77results about How to "Keep the heat" patented technology

A mechanical thermo-voltaic solar power system (MeTSoPoS) that uses a mechanical generator, instead of the photovoltaic panel commonly in use today, is disclosed. The system is comprised of three major subsystems: (1) a light collector array, (2) a mechanical thermo-voltaic generator, and (3) a storage and retrieval system. At the center of the system is the light collection array comprised of solar collector elements. These collector elements are connected to optical conduits (fiber optic cables) that carry the light energy to a mechanical generator. An automatic aiming system is used to align the collector elements directly at a light source for maximum light output. Each light collector element is comprised of a set of lenses that focus a larger area of light down to a point small enough to inject into an optical conduit. The optical conduit is then used to carry the light from each collector element to the generator. The system can use either a steam turbine or a Stirling engine type of mechanical generator, which is connected to a standard AC generator for generating electrical power. The heating chamber involves an outer shell where the optical conduits attach and allows the light to shine through to the heating area of either the boiler of a steam turbine or the hot node of a Stirling engine. Additionally, a small hole is provided in the bottom of the heating chamber where a gas burner is mounted to provide an auxiliary means of providing heat to the system. The burner can be fueled by natural gas or from stored hydrogen from the system. Electricity from the system that is not used immediately is redirected to a storage unit, such as a bank of batteries. In the system, electricity can be taken directly form the generator or can be used to charge the batteries and taken from them when needed. The overall system has a means of monitoring the amount of energy being generated and if that is less than is being used for auto aiming and other nonessential functions, it will shut down those functions and switch into energy retrieval mode.

A method for making structural automotive components and the like includes providing a blank of air hardenable martensitic stainless steel in the annealed condition. The steel blank has a thickness in the range of 0.5-5.0 mm., and is formed utilizing stamping, forging, pressing, or roller forming techniques or the like into the form of an automotive structural member. The automotive structural member is then hardened by application of heat, preferably to between 950° C. and 1100° C. for standard martensitic stainless steels. Thereafter, the automotive structural member is preferably cooled at a rate greater than 25° C. per minute to achieve a Rockwell C hardness of at least 39. The automotive structural member may undergo additional heat treating processes including high temperature or low temperature tempering processes which may incorporate electro-coating.

A method for making structural automotive components and the like includes providing a blank of air hardenable martensitic stainless steel in the annealed condition. The steel blank has a thickness in the range of 0.5-5.0 mm., and is formed utilizing stamping, forging, pressing, or roller forming techniques or the like into the form of an automotive structural member. The automotive structural member is then hardened by application of heat, preferably to between 950° C. and 1100° C. for standard martensitic stainless steels. Thereafter, the automotive structural member is preferably cooled at a rate greater than 25° C. per minute to achieve a Rockwell C hardness of at least 39. The automotive structural member may undergo additional heat treating processes including high temperature or low temperature tempering processes which may incorporate electro-coating.

A mechanical thermo-voltaic solar power system (MeTSoPoS) that uses a mechanical generator, instead of the photovoltaic panel commonly in use today, is disclosed. The system is comprised of three major subsystems: (1) a light collector array, (2) a mechanical thermo-voltaic generator, and (3) a storage and retrieval system. At the center of the system is the light collection array comprised of solar collector elements. These collector elements are connected to optical conduits (fiber optic cables) that carry the light energy to a mechanical generator. An automatic aiming system is used to align the collector elements directly at a light source for maximum light output. Each light collector element is comprised of a set of lenses that focus a larger area of light down to a point small enough to inject into an optical conduit. The optical conduit is then used to carry the light from each collector element to the generator. The system can use either a steam turbine or a Stirling engine type of mechanical generator, which is connected to a standard AC generator for generating electrical power. The heating chamber involves an outer shell where the optical conduits attach and allows the light to shine through to the heating area of either the boiler of a steam turbine or the hot node of a Stirling engine. Additionally, a small hole is provided in the bottom of the heating chamber where a gas burner is mounted to provide an auxiliary means of providing heat to the system. The burner can be fueled by natural gas or from stored hydrogen from the system. Electricity from the system that is not used immediately is redirected to a storage unit, such as a bank of batteries. In the system, electricity can be taken directly form the generator or can be used to charge the batteries and taken from them when needed. The overall system has a means of monitoring the amount of energy being generated and if that is less than is being used for auto aiming and other nonessential functions, it will shut down those functions and switch into energy retrieval mode.

A vehicle is equipped with an automated device for covering the windows of the vehicle. The device comprises a collection container, a plurality of the extensions attached to the collection container, a motor attached to the collection container to rotate the collection container, and a covering attached to the plurality of extensions and sized to cover the windows of the vehicle. The rotation of the collection container extends and retracts the plurality of extensions which results in the deployment of the covering over the windows of the vehicle and the collection of the covering from the windows of the vehicle. In a preferred embodiment, the plurality of extensions comprises malleable metal strips with eyelets at the end of the metal strips. The eyelets and the metal strips are positioned within sleeves or channels which are made integral to the covering. The covering includes a reflective fabric that is substantially opaque to sunlight.

A thermal athletic glove which comprises a back side portion that has an inner layer to provide comfort to a hand and fingers of a person, an intermediate layer to lock heat in, and an outer layer to keep the heat in. A palm side portion has an inner layer to provide comfort to the hand and the fingers of the person, an intermediate layer to lock the heat in, and an outer layer to provide an optimal grip while allowing maximum flexibility for the fingers and the hand of the person.

A heatable pet garment comprised of a garment covering the body of an animal with an opening for the head of said animal and at least two openings for the legs of said animal; a heat device within said garment to produce heat to warm said garment; a rechargeable electrical source to power said heat device; a mechanism to recharge said electrical source; and a control unit to turn said electrical source on and off.

The invention provides a sensor comprising a frame, a plurality of beams extending inwardly from said frame, a weight portion supported by the beams, a piezoelectric-resistor formed on each beam and an insulating layer that covers the piezoelectric-resistor. The piezoelectric-resistor has at least one bend, and a metal wiring is located on the insulting layer positioned at the bend. The metal wiring is connected to the bend via at least two contact holes formed in the insulating layer. Contact holes are formed in the insulating layer positioned at both ends of the piezoelectric-resistor, and a bridge circuit wiring is connected to the piezoelectric-resistor via the contact holes.

An inflator is a hybrid inflator constructed by coupling a tank charged with a pressurized gas and a gas generator containing a gas-generating chemical. A coupling mechanism is provided in each of the tank and the gas generator, and the tank and the gas generator are coupled to each other with the coupling mechanisms.

The invention provides a sensor comprising a frame, a plurality of beams extending inwardly from said frame, a weight portion supported by the beams, a piezoelectric-resistor formed on each beam and an insulating layer that covers the piezoelectric-resistor. The piezoelectric-resistor has at least one bend, and a metal wiring is located on the insulting layer positioned at the bend. The metal wiring is connected to the bend via at least two contact holes formed in the insulating layer. Contact holes are formed in the insulating layer positioned at both ends of the piezoelectric-resistor, and a bridge circuit wiring is connected to the piezoelectric-resistor via the contact holes.

A method of adjusting sensitivity of signal interpretation includes the steps of: continuously receiving an input signal; setting a sampling parameter; sampling the input signal according to the sampling parameter to obtain a plurality of sampling signals; judging whether the sampling signals are the same or not; generating a first control signal according to the sampling signals if the sampling signals are the same; and generating a second control signal according to the input signal if the sampling signals are not the same. A device of adjusting the sensitivity of signal interpretation is also disclosed.

An apparatus and method for extracting oils and fats from oil-bearing substances without using degrading temperatures. The apparatus may comprise an extraction chamber containing an oil-bearing substance, an oil-collecting chamber, a recovery pump, a first jacket adjacent at least a portion of the extraction chamber, and a second jacket adjacent at least a portion of the oil-collecting chamber. The method involves heating a solvent and reducing pressure to facilitate a low-temperature vacuum boil; delivering the heated solvent into the extraction chamber configured to facilitate the low-temperature vacuum boil of the solvent within the extraction chamber; pumping the solvent in vapor form out of the extraction chamber with the recovery pump; delivering the oil and fat extracted in the extraction chamber to the oil-collecting chamber; pumping solvent in vapor form out of the oil-collecting chamber with the recovery pump; and delivering the solvent received by the recovery pump to the first and second jackets to provide heat to the chambers.

An apparatus for exploiting the thermal energy at the bottom of the ocean. The apparatus comprises a thermal energy harnessing assembly and a drilling assembly mounted thereto. The thermal energy harnessing assembly includes in-feed tube and out-feed tubes. The drilling assembly has openings in fluid communication with the in-feed tube and a thermal energy capturing conduit in fluid communication with the out-feed tube. When the drilling assembly engages a bottom surface of the ocean and fluid is introduced into the in-feed tube, fluid flows towards the drilling assembly and out of the openings at such a pressure as to drill into the bottom surface of the ocean allowing thermal energy to escape therefrom and to flow into the out-feed tube via the thermal energy capturing conduit.