KR20160002413A - A heat engine - Google Patents

Abstract

The present invention relates to a heat engine, in which a first connecting rod of a piston and a piston is formed in one cylinder chamber, and the first connecting rod reciprocates through a hole in which air is not leaked at one side wall of the cylinder chamber Both ends of the inside of the cylinder chamber portion and the cylinder chamber in which the piston portion is closed are heated by a hot wire or a gas fire or the like in the hole of the hole in which the air can be taken in and out and the hole in which the valve capable of opening and closing the hole is formed The piston is reciprocated by a valve opening / closing control unit which is formed as a heating unit and which is closed to the cylinder chamber on the side where the air of the cylinder chamber divided by the piston is divided into two and the cylinder chamber where the air on the opposite side is opened alternately .

Description

{A heat engine}

The present invention relates to a machine for increasing the kinetic energy of gas molecules by applying heat to a gas and for obtaining mechanical energy by causing the gas molecules to push the piston.

A heat engine

A generic term for prime movers that convert thermal energy into mechanical energy to generate power. Vapor pressure of liquid, vapor of liquid, vapor of liquid, combustion of liquid, explosion, and the like, including steam engine, steam turbine and internal combustion engine.

A machine that increases the kinetic energy of gas molecules by applying heat to the gas and which causes the gas molecules to push the piston to obtain mechanical energy is called a heat engine. Since you can not just push the piston to get the kinetic energy, you have to take the heat of the expanded gas back to bring the piston back to its original position. Therefore, a given amount of gas trapped in the piston is given heat to expand it. Once the cooling operation is repeated, the piston can continue to move.

The gas can work while expanding. At this time, as the heat is increased, the gas expands vigorously and the piston moves strongly, and as the heat takes a lot, the piston contracts strongly and the piston moves strongly. To increase heat, the temperature at the time of heating must be high, and the temperature at the time of cooling should be low in order to take a lot of heat. Thus, the larger the temperature difference between heating and cooling the gas, the more forceful the piston moves.

turbine

[turbine]

summary

A machine that converts the energy of fluids such as water, gas, and steam into useful mechanical work.

Steam turbine

Steam Turbine One price of a turbine blade is said to be similar to mid-sized car prices.

It is characterized by rotating motion. Generally, a turbomachine is a turbine in which several blades or wings are placed on the circumference of a rotating body, and steam or gas is blown thereon to rotate the rotor at a high speed.

It is the hydro turbine that drops water at high altitudes and passes it through the runner runner to convert the water energy into mechanical work. Steam turbines use steam energy to blow the steam from the nozzle and hit it against the feather . Steam turbines also have impulsive and recirculating turbines, and some hybrid turbines combine the advantages of both.

It is the gas turbine that uses the energy of the high-temperature and high-pressure gas, and the air turbine that uses the energy of the high-pressure compressed air. Turbines are all important for industrial power. Steam turbines are used to drive generators in nuclear power plants, as well as thermal power plants, and hydraulic turbines are used to move generators in hydropower plants.

External engine

[external combustion engine, external combustion engine]

The generic term for external combustion engines includes piston-type steam engines and turbine-type steam engines.

The problem to be solved by the present invention is to increase the kinetic energy of gas molecules by applying heat to the gas and to selectively push the gas molecules to push the piston but to reduce the air pressure inside the cylinder by continuously pushing and pulling the piston And to provide the kinetic energy that makes them exercise.

The first connecting rod of the piston and the piston is formed inside the one cylinder chamber and the first connecting rod reciprocates through the hole of the one side wall of the cylinder chamber, The end of the first connecting rod is linked to the second connecting rod, the other end of the second connecting rod is linked to the crankshaft, and both ends of the inside of the closed cylinder chamber are provided with a hole through which air can be taken in and out, And the valve is closed by a solenoid valve or the like, and the cylinder is heated by heat or gas.

The effect of the present invention is that it does not require water, unlike a steam engine, and has the effect of providing ephemeral energy that causes the piston to continuously push and pull due to the inflation of air pressure due to thermal energy such as gas, heat, It can have the same function as the engine and can also be used for generator applications.

1 is a cross-sectional view of the present invention.
2 is another embodiment of the present invention.
Figure 3 is another embodiment of the present invention.
Figure 4 is another embodiment of the present invention.
Figure 5 is another embodiment of the present invention.
Figure 6 is another embodiment of the present invention.
Figure 7 is another embodiment of the present invention.
Figure 8 is another embodiment of the present invention.

1 is a cross-sectional view of the present invention in which a first connecting rod of a piston and a piston is formed inside a cylinder chamber, The end of the first connecting rod is linked to the second connecting rod and the other end of the second connecting rod is linked to the crankshaft, and the closed cylinder Both ends of the inside of the seal are formed with a hole through which air can be taken out and a valve that can open and close the hole. The valve is closed by a solenoid valve or the like, and the cylinder is heated by the gas fire to make the piston reciprocate FIG. 2 is a cross-sectional view of a heat exchanger according to another embodiment of the present invention, The heat sink in the piston is formed by the gas ignition device, the gas nozzle, the heat sink, and the first connecting rod as gas pipes, and the flexible gas pipe is connected to the gas tank and the first A control means for connecting between the connecting rods, a locking means for locking the gas pipe and an open state of the gas pipe to the control unit, a control unit for outputting an ignition signal of the gas and a signal for opening and closing the gas pipe in the control unit, And the ignition means for igniting the gas. While one of the valves of the ports formed at both ends of the cylinder is closed, the plate formed on both sides of the heat line formed on the piston is closed to the side where the valve is closed Open one of the valves and close it to the open side. When a solenoid valve is formed in the piston, a valve is formed at both ends of the solenoid valve. When the solenoid valve is formed at both sides of the piston, So that the valve formed on both sides of the hot wire formed on the piston is closed to the side where the valve is opened and opened by the switch and the relay so that the valve is opened when the valve is closed. Or the valve of the port formed at both ends of the cylinder is opened and closed by an electric signal, and the control unit closes the valve of the piston when the valve of the cylinder is opened and outputs the electric signal so that it opens when the valve of the cylinder is closed. As an operating means And

FIG. 3 shows another embodiment of the present invention in which a heat generating device such as a hot wire or a gas fire is formed and air heated by the heat generating device blows hot air by a nozzle along a pipe, The turbine is turned into a cylindrical space, and an exhaust pipe is formed in the upper part of the air hole.

FIG. 4 shows another embodiment of the present invention. As shown in FIG. 4, one longitudinally divided partition wall is formed in a space such as a closed cubic body, and a large hole is formed at the center of one surface of a cubic body facing the partition wall. The hole is a valve such as a solenoid valve, and when one side is opened, the other side is closed and the other side is opened. On the other hand, one side is closed, and the wall surface without large hole on the opposite side of the bulkhead forms one or more small vent holes. A heating part in which a gas fire or a heating wire for heating the inside of the hexahedron is formed in the outside, and a control part in which one side of the valve is closed when the other is closed and the other is closed,

Fig. 5 shows another embodiment of the present invention in which a valve such as a solenoid valve in Fig. 4 shows a structure in which one side is closed when the other side is opened and the other side is opened when the other side is opened

6 is a perspective view showing another embodiment of the present invention. As shown in FIG. 6, one longitudinally divided partition wall is formed inside a space of a closed body such as a closed cubic body and a large hole is formed at the center of one surface of a cubic body facing the partition, The two holes are solenoid valves and so on. When one side is opened, the other side is closed and the other side is opened, the other side is closed, and a part or all of the material such as hexahedron is heated by the greenhouse effect. The inside and the outside of the space between the partition wall where the large hole is formed in the hexahedron and the large hole such as the hexahedron facing the partition wall are shaded and cold air And the remaining part is formed with a solar heating part formed of a transparent material such as glass or the like, The cylinder chamber is formed on one side of the cylinder chamber and the cylinder chamber is closed, both sides of the cylinder chamber are closed, the piston is formed in the center, the piston reciprocates by the connecting rod and the air on the left or right side of the cylinder chamber communicates The connecting rod reciprocates through a hole that is sealed so that each valve is formed at both ends of the inside of the heating part inside the body such as a hexahedron and when the piston of the cylinder reciprocates and the outside of the body such as a hexahedron, Each valve is formed at both ends when the piston of the cylinder reciprocates to the outside of the cylinder, and when the valve is opened and closed at both ends of the piston of the cylinder and the inside of the heating unit, When the piston of the cylinder reciprocates from the outside of the body to the outside of the cylinder chamber, Probe is closed and to the right from the upper left open or at both ends at the time of the heating portion inside the cylinder piston to a reciprocating motion that opens close and the right side respectively, the valve is from the left side of the cylinder piston to the outside of the body outside and a cylinder chamber of the cube, etc. A switch for opening and closing each valve at both ends of the reciprocating motion from left to right and for outputting an electric signal in conjunction with an operation of a switch for lighting each valve at one side of the outside of the hexahedron; Control means for outputting time as an electric signal from a counter for counting time, receiving the electric signal as an electric signal from the control unit, and outputting a signal for operating the valve in the above-mentioned order in a predetermined time unit, And controlling means for controlling the opening and closing of the valve by operating in accordance with a signal output from the means.

7 shows another embodiment of the present invention. As shown in FIG. 6, a part or all of a body such as a hexahedron is formed of a transparent material such as glass to be heated by a greenhouse effect, When the addition is formed, the inside and the outside of the partition between the partition where the large hole in the hexahedron is formed and the wall where the large hole such as the hexahedron facing the partition is formed are formed in the shade and the heat insulation is formed so that the cold air is formed, Instead of forming a heated part by solar heat formed of a transparent material such as glass, a heating part is formed to be heated by a general gas or an electric device, and a body such as a hexahedron heated by the heating part is formed And

8 shows another embodiment of the present invention

In FIG. 7, one vertical partition is formed in the space of the body such as one closed hexahedron, and a large hole is formed at the center of one surface of the hexahedron facing the partition, and each of the two holes is formed by a solenoid valve When one side is opened by the valve, the other side is closed and the other side is opened . When one side is closed , Peltier element is formed on the partition wall to form a switch, so that the body to be heated in the cylinder is heated, The part where the air is introduced is endothermic.

1: Closed cylinder 2: Piston
3: hole 5: valve
10: fire 11: electromagnetic coil
15: movable iron core 20: insulation
21: flexible gas pipe 25: gas cylinder
30: crankshaft 31: link joint
32: second connecting rod 33: first connecting rod
35: blade 50: piping
51: Nozzle 52: Turbine
53: Gas pipe 55: Exhaust hole
70: wheel 77: heat sink
100: body 101: thermoelectric element

Claims (21)

The first connecting rod of the piston and the piston is formed inside the one cylinder chamber and the first connecting rod has the cylinder seal portion which reciprocates through the hole of the one side wall of the cylinder chamber, Both ends of the inner cylinder chamber are formed with a hole through which air can be taken in and out, and a heating section which heats the cylinder of the valve part of the hole in which the valve capable of opening and closing the hole is heated by heat or gas, A part or all of the material of the cylinder chamber is made of a transparent material such as glass or the like so that the inside of the cylinder chamber is heated so that the material is heated by the greenhouse effect and the valve is divided into two by a piston, The cylinder chamber on the side where the air is heated is closed and the cylinder chamber where the air on the opposite side is opened is opened A heat engine, characterized in that the piston which makes reciprocating movement due to be fulfilled to the control unit of the valve opening and closing. 2. The heat engine of claim 1, wherein the end of the first connecting rod is linked to the second connecting rod and the other end of the second connecting rod is linked to the crank shaft. A valve according to any one of claims 1 to 3, wherein a valve capable of opening and closing a hole capable of allowing air to flow in and out at both ends of the closed cylinder chamber is formed, and a solenoid valve is formed, The cam of the camshaft is rotated by a timing chain or a timing belt on a gear or a belt pulley directly connected to the shaft, the push rod is reciprocated by the cam, and the rocker arm is rotatably fixed by the push rod to the rocker arm shaft So that the valve can be opened and closed by being pressed to the port of the cylinder by the spring. The method as claimed in any one of claims 1 to 3, wherein, in the method of applying heat to the cylinder chamber, a heat line heated by electricity is formed in the piston, a blocking plate is formed on the left or right or upper and lower sides of the heat line formed in the piston, Wherein the shutoff plate formed in the shutoff valve is alternately opened in the cylinder chamber on the side where the air in the cylinder chamber divided by the piston is heated and the cylinder chamber on the opposite side is closed so that the piston reciprocates. The method as claimed in any one of claims 1 to 4, wherein, in the method of applying heat to the cylinder chamber, when a heat radiating plate is formed on the piston and a blocking plate is formed on the left or right or upper and lower sides of the heat radiating plate formed on the piston, And the gas nozzle, the heat sink, and the first connecting rod are formed as a gas pipe, a flexible gas pipe connects between the gas pipe and the first connecting rod, the locked state of the gas pipe and the open state of the gas pipe are input to the control unit, A control means for outputting a signal for opening and closing the gas pipe, and an ignition means for igniting the gas and operating means such as a servomotor operating according to a signal outputted from the control means for opening and closing the gas pipe. The apparatus as claimed in any one of claims 1 to 5, wherein one of the valves of the ports formed at both ends of the cylinder is closed while the plate formed on both sides of the hot line formed in the piston is opened to the side where the valve is closed, And a solenoid valve is provided at both ends of the solenoid valve when the solenoid valve is formed in the piston. When the solenoid valve is formed at both sides of the piston, Each valve is formed at the end of the valve. While the valve of the port formed at both ends of the cylinder is open, the plate formed on both sides of the hot wire formed on the piston is closed to the side where the valve is opened, And relay or the like, The valve of the port formed at both ends of the cylinder is opened and closed by an electric signal to the control unit, the control unit closes the valve of the piston when the valve of the cylinder is opened and outputs an electric signal to open the valve, . The valve according to claim 3, wherein when the solenoid valve is formed and the solenoid valve is opened and closed by a solenoid valve when a hole capable of allowing air to flow in and out at both ends of the cylinder chamber closed and a valve capable of opening and closing the hole are formed, Wherein a rotation angle of the shaft is sensed by a sensor and input to a control unit, and a control unit outputs an opening / closing timing of each of the valves at both ends to operate the solenoid valve to open / close the solenoid valve. A part or all of a material such as a hexahedron or the like is formed of a transparent material such as glass to heat the inside of the hexahedron or the like so as to be heated by a heating wire or a gas fire or by a greenhouse effect, Wherein the hot air is blown by the nozzle along the pipe to rotate a turbo type turbine in which a plurality of blades or blades are planted and rotated at a high speed around the circumference of the rotor. The turbo type turbine in which the heated air blows hot air by the nozzle along the tube to plant a plurality of blades or wings on the circumference of the rotating body and rotates at a high speed is closed to the cylindrical space, Wherein only air holes are formed or exhaust pipes are formed in the air holes. A single hole is vertically formed in a space such as one closed hexahedron, and a large hole is formed at the center of one surface such as a hexahedron facing the bulkhead, and each hole is formed by a valve such as a solenoid valve One side is closed when the other side is opened and one side is closed when the other side is opened. At least one small ventilation hole is formed in the wall surface without the large hole at the opposite side of the bulkhead. A heating part in which a heating part in which a heat ray is formed is formed or a part or all of a material such as a hexahedron is formed of a transparent material such as glass so as to be heated by a greenhouse effect, One side of the valve is closed and the other side is closed, thereby forming a control unit for closing one side of the valve A heat engine, characterized by. [10] The method of claim 10, wherein, when a heating part is formed in which a part or all of a material such as a hexahedron or the like is made of a transparent material such as glass so that the inside of the hexahedron is heated, And the other part is formed of a transparent material such as glass or the like. The heat pipe is made of a transparent material such as glass or the like, and the inside and the outside of the inside and the outside of the space between the partition wall and the large- . The inner and outer portions between the partition walls where large holes are formed in the hexahedron and the wall surfaces where the large holes such as the hexahedron facing the partition walls are formed are shaded Wherein a heat insulating material is formed so that cold air is formed and the remaining part is formed of a material which is easily heated and a heating part is formed inside or outside. The heat engine according to claim 10, wherein an exhaust pipe is formed in a small exhaust hole formed in a wall surface without a large hole. A large hole is formed at the center of one surface of a hexahedron facing the partition wall, and one of the holes is formed by a valve such as a solenoid valve or the like When one side is opened, the other side is closed and the other side is opened, and one side is closed. In order to be heated by the greenhouse effect, a part or all of a material such as a hexahedron is formed of a transparent material such as glass, When the addition is formed, the inside and the outside of the partition between the partition where the large hole in the hexahedron is formed and the wall where the large hole such as the hexahedron facing the partition is formed are formed in the shade and the heat insulation is formed so that the cold air is formed, A solar heating part formed of a transparent material such as glass is formed, and a cylinder chamber is formed on one side of the inside of the heating part And the cylinder chamber is cylindrical, the both ends of the cylinder are closed, the piston is formed in the center, the piston is reciprocated by the connecting rod, and the connecting rod is inserted through the hole sealed on the left or right side of the cylinder chamber, And the piston of the cylinder is reciprocated and valves are formed at both ends when the piston of the cylinder reciprocates, and the piston of the cylinder to the outside of the cylinder chamber outside the body of the hexahedron or the like reciprocates The valves are formed at both ends of the cylinder, and when the valves are opened and closed at both ends of the piston in the heating section and at the both ends when the piston reciprocates, the cylinder is opened to the outside of the cylinder chamber, the piston is at both ends at the time of the reciprocal movement of each respective valve is closed and the column from left to right Both the time to, or close and to the right at each end at the time of the heating element inside the piston is reciprocating in the cylinder respectively, the valve is from left open to the cylinder piston reciprocating motion to the outside of the body outside and a cylinder chamber of the cube, etc. Each of the valves being opened and closed from the left to the right, and a switch for outputting an electric signal in cooperation with the operation of the switch for lighting each valve on one side of the outside of the hexahedron; Control means for outputting time as an electric signal from a counter for counting time, receiving the electric signal as an electric signal from the control unit, and outputting a signal for operating the valve in the above-mentioned order in a predetermined time unit, And means for controlling the opening and closing of the valve by operating according to a signal outputted from the means. A large hole is formed at the center of one surface of a hexahedron facing the partition wall, and one of the holes is formed by a valve such as a solenoid valve or the like When the other side is opened and the other side is opened, one side is closed , and when the heating part in which the gas fire or the heat ray is formed is formed, the partition wall in which the large hole in the hexahedron is formed and the hexahedron The inside and the outside between the wall where the holes are formed and the outside are formed with a heat insulating material so that cold air is formed and the remaining part is formed of a material which can be heated well and a heating part is formed inside or outside, When the cylinder chamber is formed and the cylinder chamber is cylindrical or the like, both the right and left end faces are closed, the piston is formed in the center, The connecting rod reciprocates through a hole which is sealed so that the air does not pass through the left or right side of the cylinder chamber. When the piston of the cylinder reciprocates inside the heating portion inside the body such as a hexahedron And each valve is formed at both ends of the piston when the piston of the cylinder reciprocates to the outside of the cylinder chamber and the piston of the cylinder reciprocates When each valve is opened and closed from the left to right on both ends of the cylinder, the valves are closed from left to right at both ends when the piston of the cylinder reciprocates to the outside of the cylinder chamber and the outside of the cylinder chamber, each respective valve at both ends when the piston reciprocates inside the cylinder and to the right from the left Higo open, closed, open to the right from both sides at the end of each respective valve is left at the time of the body outside and a cylinder piston reciprocating motion to the outside of the cylinder chamber of the cube, etc., and of the cube outside one side of the switch to be turned to each of the valve A switch for outputting an electric signal in conjunction with the operation of the switch;
Control means for outputting time as an electric signal from a counter for counting time, receiving the electric signal as an electric signal from the control unit, and outputting a signal for operating the valve in the above-mentioned order in a predetermined time unit, And means for controlling the opening and closing of the valve by operating according to a signal outputted from the means. The method according to any one of claims 10 to 15, characterized in that a large hole is formed in the center of one surface of a body such as a closed hexahedral body and a hexahedron facing the partition wall , two holes are opened, the side of one of the valve such as a solenoid valve, the other is closed and the other side is open, the body is one side to form the switch to form the Peltier elements on the partition wall is heated during the passage time can be a closed structure of each And a portion where air flows from the outside of the body to the inside of the body is heat absorbed. 17. The method of manufacturing a semiconductor device according to any one of claims 10 to 16, wherein a large hole is formed at a center of one surface of the one hexagonal body facing the bulkhead, The two holes are solenoid valves and so on. When one side is opened, the other side is closed. When the other side is opened, one side is closed. When there is one solenoid valve, a large valve is formed on both ends of the solenoid valve. A switch for generating a large valve at each end of the solenoid valve and outputting an electric signal in conjunction with the operation of the switch for lighting the solenoid valve when the diaphragm is formed on one side of the partition wall and the hexahedron facing the partition;
When the solenoid valve of the control unit opens one side of the hexahedron facing the partition and the other side of the partition, the time is outputted as an electric signal from the counter for calculating the time, And a valve adjusting means such as a solenoid valve for outputting an electric signal so that one side is closed when the other side is closed and the other side is closed and operating according to a signal outputted from the control portion to close the valve. 18. A heat exchanger according to any one of claims 1 to 17, wherein the valve is formed by a valve of a heat insulator. The heat engine according to any one of claims 10 to 18, characterized in that a wheel is formed on a lower side surface of a hexahedron or the like. The method of claim 8, 9, or 19, wherein hot air is blown by the nozzle along the tube to rotate a turbo-type turbine to plant multiple blades or blades in the circumference of the rotating body and rotate at a high speed Characterized in that the tube connected to the nozzle is connected to the small exhaust hole by a wall surface without any large hole at the opposite side of the partition wall of any one of claims 10 to 13 and any one of claims 17 to 19. [ . 20. The power source for driving a valve according to any one of claims 1 to 20, wherein the power source for driving the valve is a direct current power source using a household AC power source or a direct current power source using an AC / DC inverter, Wherein the secondary battery is formed when current or direct current is used so that electricity can be supplied by the secondary battery even when the solar battery does not generate electricity.

Images