Parallel motion heat energy power machine and working method thereof

Abstract

A parallel motion heat energy power machine and a working method thereof, includes a heat collector, an insulating pipe, a gasification reactor, an atomizer, a cylinder, a piston, a piston ring, an automatic exhaust valve, a cooler, a liquid storage tank, a pressure pump, a push-pull rod, an insulating layer, and a housing. The two cylinders are oppositely arranged on the housing in parallel. The piston is arranged inside the cylinder. The piston is provided with the piston ring. The pistons are arranged on both ends of the push-pull rod. The heat collector is connected to the gasification reactor through the insulating pipe. The atomizer is arranged on the air inlet end of the gasification reactor. The parallel motion heat energy power machine and working method thereof has a high heat-energy conversion efficiency. It is energy-saving, environmentally friendly, and less noisy.

Claims

1. A parallel motion heat energy power machine, comprising a heat collector, two insulating pipes, two gasification reactors, two atomizers, two cylinders, two pistons, at least one piston ring, two automatic exhaust valves, a cooler, a liquid storage tank, two pressure pumps, a push-pull rod, an insulating layer, and a housing; wherein the two cylinders are oppositely arranged on the housing in parallel; wherein the two pistons are arranged inside the two cylinders respectively; wherein the each piston is provided with at least one of the at least one piston ring; wherein the two pistons are arranged on both ends of the push-pull rod respectively; wherein the heat collector is connected to the two gasification reactors through the two insulating pipes respectively; wherein the two atomizers are arranged on air inlet ends of the two gasification reactors respectively; wherein the two atomizers are connected to the two pressure pumps respectively; wherein the two pressure pumps are both connected to the liquid storage tank; wherein the two gasification reactors are arranged on top dead centers of the two cylinders respectively; wherein the two automatic exhaust valves are arranged on bottom dead centers of the two cylinders respectively; wherein the two automatic exhaust valves are both connected to the cooler; wherein the cooler is connected to the liquid storage tank; and wherein an outer layer of the housing is provided with the insulating layer.

2. The parallel motion heat energy power machine according to claim 1, wherein the heat collector can absorb solar energy, geothermal energy, high-temperature gas generated by burning of a combustible, exhaust gas of an internal combustion engine, or high-temperature gas discharged from a factory.

3. The parallel motion heat energy power machine according to claim 1, wherein each gasification reactor includes a pressure vessel, a gasification conducting strip, and a plurality of gas holes; wherein each of the gasification conducting strips is arranged on a respective pressure vessel; wherein the plurality of gas holes are arrayed on each of the gasification conducting strips; and wherein one of the atomizers is arranged on an air inlet end of each of the pressure vessels.

4. The parallel motion heat energy power machine according to claim 1, wherein the pressure pumps are associated with the push-pull rod; wherein each pressure pump opens and closes once whenever a circulation is completed.

5. The parallel motion heat energy power machine according to claim 1, wherein the push-pull rod is provided with a transmission shaft, which connects to a rotor of a generator to cut magnetic induction lines.

6. A method of using the parallel motion heat energy power machine according to claim 1, comprising: absorbing, by the heat collector, solar energy, geothermal energy, high-temperature gas generated by burning a combustible, heat energy or exhaust gas of an internal combustion engine, or high-temperature gas discharged from a factory; transmitting heat to the gasification reactors directly or via a the insulating pipes, wherein the insulating pipes are provided with a flowing heat conducting medium; injecting, through the pressure pumps, a liquid working medium into the gasification reactors to be atomized; gasifying and expanding, by the gasification reactors, the atomized working medium; discharging working gas from the automatic exhaust valves when one of the pistons reaches a bottom dead center of the respective cylinder; cooling the discharged gaseous working medium by the cooler; wherein, when the other piston reaches a top dead center of the other cylinder, the respective pressure pump for the other cylinder opens, the liquid working medium is injected into the respective gasification reactor through the respective atomizer so as to gasify and expand to push the other piston to work; wherein the two pressure pumps open and close in turns; wherein the two pistons inside the two cylinders take turns to work; and wherein kinetic energy is output by the push-pull rod.

7. A method of using the parallel motion heat energy power machine according to claim 2, comprising: absorbing, by the heat collector, solar energy, geothermal energy, high-temperature gas generated by burning a combustible, heat energy or exhaust gas of an internal combustion engine, or high-temperature gas discharged from a factory; transmitting heat to the gasification reactors directly or via a the insulating pipes, wherein the insulating pipes are provided with a flowing heat conducting medium; injecting, through the pressure pumps, a liquid working medium into the gasification reactors to be atomized; gasifying and expanding, by the gasification reactors, the atomized working medium; discharging working gas from the automatic exhaust valves when one of the pistons reaches a bottom dead center of the respective cylinder; cooling the discharged gaseous working medium by the cooler; wherein, when the other piston reaches a top dead center of the other cylinder, the respective pressure pump for the other cylinder opens, the liquid working medium is injected into the respective gasification reactor through the respective atomizer so as to gasify and expand to push the other piston to work; wherein the two pressure pumps open and close in turns; wherein the two pistons inside the two cylinders take turns to work; and wherein kinetic energy is output by the push-pull rod.

8. A method of using the parallel motion heat energy power machine according to claim 3, comprising: absorbing, by the heat collector, solar energy, geothermal energy, high-temperature gas generated by burning a combustible, heat energy or exhaust gas of an internal combustion engine, or high-temperature gas discharged from a factory; transmitting heat to the gasification reactors directly or via a the insulating pipes, wherein the insulating pipes are provided with a flowing heat conducting medium; injecting, through the pressure pumps, a liquid working medium into the gasification reactors to be atomized; gasifying and expanding, by the gasification reactors, the atomized working medium; discharging working gas from the automatic exhaust valves when one of the pistons reaches a bottom dead center of the respective cylinder; cooling the discharged gaseous working medium by the cooler; wherein, when the other piston reaches a top dead center of the other cylinder, the respective pressure pump for the other cylinder opens, the liquid working medium is injected into the respective gasification reactor through the respective atomizer so as to gasify and expand to push the other piston to work; wherein the two pressure pumps open and close in turns; wherein the two pistons inside the two cylinders take turns to work; and wherein kinetic energy is output by the push-pull rod.

9. A method of using the parallel motion heat energy power machine according to claim 4, comprising: absorbing, by the heat collector, solar energy, geothermal energy, high-temperature gas generated by burning a combustible, heat energy or exhaust gas of an internal combustion engine, or high-temperature gas discharged from a factory; transmitting heat to the gasification reactors directly or via a the insulating pipes, wherein the insulating pipes are provided with a flowing heat conducting medium; injecting, through the pressure pumps, a liquid working medium into the gasification reactors to be atomized; gasifying and expanding, by the gasification reactors, the atomized working medium; discharging working gas from the automatic exhaust valves when one of the pistons reaches a bottom dead center of the respective cylinder; cooling the discharged gaseous working medium by the cooler; wherein, when the other piston reaches a top dead center of the other cylinder, the respective pressure pump for the other cylinder opens, the liquid working medium is injected into the respective gasification reactor through the respective atomizer so as to gasify and expand to push the other piston to work; wherein the two pressure pumps open and close in turns; wherein the two pistons inside the two cylinders take turns to work; and wherein kinetic energy is output by the push-pull rod.

10. A method of using the parallel motion heat energy power machine according to claim 5, comprising: absorbing, by the heat collector, solar energy, geothermal energy, high-temperature gas generated by burning a combustible, heat energy or exhaust gas of an internal combustion engine, or high-temperature gas discharged from a factory; transmitting heat to the gasification reactors directly or via a the insulating pipes, wherein the insulating pipes are provided with a flowing heat conducting medium; injecting, through the pressure pumps, a liquid working medium into the gasification reactors to be atomized; gasifying and expanding, by the gasification reactors, the atomized working medium; discharging working gas from the automatic exhaust valves when one of the pistons reaches a bottom dead center of the respective cylinder; cooling the discharged gaseous working medium by the cooler; wherein, when the other piston reaches a top dead center of the other cylinder, the respective pressure pump for the other cylinder opens, the liquid working medium is injected into the respective gasification reactor through the respective atomizer so as to gasify and expand to push the other piston to work; wherein the two pressure pumps open and close in turns; wherein the two pistons inside the two cylinders take turns to work; and wherein kinetic energy is output by the push-pull rod.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is the structural schematic diagram of the invention;

(2) FIG. 2 is the structural diagram of the gasification reactor of the invention;

(3) In figures: 1 is a heat collector; 2 is an insulating pipe; 3 is a gasification reactor; 4 is an atomizer; 5 is a cylinder; 6 is a piston; 7 is a piston ring; 8 is an automatic exhaust valve; 9 is a cooler; 10 is a liquid storage tank; 11 is a pressure pump; 12 is a push-pull rod; 13 is an insulating layer; 14 is a housing; 15 is a pressure vessel; 16 is it gasification conducting strip; 17 is a gas hole.

DETAILED DESCRIPTION OF THE EMBODIMENT

(4) Referring to FIGS. 1-2, the embodiments of the invention are as follows:

(5) Embodiment 1

(6) A parallel motion heat energy power machine includes a heat collector 1, insulating pipes 2. gasification reactors 3, atomizers 4, cylinders 5, pistons 6, piston rings 7, automatic exhaust valves 8, cooler 9, liquid storage tank 10, pressure pumps 11, push-pull rod 12, insulating layer 13, and a housing 14. Two cylinders 5 are oppositely arranged on housing 14 in parallel Piston 6 is arranged inside cylinders 5. Piston 6 is provided with piston rings 7. Pistons 6 are arranged on both ends of push-pull rod 12. Heat collector 1 is connected to gasification reactor 3 through insulating pipe 2. Atomizer 4 is arranged on the air inlet end of gasification reactors 3. Atomizer 4 is connected to pressure pumps 11 through the pipes. Pressure pump 11 is connected to liquid storage tank 10 through the pipes. Gasification reactor 3 is arranged on the top dead center of cylinder 5. Automatic exhaust valve 8 is arranged on the bottom dead center of cylinder 5. Automatic exhaust valve 8 is connected to cooler 9 through the pipes. Cooler 9 is connected to liquid storage tank 10 through the pipes. The outer layer of the housing 14 is provided with insulating layer 13.

(7) Embodiment 2

(8) The parallel motion heat energy power machine as described in Embodiment 1, the gasification reactor includes pressure vessel 15, gasification conducting strip 16, gas hole 17, atomizer 4. Gasification conducting strip 16 is arranged on pressure vessel 15. Gas hole 17 is arrayed on gasification conducting strip 16. Atomizer 4 is arranged on the air inlet end of pressure vessel 15. Pressure pump 11 is associated with push-pull rod 12. pressure pump 11 opens and closes once whenever the circulation is completed. Push-pull rod 12 is provided with a transmission shaft, which connects to the rotator of the generator to cut the magnetic induction lines. Cooler 9 uses the natural water cooling method or the condenser.