 to Conveyor2. The Conveyor2 will carry the object to the free falling unit (2) area with speed control. The object will fall in the free falling area with the help of permanent magnets; the object will get attached on Conveyor3, which will give drive to the rotating wheel. The object gets detached from Conveyor3 and gets transferred to Conveyor4. Conveyor4 will take the object back to Conveyor1 with speed control. The falling object is again carry on the top and same cycle is continuously rotating the rotational wheel which further generate the electricity. By such way multiple devices are synchronized to give continuous power to the respective rotating wheel of each machine, wherein one main shaft passing through the rotating wheel of multiple machines.

An impulse momentum propulsion apparatus includes a power source and a track arranged radially relative to a vertical axis with a proximal end of the track nearest the vertical axis and a distal end of the track farthest from the vertical axis, the track powered by the power source to rotate about the vertical axis. The apparatus further includes a mass constrained to move along the track and a linear actuator that moves the mass from the distal end of the track to the proximal end of the track when the primary mass arrives at the distal end of the track due to centrifugal force acting on the mass caused by the rotation of the track. A net reaction force acting on the track over a full rotation of the track includes a non-zero propulsive force component in a propulsion direction.

An impulse momentum propulsion apparatus includes a power source and a track arranged radially relative to a vertical axis with a proximal end of the track nearest the vertical axis and a distal end of the track farthest from the vertical axis, the track powered by the power source to rotate about the vertical axis. The apparatus further includes a mass constrained to move along the track and a linear actuator that moves the mass from the distal end of the track to the proximal end of the track when the primary mass arrives at the distal end of the track due to centrifugal force acting on the mass caused by the rotation of the track. A net reaction force acting on the track over a full rotation of the track includes a non-zero propulsive force component in a propulsion direction.

A system (100) for generating electricity comprising - at least one structure (1) defining an upper support surface (11) and a lower support surface (12); - a plurality of cranes (2, 2a, 2b, 2c, 2d, 2e) adapted to move a plurality of bodies (3) from the upper support surface (11) to the lower support surface (12), and vice versa; wherein each crane (2, 2a, 2b, 2c, 2d, 2e) is provided with - gripping means (21 ) adapted to grasp a body (3) of said plurality of bodies (3); - and a device (4) connected to the gripping means (21), adapted to transform into electricity the kinetic energy of a body (3) grasped by the gripping means (21 ), which moves, in particular substantially vertically, under the effect of gravity towards the lower support surface (12).

A nonpropellant inertial device to propel structures on and off earth is disclosed. Secured on a rigid planar base are electrically powered motors for two crankshafts. Pair of parallel linkages are connected between the crankshafts and the sides of a freely rotatable cylintrical weight. The crankshafts rotate differentially to create straight-line reciprocating motion to the linkages. The linkages are design to only pull the cylindrical weight from one side then the other causing the weight to rotate back and forth in reciprocal motion, traverse to the straight-line motion of the linkages. High frequency impulses alternate from the sides of the cylintrical weight with each impulse being a simultaneous action-reaction event. However, only part of the angular action to the weight, directly opposes the straight-line reaction to the crankshafts. Therefore, a net amount of reaction remains to impart unidirectional inertial propulsion to the mover. Two similar cylintrical weight systems are generally used for cancelling out lateral vibrations to the mover.