RU2009117950A - PNEUMATIC HYDROSTATIC ENGINE FOR ENVIRONMENTALLY FRIENDLY POWER PLANT - Google Patents

Abstract

1. Pneumohydrostatic engine for an environmentally friendly power plant, comprising a gravity transducer in a mechanical reciprocating motion, a mechanical reciprocating motion transducer in a rotational mechanical motion, a rotary mechanical motion transducer in electric energy, characterized in that the pneumohydrostatic engine for an environmentally friendly power plant includes a housing, power system consisting of working bodies, connecting rods, crank mechanism and, a multiplier, electricity generator, and a control system consisting of the storage of a starter battery, a compressor, a receiver with a pressure gauge, an air line, bottom flaps and top flaps. ! 2. Pneumohydrostatic engine for an environmentally friendly power plant according to claim 1, characterized in that the power unit of the pneumohydrostatic engine consists of more than one working fluid, each of which reciprocates strictly vertically in the space between the top dead center and bottom dead point as a result of alternately filling the cavities of the working fluid with air or other gas in the bottom dead center, which ensures the movement of the working fluid up under the action of the ejection strength, and water or other fluid in the upper dead point, while the release of air from the working body cavity, whereby the buoyant force is turned off, and the vertical reciprocating movement of working fluids provides rollers disposed on opposite sides of the side walls of the working substances, and nap

Claims (9)

1. Pneumohydrostatic engine for an environmentally friendly power plant, comprising a gravity transducer in a mechanical reciprocating motion, a mechanical reciprocating motion transducer in a rotational mechanical motion, a rotary mechanical motion transducer in electric energy, characterized in that the pneumohydrostatic engine for an environmentally friendly power plant includes a housing, power system consisting of working bodies, connecting rods, crank mechanism and, a multiplier, electricity generator, and a control system consisting of the storage of a starter battery, a compressor, a receiver with a pressure gauge, an air line, bottom flaps and top flaps. 2. Pneumohydrostatic engine for an environmentally friendly power plant according to claim 1, characterized in that the power unit of the pneumohydrostatic engine consists of more than one working fluid, each of which reciprocates strictly vertically in the space between the top dead center and bottom dead point as a result of alternately filling the cavities of the working fluid with air or other gas in the bottom dead center, which ensures the movement of the working fluid up under the action of the ejection forces, and water or other liquid at the top dead center while simultaneously releasing air from the cavity of the working fluid, as a result of which the buoyancy force is turned off, and the vertical reciprocating movement of the working fluid is provided by rollers located on opposite sides of the side walls of the working fluid, and guide rods or other known devices, while connecting rods, which are pivotally connected to the working ends with their lower ends, are attached to the working bodies, mainly to their upper part, using known fasteners and bodies, and their upper ends - with cranks of a crank mechanism, which includes a crankshaft with a crank and connecting rod, while the crankshaft rotates in the bearings, and the crankshaft crankshaft output is connected to the input of the multiplier, the output of which is connected to the generator shaft transforming the rotational movement of the crankshaft crank mechanism into electricity. 3. Pneumohydrostatic engine for an environmentally friendly power plant according to claim 2, characterized in that the multiplier has more than one stage of multiplying the crankshaft speed of the crank mechanism. 4. Pneumohydrostatic engine for an environmentally friendly power plant according to claim 1, characterized in that the housing of the pneumohydrostatic engine and the power system of the pneumohydrostatic engine are placed in a pool that is filled with water or other liquid to a level above the top dead center. 5. Pneumohydrostatic engine for an environmentally friendly power plant according to claim 4, characterized in that the pool consists of compartments filled with water or other liquid up to the level above the top dead center, and the working fluid of the power system of the pneumohydrostatic engine performs reciprocating movement inside these compartments. 6. Pneumohydrostatic engine for an environmentally friendly power plant according to claim 1, characterized in that the control system of the pneumohydrostatic engine consists of lower valves and upper valves that provide reciprocating movement (ascent and immersion) of the working fluid in the space between the bottom dead center and the top dead center by alternately filling the working fluid with air or another gas and water or other liquid, while the lower valves are connected to the outlets of the air line, which th end is connected to a receiver equipped with a manometer, and is connected to the compressor supplying air to the air or other gas line, and powered by a rechargeable battery which is recharged by a generator. 7. Pneumohydrostatic engine for an environmentally friendly power plant according to claim 6, characterized in that the control system of the pneumatic hydrostatic engine is equipped with a system for recovering (storing) excessive pressure of air or other gas, which ensures the reuse of air or other gas in the air line using air ducts connecting openings of the working fluid through which air or other gas leaves the working fluid, with an air line. 8. Pneumohydrostatic engine for an environmentally friendly power plant according to claim 6, characterized in that the upper valve mounted on the upper panel of the working fluid, having in its upper panel openings for air or other gas to exit the working fluid, and in the lower part having no bottom consists of a valve cover in the form of a cup with a sleeve for attaching the valve axis, the valve axis itself, a spring, an annular gasket to ensure a tight fit of the valve cover in the form of a cup to the working medium panel, a thrust sleeve on the upper end of the axis the valve, which, when the valve is opened, comes into contact with a special stop rigidly connected to the body of the pneumohydrostatic engine, due to which the valve axis moves vertically downwards, overcoming the spring resistance, and the valve opens, as a result of which air or other gas is squeezed out through these valve openings with water or other liquid and as a result, the working fluid is filled with water and the buoyant force acting on the working fluid is turned off, and as soon as the working fluid leaves the top dead center and the upper valve is closed by the spring. 9. Pneumohydrostatic engine for an environmentally friendly power plant according to claim 6, characterized in that the bottom valve connected to the output of the air line consists of a drive switch for the control mechanism with an eccentric plate, a drive control rod with a roller, an end position lock, an end position spring, traction of the control mechanism, the lever of the control mechanism with two axes of the lever and two axles of the rods of the lower valve, as well as the traction of the lower valve, while the drive switch of the control mechanism is mounted on the central the crankshaft of the crank mechanism, and the linkage control rod is mounted on an individual axis rigidly fixed to the body of the pneumohydrostatic engine; the initial position of the traction control disk is guaranteed by the end position lock and the spring of the extreme position, while the control mechanism pulls away from the traction control disk, which is connected to the control lever by the second end, which is able to swing in two axes of the control lever, while to the second ends of the control lever the axles of the lower valve rods are connected, and the swing arms of the control lever are asymmetrical, in a ratio of the order of 1: 5, while the eccentric plate on the drive The control casing in its angular position and the value of the angle of rotation of the crankshaft (recalculated during the on position of the lower valve) is made in such a way that the start of the rotation of the drive control rod from the initial position occurs at the moment when the working fluid approaches the bottom dead center; under the action of the eccentric plate, the force from the control gear enable disk is transmitted through the roller to the traction control disk, the control gear rod moves upward, shifting the left edge of the control gear lever up, the control gear lever rotates in the axes of the control gear lever, providing the right edge of the control gear lever to move down , two rods of the lower valve synchronously move the rods of the lower valve down, which leads to the opening of the lower valve; in this position, the lower valve is located until the eccentric plate holds the traction control disk in the turned position and as soon as the roller leaves the eccentric plate under the action of the spring of the extreme position, the traction control disk returns to its original position and as a result the lower valve closes, and thus , the eccentric plate provides a fixed on time for the bottom valve.