Abstract: A fluid dynamic kinetic energy-based frictionless type generator of a range extender and recharger for an electric vehicle or device and the production of electricity is characterized by converting fluid motion into electric energy. This device uses the drag force acting opposite to the relative motion of objects moving with respect to a surrounding fluid. This force can exist between two fluid layers or a fluid and a solid surface. The device comprises a cylinder covered with paddles, air ducting ramp, permanent magnets, armature winding, charge controller and battery bank. It's a frictionless, high efficiency, brushless generator design that utilizes kinetic energy produced by drag, pressure, friction, fluid resistance, fluid dynamics, aerodynamics, wind, and or motion together with the device itself to create a frictionless brushless generator that will deliver power to the engine directly, the enclosed battery bank or can be diverted to the vehicle battery bank for recharging.

Abstract: An assembly for a shoe or other footwear comprising computer controlled individually configurable inflatable air bladder orthotic structures that are monitored by a flexible pressure sensor pad. Comprising of a plurality of regions, each region including a respective plurality of air bladders; each respective air bladder being individually feed by a separate tube; each tube having a self-sealing valve disposed thereon and configured to allow air to enter the bladder through the valve while maintaining air pressure within the air bladder; and each self-sealing tube valve configured to allow air to escape through the valve via a computer controlled mini compressor integrated pump and release valve device. Where the air bladders are feed air through a mini smart compressor, which additionally can be controlled by a smart phone or computer. Said smart compressor connects with the shoe assembly at the heel pad plug in.

Abstract: A wheel-based generator of a range extender and recharger for an electric vehicle is characterized by comprising an armature winding, wheel cover, wheel well, tire, permanent magnets, spokes, charge controller and battery bank. This is a frictionless, high efficiency, brushless generator design that utilizes the wheel well and or wheel cover, together with the mechanical energy of the tire itself to create a frictionless brushless generator that will deliver power to the engine directly or can be diverted to the battery bank for recharging.

Abstract: The present invention involves methods and apparatus for permanent downhole deployment of optical sensors. Specifically, optical sensors may be permanently deployed within a wellbore using a casing string. In one aspect, one or more optical sensors are disposed on, in, or within the casing string. The optical sensors may be attached to an outer surface of the casing string or to an inner surface of the casing string, as well as embedded within a wall of the casing string. The optical sensors are capable of measuring wellbore parameters during wellbore operations, including completion, production, and intervention operations.

Abstract: The present generally relates to apparatus and methods for instrumentation associated with a downhole deployment valve or a separate instrumentation sub. In one aspect, a DDV in a casing string is closed in order to isolate an upper section of a wellbore from a lower section. Thereafter, a pressure differential above and below the closed valve is measured by downhole instrumentation to facilitate the opening of the valve. In another aspect, the instrumentation in the DDV includes sensors placed above and below a flapper portion of the valve. The pressure differential is communicated to the surface of the well for use in determining what amount of pressurization is needed in the upper portion to safely and effectively open the valve. Additionally, instrumentation associated with the DDV can include pressure, temperature, seismic, acoustic, and proximity sensors to facilitate the use of not only the DDV but also telemetry tools.

Abstract: Methods for forming a portion of a wellbore are provided. The well is drilled from a first selected depth to a second selected depth to form a bore through a surrounding earth formation. A fluid heating apparatus is disposed within the bore on a working string. Fluid is then heated by moving the fluid through the fluid heating apparatus in the wellbore. The process of circulating fluid adjacent the earth formation serves to also heat the surrounding formation so as to increase the fracture gradient. The fluid heating process may be conducted during a drilling procedure. Alternatively, the fluid heating process may be conducted in connection with a liner hanging and cementing process. A fluid flow restrictor is provided along a run-in assembly that serves to warm the fluids as they are circulated. The warm fluids provide convective heat to the surrounding earth formation, thereby reducing the formation's fracture gradient.

Abstract: A nasal inhaler has a body with an open end and containing a frangible fluid containing ampul. A nozzle is mounted in the open end for movement relative to the body and the ampul. Structure responsive to the movement of the nozzle relative to the body and the ampul ruptures the ampul and releases the contained fluid.