TWM399913U - Fly-wheel thermal combustion system - Google Patents

Description

V. New description: [New technical field] A flywheel thermal combustion system is available for generating electric energy. This creation refers to a flywheel thermal combustion system that converts thermal energy into mechanical energy and recycles it to generate electrical energy. [Prior Art] Since the industrial revolution, various types of thermal combustion engines have respectively promoted the industrial revolution of human beings at different stages, in which the technology of using steam engines to drive generators to generate electric crescents, σ used to date, and diesel-driven internal combustion engines Leading the current global power output sector, the demand for fossil fuels is increasing. However, burning petrochemical energy also produces solid and gaseous pollutants such as nitrogen oxides, sulfur oxides and carbon dioxide, and the petrochemical energy system is a kind. Linear energy 'can not be manufactured by itself, can not be recycled when used, so there are many shortcomings in petrochemical energy. In addition, when petrochemical energy is implemented, after various types of energy conversion, petrochemical energy will be exhausted to petrochemical Energy-driven vehicles, for example, petrochemical energy flows through the power plant's intake, I, explosion, and discharge. The chemical moons generated by the households are partially discharged in the form of heat. However, excessive heat also causes the power plant to operate. A malfunction occurs, so it is necessary to use a uniform cold set to cool the power unit before continuing. Actuation, and only part of the energy of the converted stem can actually be applied to the power unit, and the efficiency of the energy is more affected by the friction of the 3 M399913 generated by the weight and displacement at that time. The real conversion of fossil fuels into mechanical energy is reduced. Therefore, it is necessary to continuously supplement fossil fuels for the continuous operation of power plants, and the use of fossil fuels to produce associated pollution, so that scientists all over the world are striving to find zero-emission fuels instead. Petrochemical fuel, which is the most attractive of hydrogen fuel, argon is 100% recycled fuel: it is decomposed by water resources, hydrogen production by heavy water electrolysis, solar tower hydrogen collection and hydrogen production, etc. Hydrogen and oxygen, which can be used when the internal combustion engine is actuated, or drive the hydrogen fuel cell to generate electricity, and the wind fuel can be easily obtained, and the nitrogen fuel can be recycled repeatedly through the electrolytic reduction technology. By decomposing the measured electric power, it is possible to delete the oxyhydrogenated money, so how to make the gas fuel effective. With department is a significant learning. _ The above-mentioned problems are all applied at the fuel level. However, the existing thermal combustion engine structure can not improve the efficiency of energy conversion. Among them, the existing thermal combustion engines are mainly divided into two types: internal combustion engine and external combustion engine, and according to the mechanism. The difference is further divided into radial (vertical) or axial (horizontal), and radial, the cylinder piston is perpendicular to the axis of the shaft, and the axial direction refers to the gas piston is parallel to the (four) axis However, the above two structures can only perform one-way operation during the operation of one X cycle, thereby making the efficiency of energy conversion low. Moreover, the conventional gasoline heat engine is mainly divided into two strokes (Two Storke) and four. Stroke (F〇ur st〇rke), in which the two-stroke gasoline internal combustion engine uses a radial piston to perform up-and-down displacement-times, using the crank-and-ample to complete the four actuation processes of intake, compression, expansion and exhaust, 4 M399913 wide-range gasoline internal combustion engine uses the radial piston to generate two crankshafts up and down to complete the intake, _, expansion and exhaust four steps to complete the conversion of gasoline chemical energy conversion mechanical energy, X 'the above gasoline internal combustion The radial piston of the machine belongs to the open gas circulation exchange, which is operated: exchange with natural air, which leads to the conversion of mechanical energy efficiency: low, and the converted gasoline is partially discharged as exhaust gas. Pollution and greenhouse gas production, and whether using diesel or gasoline transmission: the internal combustion engine's need to be mixed with natural air, 'Xiao, cold air suction and fossil fuel mix, and second internal combustion, explosion, discharge, etc. Conversion, and finally discharged in ..., waste milk type, so the effect on energy conversion ==:: mechanical energy, the rest _ exhaust gas - I == and friction loss and loss; in addition, the traditional external combustion knife is open or Closed working fluid duty ring, squatting, door-mounted type:: single-cylinder single-piston for air (four) for dual use "two * wrong by gas circulation with natural air, colder cold air, but It also leads to the relative efficiency of the action [new content] In view of the above problems, the creator is based on the experience of multi-product design, and conducts relevant analysis and research on the hydrogen fuel cycle 4 production structure: and the composition of the thermal combustion engine Solving the problem that traditional petrochemical 5 M399913 energy can not be reused and conversion effect (4), and the structural limitation of only one-way operation when the traditional heat engine is activated, the main purpose of this creation is to provide (4) heat source startup, and It is equipped with an ammonia energy source to achieve cycle power generation. In order to achieve the above objectives, the creator uses "heat" as the main driving source, Constructed by an actuating device, a radial actuating device and a flywheel electromagnetic induction device, the heat actuating device drives the axial actuating device to generate an actuating motion and the radial actuating device generates a circular motion, and the flywheel electromagnetic induction device is radially Actuation of the actuating device generates electric power, which can be stored by the capacitor battery for use in the operation of the flywheel thermal combustion system. Further, the creation system can be further combined with a hydrogen regenerative electrolysis battery device, which is set by the radial actuating device. The set-piston linkage and more than one radial piston' extracts a water resource while the radial actuator is used as a raft The K electrolysis A generates 'produces hydrogen oxygen, and the hydrogen and oxygen generated can be further synthesized and burned for use in the operation of the axial actuating device, or it can be actuated with the hydrogen fuel cell device to generate Electricity, in order to supply the electricity required for the decomposition of water resources, in order to achieve the goal of no-green/green-powered cycle power generation. The above description of the contents of this creation and the description of the following embodiments demonstrate and explain the spirit of the creation and the original 35, and further explain the scope of the patent of this creation. 6 M399913 [Embodiment] See "Figure 1" for clarity. In the figure, T is the business chart of the creation. As shown in the figure, the author, the so-called flywheel thermal combustion system, has an axial direction. Actuating device] 01, a radial actuating device is composed of β ^ ψ i〇q " 102 and - flywheel electromagnetic induction device 103, the dragon, 6., /, the axial actuating device 101 through the heart and The piston bearing column 1〇U is connected to the radial actuating device 1〇2, and the flywheel electromagnetic induction device 103 is connected to the radial actuating device 10”. Please refer to “Fig. 2”, which is shown in the figure. The components of this creation are not intended to be (1). As shown in the figure, 'the axial acting device 1〇1 referred to in this creation is mainly a closed-type circulatory fluid circulation using a single-gas rainbow single-piston. The open working fluid circulation is different, and it is not necessary to use the double piston to generate the action 'and mainly utilizes the heat source to generate the start, wherein the Γ axial actuating device 101 is formed with a hot chamber 1 〇 12 and a cold chamber 1 〇丨 3, two chambers. The chambers (1012, 1013) are in a connected shape, and the thermal chambers 1〇12 are slightly elongated, and the cold chambers are UH3 is slightly flat, and there is an axial piston 1014 between the two chambers (1〇l2, i〇i3). After the axial pistons 1〇14 are activated, they can be respectively in the two chambers (1012, 1013). Linear reciprocating, the axial piston 1〇14 is formed with a piston bearing column Ι0Π, which can be actuated by the interlocking radial actuating device 1〇2, and a linear Palin 1 〇15 is arranged on the piston bearing column 1 〇11, The outer end edge of the thermal chamber 1012 is formed with a heat cycle tube. The heat cycle tube 1016 is further assembled with a regenerator 1〇17, and one end of the regenerator 1017 is assembled with the uniform cooler 1〇18. The other end edge of the refrigerator 1018 is further connected to the cold chamber 丨〇13, and further, the 7 M399913 cold state 1018 # outer edge is step-by-step covered by the -forest cycle assembly i 1019, the cold water circulation device 1019 The hot air flowing through the refrigerator 1018 can be cooled by externally extracting water resources or filled with a uniform cold liquid, thereby generating and generating two air, and the cold air is further introduced into the cold chamber to form an axial acting device 1 The required source of cold contraction pressure when 〇1 is actuated. As shown in the figure, the radial actuating device 102' referred to above is coupled to the axial acting device 101 by the axial acting device 101, and the overall appearance is slightly a cylindrical shape and the outer edge is formed with a slightly wavy actuating guide rail 1G21' having a height difference; and the ends of the plug post i Q丨丨 are respectively formed with a first side

V

See "Figure 3" for the purpose of showing the component group of the original assembly to the pedestal 1022 and the second directional frame. The first directional frame 1 022 is provided with several linear Palin 1 〇24, and through a first actuating disc 1G25 and radial actuating device 1Q2, and the first actuating disc 5 is assembled in the actuating guide rail 1 〇 21, and the first direction cuff 〇 22 is subjected to the piston Driven by the column um, the operation of the "specific direction" is generated 々K flat direction 'X' The second direction of the yoke 1 () 23 is connected by the second operating disk 1 〇 26 and the radial actuator S (1), The two actuating discs 1026 are arranged in the actuating guide rails 1〇21, and the second-direction scaffolds are driven by the piston caps 1 〇1 1 to generate another-direction action such as a vertical direction, so that when the piston bearing When the column 1011 produces a linear displacement, the radial actuating device 1() 2 can be rotated to generate a circular motion; and please refer to the "4th circle", which is a schematic diagram of the composition of the created component (3), presented as 8 M399913 , 'i^ flywheel electromagnetic induction device 103 is arranged in combination with the radial actuating device 1 〇 2 When the circular motion is generated by the radial actuating device 102, the flywheel electromagnetic induction device 103 generates a magnetic line cut to generate electric energy, and the so-called flywheel electromagnetic induction device 103 is an externally-rotated electromagnetic induction power generating mechanism having a certain sub-1031 And a rotor 1032, wherein the 'rotor 1032 is assembled with the radial actuating device 1〇2, or formed on the radial actuating device 102, and the rotor (10) is formed with a radial magnet 1 033 and an axial magnet. 1034, each of the magnets (1 033, 1〇34) can be formed with a radial induction coil and an axial induction coil 1〇36, respectively, and a stator coil 1Q3i, and each induction coil (1〇35, 1〇36) corresponds to each of the magnets 0 033, 1034), and further, the rotor 1〇32 is further electrically connected to the electronic circuit unit (10) for the flywheel electromagnetic induction device 103 to operate, and the generated electric energy can be The electronic circuit unit transmits to other devices for operation, and in order to reduce the friction during rotation when the rotor 1032 is rotated, a rotation can be further set between the rotor 1〇32 and a fixed shaft•1037. A piece 1038, such as Palin, etc., and the electronic circuit unit 104 as described above may be a smart grid. Please refer to "Figure 5". The diagram shows the flow chart of the implementation of this creation. Please refer to Figure 2~4. The implementation process of the flywheel thermal combustion system 10 referred to in this creation is as follows: (1) Startup 21·· This creation relies on an external thermal energy, such as the sun, heat or combustion heat, to cause the axial actuator 1 产生1 to actuate. First, the heat source is brought close to the thermal chamber of the axial actuator j 〇j 9 The outer periphery of 1012 causes the thermal chamber 1012 to gradually expand due to heat, and drives the heat of the hot chamber 丨〇丨2 to form a heat-pressing pressure, which in turn pushes the axial piston 1014 to the direction of thermal expansion, and the heat The air system is further introduced into the refrigerator 1018 by the heat cycle tube 1016, through the regenerator 1〇17, and when the hot air is cooled by the cold water circulation device 1019, it is converted into a cold air, which is further introduced into the cold chamber. In the chamber 1013, to form a contraction pressure 1 the cold air further fills the ends of the cold chamber 1013 and the axial piston bore 14, and the cold air pushes the axial piston 1014 toward the heat chamber 1012, thus In thermal expansion and cold Under the pushing of the two forces, the axial piston 1014 is linearly reciprocated; the electric ft 22 is generated. According to the above, the axial acting device generates a linear reciprocating motion, and the piston bearing column 1011 further drives the first step. - The directional pedestal 1022 and the second directional pedestal 1 〇 23 actuate to cause the radial actuating device 102 to produce a 360 degree circular motion 'this time' the rotor 1032 of the flywheel electromagnetic induction device 103, due to the radial actuating device 1 〇 2 The action, which in turn produces a rotation 'such a rotor 1 032 rotation produces a magnetic line of cutting' stator 1 〇 3 各 on each of the induction coils (1035, 1036) respectively generate an electric energy; electric crescent conversion and storage # 23: the generation of electrical energy According to the step M399913, the electric energy generated by the flywheel electromagnetic induction device 103 is further processed through the electronic circuit unit 1〇4, and the generated electric energy is processed and the converted electric energy can be further stored in a capacitor battery. The electrical energy system can be used as an energy source for the flywheel thermal combustion system 10 to start again. The above-mentioned 'energy generated by the above components can be used in addition to the continuous operation of the flywheel thermal combustion system. It can be further used with a hydrogen regenerative electrolytic cell device. Please refer to Figure 6 It is not a schematic diagram of another embodiment of the present invention, and please refer to "FIG. 7", which is a schematic diagram of the components of another embodiment of the present creation, as shown in the figure, hydrogen regeneration The electrolysis battery device 丨〇5 is electrically connected to the rear end of the electronic circuit unit 〇4 to obtain the converted electric energy of the electronic circuit unit 104, wherein the hydrogen regenerative electrolysis battery device is composed of a water electrolysis device 1051 and A hydrogen fuel cell device 1〇52, and the water electrolysis device 1051 and the hydrogen fuel cell device 1 1Q52 are respectively connected through a pipeline to generate the relevant energy required for the operation, or to transfer the generated hydrogen to other devices. In order to generate the actuation, the radial actuating device 1〇2 is further provided with a piston interlocking seat 1〇27, which has a continuous concave-convex shape as a whole, and is formed with one or more convex portions 1〇28 and concave portions 1〇29, And the piston coupling seat 1027 is connected with more than one radial piston m. When the piston coupling seat 1027 is rotated by the radial actuating device 1〇2, the top end of the plug Q6 is continuously in the convex portion 1 (4) and Between the recesses 1029, the catastrophes are driven by the pistons of the piston 1 〇6 to linearly reciprocate 11 M399913. Thus, the radial pistons 106 can be used to extract water resources or hydrogen fuel generated by the water electrolysis device 1051. Compressed and stored in a high-pressure carbon fiber bottle 107, and the hydrogen fuel stored in the high-pressure carbon fiber bottle 107 is available for synthetic combustion, and the flywheel thermal combustion system is again driven to operate, or the gas-fueled fuel cell device 1052 generates electricity. The water electrolysis device 1051 referred to above can further utilize graphite as a carbon-based source. When the water electrolysis device 1051 is actuated, the generated gas is a separated gas, such as hydrogen, oxygen, etc., such as the gas produced by the water electrolysis device 1051. Multi-layer applications are available. Please refer to "Fig. 8". The figure is a flow chart of the implementation of another embodiment of the present invention, and please refer to "Fig. 6". According to the above, the implementation process of this embodiment is as follows: The water source is extracted 24. After the step 5 of storing the electric power in the "figure 5" step, when the radial actuating device 102 performs the circular motion, the radial piston 16 is simultaneously actuated, so that the radial piston 1 can be actuated. The operation of 06, extracting a water resource, such as seawater, etc.; (2) cooling and hydrogen decomposition 2 5: after the above-mentioned water resources are extracted, further supply to the water electrolysis device 1051 is required. The electric power generated by the flywheel thermal combustion system 10 converts the generated alternating current power into direct current power through the electronic circuit unit 1〇4, and operates to generate a flammable hydrogen-oxygen separation gas, and the above step 12 M399913 extracts The water resource, in addition to the water electrolysis device 〖051, can be introduced into the water-cooling circulation device 1019 of the axial actuating device 1〇1 for cooling the axial actuating device 1〇1, and when extracted Water When the source is seawater, the seawater can be treated by the __water reverse osmosis unit 08 (see Figure 8) before the water electrolysis unit 1G51;

(3) Storage of hydrogen fuel 26: After the water electrolysis device 1〇51 is actuated, the generated hydrogen and oxygen separation gas is further stored in the high pressure carbon fiber bottle 1〇7 by the action of the radial piston 106; (4) Synthesis Burning m, stored in a high-pressure carbon fiber bottle 1〇7, can be synthesized to produce a combustible gas to provide the thermal energy required for the flywheel thermal combustion system 10 to be cycled;

(5) generating electric power 27B: storing hydrogen fuel 26 steps, storing hydrogen and oxygen in the high-pressure carbon fiber bottle 107, and transmitting through the pipeline 'hydrogen fuel cell charging £1 052 when using the hydrogen fuel cell device 1G52 After a chemical effect with hydrogen and oxygen, the generated electrical energy can be used by the water electrolysis device 1051 to operate or can be stored by a battery capacitor. In the implementation of the above-mentioned embodiment, many of the steps of the process require the radial piston 106 to be actuated, and this is the case; the system is further assembled with a plurality of radial pistons 106, and each radial direction The operation of the piston 106 is not the same. 1 Refer to the "Fig. 7". In this embodiment, only the 8 radial pistons 1G6 are taken as an example. However, the user 13 M399913 may add or reduce the group according to the implementation. A radial piston 丨〇6 is provided, as shown in the figure, 'the radial piston 106 is mainly used for pumping water, and the radial piston 106A is connected to the radial piston 1 Ο 6B, and the radial piston! Between the 〇6a and the radial piston 106B, there is a water reverse osmosis device 丨〇8 for treating the water extracted by the radial piston 106A, and the water treated by the water reverse osmosis device 108 The resource is transmitted to the radial piston 1〇6D through the radial piston 丨〇6B and the radial piston 106C, and the water resource can be used in the axial movement by the action of the radial piston 1061) and the radial piston 1 〇6E. On the cooling of the device 101, in turn, the radial piston 1〇6F is mainly used to compress hydrogen and oxygen in the still-pressed carbon fiber 1 〇7, however, the radial piston 丨〇6f is activated by the piston coupling seat 1 027. The gas is stored via a diaphragm jj and a membrane chamber 11 2, and the embodiment thereof is as follows: (1) Pushing the diaphragm: When the radial piston 1〇6F is pushed by the piston linkage 1027, the displacement is the most At the bottom, the gas enters the membrane chamber 112 and displaces the diaphragm 111 to the bottom of the membrane chamber 112, at which time the membrane chamber 112 is filled with gas, and when the piston linkage 1027 continues to act, the radial piston 106F is at the bottom position. Displace to the top 'and compress the gas; (2) back In-situ. When the pressure of the compressed gas reaches a certain level, the compressed gas is discharged. At this time, the radial piston 丨〇6F continues to shift to the top. When the radial piston 106F is displaced to the top, the compression process of one duty cycle ends. The compression of the gas can be completed by continuously repeating the compression process. 14 Further, the radial piston 106G can be connected to the rear end of the radial piston 1〇6F, and between the radial piston 106G and the radial piston i 〇6H. There is a heat sink 12 such that the radial piston 丨〇6G and the radial piston 丨〇6H form a two-stage hydrogen compression cooling piston unit. According to the red, the flywheel thermal combustion system referred to in this creation is based on "thermal" as the main driving source, and is composed of an axial actuating device, a radial actuating device and a flywheel electromagnetic induction device. The heat source drives the axial actuating device to actuate, and the radial actuating device generates a circular motion, and the flywheel electromagnetic induction device generates electricity by the action of the radial actuating device. This power can be stored via a capacitor battery for the flywheel thermal combustion system. When used again, this (4) is a H-hydrogen regeneration battery device'; by the piston acting on the piston to set up the piston linkage seat and (4) or more; the piston is actuated by the radial actuating device At the same time, the extraction-water resources 'produces hydrogen and oxygen by the water electrolysis device, and the generated argon oxygen It system can be synthesized and burned for use in the axial actuating operation. Acting with the hydrogen regenerative electrolysis cell device to generate electricity to supply the electricity required for the decomposition of water resources. According to this, after the implementation of this creation, it is indeed possible to provide it. # Ring can generate electricity, in order to improve the thermal efficiency of gas turbines, and resolve pass. · 'Flywheel system to heat combustion of fossil fuels can not be used once again drawbacks. It is to be understood that the preferred embodiment of the present invention is not intended to limit the scope of the present invention; any person skilled in the art can make equal changes without departing from the spirit and scope of the present invention. M399913 modifications are to be covered by the scope of this creation. In summary, the effectiveness of this creation is based on new types of “industry availability,” “novelty,” and “progressiveness”; the applicant filed a new patent with the hook in accordance with the provisions of the Patent Law. Application. 16 M399913 f simple description of the diagram] The first diagram is a schematic diagram of the components of the creation. Figure 2 is a schematic diagram of the composition of the creation of the creation (-). Figure 3 is a schematic diagram of the components of this creation (2). The fourth circle is a schematic diagram of the composition of the creation of the creation (3). Figure 5 is a flow chart of the implementation of this creation.

Figure 6 is a schematic diagram showing the composition of another embodiment of the present invention. The seventh circle is a schematic view of the components of another embodiment of the creation. The cargo diagram is a flowchart of the implementation of another embodiment of the creation. [Main component symbol description] 10 Flywheel thermal combustion system 101 Axial actuator 1011 Piston column 1012 Thermal chamber 1013 Cold chamber 1014 Axial piston 1015 Linear Palin 1016 Thermal loop 1017 Regenerator 1018 Refrigerator 1019 Cold water circulation device 103 Flywheel electromagnetic induction device 102 Radial actuation device 1021 Actuation guide rail 1022 First direction creel 1023 First direction creel 1024 Linear Palin 1025 First actuation plate 1026 First actuation plate 1027 Piston linkage 1028 Projection 1029 recess 104 electronic circuit unit 17 M399913

1031 Stator 1032 Rotor 1033 Radial magnet 1034 Axial magnet 1035 Radial induction coil 1036 Axial induction coil 1037 Fixed shaft 1038 Rotating member 105 Hydrogen regenerative electrolytic cell device 1051 Water electrolysis device 1052 Hydrogen fuel cell device 106 Radial piston 106A-H Radial piston 108 Water reverse osmosis unit 111 Diaphragm 112 Membrane chamber 12 Heat sink 21 Start 22 Generate electric energy 23 Power conversion and storage 24 Water extraction 25 Cooling and hydrogen decomposition High pressure carbon fiber bottle 18 M399913 26 Storage hydrogen fuel 27A Synthetic combustion 27B Generate electricity

Claims (1)

M399913 - VI. Patent application scope: ^ 1 · A flywheel thermal combustion system, comprising: an axial actuating device, forming a cold chamber and a heat chamber, the two chambers being in a (four) pass shape... an axial piston borrowing a piston assembly is disposed between the cold and hot chambers; a radial device having a "帛-direction_frame" and a second direction frame, and the first direction frame and the second The directional material frame is assembled with an actuating guide rail, and the radial actuating device is connected to the piston bearing column of the axial actuating device; and a flywheel electromagnetic induction device has a stator and a rotor, and the rotor In combination with the radial actuating device, the stator has a radial induction coil and an axial induction coil, and the rotor has a radial magnet and an axial magnet. 2. The flywheel thermal combustion system of claim 1, wherein the axial end of the thermal actuator is formed with a heat cycle tube. The flywheel thermal combustion system of claim 2, wherein the heat cycle tube set is provided with a regenerator. 4. The flywheel thermal combustion system of claim 3, wherein one end face of the regenerator is provided with a refrigerator, and the refrigerator is in communication with the cold chamber. 5. The flywheel thermal combustion system of claim 4, wherein the refrigerator is covered by a cold water circulation device. 6. The flywheel thermal combustion system of claim 1, wherein the 20-piston column assembly is provided with a linear Palin. The flywheel thermal combustion system of claim 1, wherein the actuating guide rail has a wave shape and has a height difference. 10. The flywheel thermal combustion system described in item 1 of the patent application is continued to be connected to the actuating guide rail through a first actuating disc as claimed in the patent application scope. The flywheel thermal combustion system according to Item 1, wherein the brother-direction yoke is provided with one or more linear linings. The flywheel thermal combustion system according to claim 1, wherein the second direction yoke is connected to the actuating guide rail through a second urging disc. The flywheel thermal combustion system of claim 1, wherein the meridional actuator has a piston linkage seat. The piston linkage is assembled with more than one radial piston. 12. The flywheel thermal combustion system of claim 11, wherein the piston linkage has a projection and a recess. 13. The flywheel thermal combustion system of claim n, wherein the radial piston set is provided with a hydrogen regenerative electrolytic cell device. 14. The flywheel thermal combustion system of claim 13, wherein the hydrogen regenerative electrolysis cell device has a water electrolysis device and a hydrogen fuel cell device. 15. The flywheel thermal combustion system of claim 11, wherein the radial piston set is provided with a high pressure carbon fiber bottle. The flywheel thermal combustion system of claim 11, wherein the radial piston set is provided with a heat sink. The flywheel thermal combustion system of claim 1, wherein the rotor of the flywheel electromagnetic induction device is integrally formed on the radial actuator. 18. The flywheel thermal combustion system of claim 1, wherein the light moving magnet is a permanent magnet. 19. The flywheel thermal combustion system of claim 1, wherein the axial magnet is a permanent magnet. The flywheel thermal combustion system of claim 1, wherein the flywheel electromagnetic induction device has a rotating member. 21. The flywheel thermal combustion system of claim 2, wherein the rotating member is a Palin. 22. The flywheel thermal combustion system of claim 1, wherein the flywheel thermal combustion system is electrically connected to an electronic circuit unit. 23. The flywheel thermal combustion system of claim 22, wherein the electronic circuit unit is a smart grid. twenty two