RU2011104532A - METHOD AND DEVICE FOR CONVERSION OF HEAT ENERGY IN USEFUL WORK - Google Patents

Abstract

 1. A method of converting thermal energy into useful work, including: vaporization of an easily evaporating low-boiling working fluid, its condensation and its completion in a closed cycle, characterized in that the vaporized working fluid is first condensed, transferring the latent heat of condensation to the working fluid located in the liquid aggregate state, while heating the latter with the warmth of the environment, expanding, it moves one step L of the pistons of the hydraulic cylinders, which are located behind this the magnitude from each other, and which transmit the movement of the transmission fluid, which acts on the large piston located at the extreme upper point of one hydraulic cylinder and moves it over the entire length of the stroke Lх, transferring the heated working fluid through the valve-distributor to the rotor of the jet turbine, making useful work, also when moving the pistons one step L into the cavity below them, a cold working fluid is sucked from the storage-evaporator through their check valves, and during the next working cycle repeats the same, but with the alternation of the cylinder supplying the working fluid to the jet turbine, and the step L to which the pistons move in one working cycle is calculated by the formula:! ! where Lpx is the length of the piston stroke of the cylinder, N is the number of cylinders. ! 2. A device for converting thermal energy into useful work, consisting of a storage-evaporator of an easily evaporating, low-boiling working fluid, a pump, a condenser connected to a piston mechanism with valves and a mechanism for performing useful work, characterized in that �

Claims (6)

1. A method of converting thermal energy into useful work, including: vaporization of an easily evaporating low-boiling working fluid, its condensation and its completion in a closed cycle, characterized in that the vaporized working fluid is first condensed, transferring the latent heat of condensation to the working fluid located in the liquid aggregate state, while heating the latter with the warmth of the environment, expanding, it moves one step L of the pistons of the hydraulic cylinders, which are located behind this elichinu from one another and which transmit the movement of the transmission fluid, which acts on the large piston located in the topmost point of the hydraulic cylinder and moves it over the entire length of the working stroke L _p, passing the preheated working fluid through the valve distributor to the rotor jet turbine undergoing a useful work, also when moving the pistons one step L into the cavity below them, a cold working fluid is sucked from the storage-evaporator through their check valves, and in the next working cycle, repeat the same, but with the alternation of the cylinder feeding the working fluid to the jet turbine, and the step L to which the pistons move in one working cycle is calculated by the formula:

, where L _px is the length of the piston stroke of the cylinder, N is the number of cylinders. 2. A device for converting thermal energy into useful work, consisting of a storage-evaporator of an easily evaporating, low-boiling working fluid, a pump, a condenser connected to a piston mechanism with valves, and a useful work mechanism, characterized in that the piston mechanism is made of N, at least two-piston stepped hydraulic cylinders, and the steps with a smaller piston are placed in heat transfer tubes communicating with check valves with thermally insulated hydro steps cylinders with large pistons and interconnected through communicating channels with a transmission fluid, in addition, heat pump coils are placed inside the heat exchange tubes, and alternately for one cycle of operation only one of the hydraulic cylinders has the ability to supply a heated liquid working fluid through the valve a distributor, on the rotor of the mechanism for performing useful work - a jet turbine, and the remaining hydraulic cylinders of the piston group are made with the possibility of transmitting movement to this one supply guide of logs. 3. The device according to claim 2, characterized in that the rotor of the jet turbine is made S-shaped with Laval nozzles located at the exit of it. 4. The device according to claim 2, characterized in that devices that produce work due to the temperature difference are placed on the heat exchange tubes. 5. The device according to claim 4, characterized in that thermoelectric elements are placed on the heat exchange tubes. 6. The device according to claim 4, characterized in that the heat exchanger tubes are equipped with a cooler for an “external combustion” engine, such as a Stirling engine.