CN106065852A - A kind of electromotor - Google Patents

Abstract

The invention discloses a kind of electromotor, including gas ionization unit, charged gas electromagnetism accelerator module, combustor and charged gas generator unit, the gas outlet of described gas ionization unit connects with the gas access of described charged gas electromagnetism accelerator module, and the gas outlet of described charged gas electromagnetism accelerator module connects through the gas access of described combustor with described charged gas generator unit.Electromotor of the present invention not only has efficiency height, pollutes little feature, and it is few to have moving component, the advantage of simple in construction.

Description

A kind of electromotor

Technical field

The present invention relates to heat energy and dynamic field, particularly relate to a kind of electromotor.

Background technology

In traditional electromotor, either gasoline engine, diesel engine, jet engine or gas turbine not only have dirt The problems such as dye discharge is serious, efficiency is low, but also there is the shortcoming that moving component is many.Start it is thus desirable to invention one is novel Machine.

Summary of the invention

In order to solve the problems referred to above, the technical scheme that the present invention proposes is as follows:

Scheme 1: a kind of electromotor, electric including gas ionization unit, charged gas electromagnetism accelerator module, combustor and band Body generator unit, the gas outlet of described gas ionization unit connects with the gas access of described charged gas electromagnetism accelerator module Logical, the gas outlet of described charged gas electromagnetism accelerator module is through the gas of described combustor Yu described charged gas generator unit Entrance connects.

Scheme 2: on the basis of scheme 1, makes the gas outlet of described charged gas generator unit with jet pipe even further Logical.

Scheme 3: on the basis of scheme 1 or scheme 2, makes described charged gas generator unit to described gas electricity further From unit and/or described charged gas electromagnetism accelerator module feed electric power.

Scheme 4: on the basis of scheme 1, makes described charged gas generator unit to described gas ionization unit further And/or described charged gas electromagnetism accelerator module feed electric power, described charged gas generator unit external feed electric power.

Scheme 5: a kind of electromotor, electric including gas ionization unit, charged gas electromagnetism accelerator module, heating chamber and band Body generator unit, the gas outlet of described gas ionization unit connects with the gas access of described charged gas electromagnetism accelerator module Logical, the gas outlet of described charged gas electromagnetism accelerator module is through the gas of described heating chamber Yu described charged gas generator unit Entrance connects.

Scheme 6: on the basis of scheme 5, makes the gas outlet of described charged gas generator unit with jet pipe even further Logical.

Scheme 7: on the basis of scheme 5 or 6, makes described charged gas generator unit to described gas ionization list further First and/or described charged gas electromagnetism accelerator module feed electric power.

Scheme 8: on the basis of scheme 5, makes described charged gas generator unit to described gas ionization unit further And/or described charged gas electromagnetism accelerator module feed electric power, described charged gas generator unit external feed electric power.

Scheme 9: a kind of electromotor, including solid particle accelerator, gas ejector, gas-solid separator and combustor, institute State solid particle accelerator, described gas ejector, described gas-solid separator and described combustor to be sequentially communicated.

Scheme 10: on the basis of scheme 9, makes the solid particle outlet of described gas-solid separator and described solid further The solid particle inlet connection of particle accelerator.

Scheme 11: a kind of electromotor, including solid particle accelerator, gas ejector, combustor and gas-solid separator, institute State solid particle accelerator, described gas ejector, described combustor and described gas-solid separator to be sequentially communicated.

Scheme 12: on the basis of scheme 11, the solid particle outlet making described gas-solid separator further is solid with described The solid particle inlet connection of body particle accelerator.

Scheme 13: a kind of electromotor, including solid particle accelerator, gas ejector, gas-solid separator and heating chamber, institute State solid particle accelerator, described gas ejector, described gas-solid separator and described heating chamber to be sequentially communicated.

Scheme 14: on the basis of scheme 13, the solid particle outlet making described gas-solid separator further is solid with described The solid particle inlet connection of body particle accelerator.

Scheme 15: a kind of electromotor, including solid particle accelerator, gas ejector, heating chamber and gas-solid separator, institute State solid particle accelerator, described gas ejector, described heating chamber and described gas-solid separator to be sequentially communicated.

Scheme 16: on the basis of scheme 15, the solid particle outlet making described gas-solid separator further is solid with described The solid particle inlet connection of body particle accelerator.

Scheme 17: a kind of electromotor, including magnetic-particle electromagnetism accelerator, gas ejector, combustor and magnetic-particle Generator unit, described magnetic-particle electromagnetism accelerator, described gas ejector, described combustor and the generating of described magnetic-particle are single Unit is sequentially communicated.

Scheme 18: on the basis of scheme 17, makes described magnetic-particle generator unit to described magnetic-particle electricity further Magnetic accelerator feed electric power.

Scheme 19: a kind of electromotor, including magnetic-particle electromagnetism accelerator, gas ejector, heating chamber and magnetic-particle Generator unit, described magnetic-particle electromagnetism accelerator, described gas ejector, described heating chamber and the generating of described magnetic-particle are single Unit is sequentially communicated.

Scheme 20: on the basis of scheme 19, makes described magnetic-particle generator unit to described magnetic-particle electricity further Magnetic accelerator feed electric power.

Scheme 21: a kind of electromotor, including magnetic fluid electromagnetism accelerator, gas ejector, combustor and magnetic fluid Generator unit, described magnetic fluid electromagnetism accelerator, described gas ejector, described combustor and the generating of described magnetic fluid are single Unit is sequentially communicated.

Scheme 22: on the basis of scheme 21, makes described magnetic fluid generator unit to described magnetic fluid electricity further Magnetic accelerator feed electric power.

Scheme 23: a kind of electromotor, including magnetic fluid electromagnetism accelerator, gas ejector, heating chamber and magnetic fluid Generator unit, described magnetic fluid electromagnetism accelerator, described gas ejector, described heating chamber and the generating of described magnetic fluid are single Unit is sequentially communicated.

Scheme 24: on the basis of scheme 23, makes described magnetic fluid generator unit to described magnetic fluid electricity further Magnetic accelerator feed electric power.

Scheme 25: a kind of electromotor, including conductive particles electromagnetism accelerator, gas ejector, combustor and conductive particles Generator unit, described conductive particles electromagnetism accelerator, described gas ejector, described combustor and the generating of described conductive particles are single Unit is sequentially communicated.

Scheme 26: on the basis of scheme 25, makes described conductive particles generator unit to described conductive particles electricity further Magnetic accelerator feed electric power.

Scheme 27: a kind of electromotor, including conductive particles electromagnetism accelerator, gas ejector, heating chamber and conductive particles Generator unit, described conductive particles electromagnetism accelerator, described gas ejector, described heating chamber and the generating of described conductive particles are single Unit is sequentially communicated.

Scheme 28: on the basis of scheme 27, makes described conductive particles generator unit to described conductive particles electricity further Magnetic accelerator feed electric power.

Scheme 29: a kind of electromotor, including conducting liquid electromagnetism accelerator, gas ejector, combustor and conducting liquid Generator unit, described conducting liquid electromagnetism accelerator, described gas ejector, described combustor and the generating of described conducting liquid are single Unit is sequentially communicated.

Scheme 30: on the basis of scheme 29, makes described conducting liquid generator unit to described conducting liquid electricity further Magnetic accelerator feed electric power.

Scheme 31: a kind of electromotor, including conducting liquid electromagnetism accelerator, gas ejector, heating chamber and conducting liquid Generator unit, described conducting liquid electromagnetism accelerator, described gas ejector, described heating chamber and the generating of described conducting liquid are single Unit is sequentially communicated.

Scheme 32: on the basis of scheme 31, makes described conducting liquid generator unit to described conducting liquid electricity further Magnetic accelerator feed electric power.

Scheme 33: a kind of electromotor, including conducting liquid electromagnetism accelerator, gas ejector, combustor and conducting liquid Generator unit, described conducting liquid electromagnetism accelerator, described gas ejector, described combustor and the generating of described conducting liquid are single Unit is sequentially communicated, and the gas access of described gas ejector connects with the gas outlet of described conducting liquid generator unit.

Scheme 34: on the basis of scheme 33, make further described conducting liquid generator unit conducting liquid outlet with The conducting liquid entrance connection of described conducting liquid electromagnetism accelerator.

Scheme 35: on the basis of scheme 33 or scheme 34, makes described conducting liquid generator unit lead described further Electro-hydraulic body electromagnetism accelerator feed electric power.

Scheme 36: a kind of electromotor, including conducting liquid electromagnetism accelerator, gas ejector, heating chamber and conducting liquid Generator unit, described conducting liquid electromagnetism accelerator, described gas ejector, described heating chamber and the generating of described conducting liquid are single Unit is sequentially communicated, and the gas access of described gas ejector connects with the gas outlet of described conducting liquid generator unit.

Scheme 37: on the basis of scheme 36, make further described conducting liquid generator unit conducting liquid outlet with The conducting liquid entrance connection of described conducting liquid electromagnetism accelerator.

Scheme 38: on the basis of scheme 36 or scheme 37, makes described conducting liquid generator unit lead described further Electro-hydraulic body electromagnetism accelerator feed electric power.

Scheme 39: in scheme 33 to scheme 38 on the basis of either a program, makes quilt in described gas ejector further The gas of injection is set to helium.

Scheme 40: in scheme 33 to scheme 39 on the basis of either a program, makes described conducting liquid electromagnetism add further Accelerated conducting liquid in speed device is set to hydrargyrum.

In the present invention, according to heat energy and the known technology of dynamic field, the parts of necessity, list should be set in necessary place Unit or system etc..

Inventors believe that, celestial body mutually moves and necessarily leads to gravitational interaction, and gravitational interaction necessarily leads to thing Mass flow is moved and/or object deformation, owing to material flowing and object deformation are irreversible process, is i.e. the mistake producing heat Journey, therefore the flowing of the material under gravitational field effect and object deformation necessarily lead to heat, and the heat that this form produces necessarily disappears The kinetic energy of consumption celestial body, As time goes on, through very long process, sky cognition gradually loses kinetic energy, and final sky is known from experience mutually Merging, final universe forms a particle, and the temperature and pressure of this particle all can be ramping up, thus is formed violent quick-fried Fried, blast re-forms celestial bodies motion state, even if celestial body has kinetic energy, again forms mutual relative motion and phase between celestial body Interaction, enters next one circulation.It can be considered that the existence in universe is a thermodynamic cyclic process with development in fact.This The essence of the process of kind can be summarised as " you invite me, and I am the most certain swallows you " simple, understandablely, it can be seen that, exist and alternately make The exactly mutually phagocytosis of its final final result of main body, mutually merge.

The present inventor thinks according to thermodynamic (al) ultimate principle and the observation to universe phenomenon: do not having external factor shadow On the premise of sound, heat can not absolutely be converted into other any type of energy or material.Conventional thermal mechanics second is fixed Rule only elaborating, heat can not absolutely be changed successfully, and this law is just on the premise of not having external factor impact True, but be unilateral.With popular language, heat can be defined as the minimum form of energy, or referred to as this is universe Rubbish.Through analyzing, the present inventor is additionally considered that: the growth course of any biology is all heat release.Through analyzing, the present inventor also recognizes For: (being not limited to thermodynamic process, such as chemical reaction process, biochemistry is anti-for any one process or any one circulation Process, photochemical reaction process, biological growth process, growing process is answered to be included) its maximum acting ability conservation, Inventors believe that and do not have photosynthetic growing process can not improve its acting ability, say, that bean sprout Acting ability is the acting ability sum that impossible add its nutrient absorbed higher than the acting ability of bean or pea；Why one tree The acting ability of wood is greater than the acting ability of seedling, is because sunlight and take part in by seedling to trees with photosynthetic form Growth course.

Present inventors believe that the basic logic that heat engine works be restrain-be heated-dissipate.So-called convergence is the density of working medium Increase process, such as condense, compress and all belong to convergence process, under same pressure, the working medium degree of convergence that temperature is low is big；Institute It is exactly the endothermic process of working medium that meaning is heated；What is called dissipates the process referring to that the density of working medium reduces, such as, expand or spray.Any One dissipates process and all can form the reduction of acting ability, and such as, the acting ability of the air of gaseous state is empty well below liquid The acting ability of gas；What methanol plus water added moderate temperature is thermally generated carbon monoxide and hydrogen, although the carbon monoxide generated and The combustion heat of hydrogen is more than the combustion heat about 20% of methanol, but its acting ability is the most micro-more than the ratio of the acting ability of methanol It is micro-, although its reason is this process and has inhaled the heat of about 20%, but the dissipating of product carbon monoxide and hydrogen Degree is far longer than methanol.Therefore, the physochlaina infudibularis utilizing temperature the highest adds chemical reaction and has no idea to be effectively improved product Acting ability.

It is known that in economics, Nobel Prize was all authorized in the research to information asymmetry and information symmetrical, it is seen that Both parties have Determines transaction success or failure, the fairness of transaction and the profit of transaction of information.The essence of transaction is in fact Information trading.For inventors believe that, patent has information zero symmetry, i.e. both parties and the true value of patent is all known it The fewest.Patent information zero symmetric properties, if do not cracked, operation is difficulty with.Information zero symmetry of patent determines patent fortune The science of battalion and complexity.In general goods is concluded the business, information asymmetry may advantageously facilitate transaction, improves profit.And to specially For profit, the most entirely different, patent needs to solve technical problem, and the value of patent is quickly known in patent exploitation, so Patent must be out-and-out, and information zero is symmetrical and information asymmetry is inevitable all can seriously hinder patent operation, solves patent information Zero AXIALLY SYMMETRIC PROBLEMS, making both parties' information symmetrical on high level is that the basic of patent operation enterprise works.

Beneficial effects of the present invention is as follows: electromotor of the present invention not only has efficiency height, pollutes little feature, and And it is few to have moving component, the advantage of simple in construction.

Accompanying drawing explanation

Shown in Fig. 1 is the structural representation of the embodiment of the present invention 1；

Fig. 2, shown in 3 it is the structural representation of the embodiment of the present invention 2；

Shown in Fig. 4 is the structural representation of the embodiment of the present invention 3；

Shown in Fig. 5 is the structural representation of the embodiment of the present invention 4；

Shown in Fig. 6 is the structural representation of the embodiment of the present invention 5；

Shown in Fig. 7 is the structural representation of the embodiment of the present invention 6；

Fig. 8, shown in 9 it is the structural representation of the embodiment of the present invention 7；

Figure 10, shown in 11 it is the structural representation of the embodiment of the present invention 8；

Shown in Figure 12 is the structural representation of the embodiment of the present invention 9；

Shown in Figure 13 is the structural representation of the embodiment of the present invention 10；

Shown in Figure 14 is the structural representation of the embodiment of the present invention 11；

Shown in Figure 15 is the structural representation of the embodiment of the present invention 12；

Shown in Figure 16 is the structural representation of the embodiment of the present invention 13；

Shown in Figure 17 is the structural representation of the embodiment of the present invention 14；

Shown in Figure 18 is the structural representation of the embodiment of the present invention 15；

Shown in Figure 19 is the structural representation of the embodiment of the present invention 16；

Shown in Figure 20 is the structural representation of the embodiment of the present invention 17；

Shown in Figure 21 is the structural representation of the embodiment of the present invention 18；

Shown in Figure 22 is the structural representation of the embodiment of the present invention 19；

Shown in Figure 23 is the structural representation of the embodiment of the present invention 20；

Shown in Figure 24 is the structural representation of the embodiment of the present invention 21；

Figure 25, shown in 26 it is the structural representation of the embodiment of the present invention 22；

Shown in Figure 27 is the structural representation of the embodiment of the present invention 23；

Figure 28, shown in 29 it is the structural representation of the embodiment of the present invention 24.

In figure:

1 gas ionization unit, 2 charged gas electromagnetism accelerator modules, 3 combustor, 4 charged gas generator units, 5 jet pipes, 6 Heating chamber, 7 solid particle accelerators, 8 gas ejectors, 9 gas-solid separators, 10 magnetic-particle electromagnetism accelerators, 11 magnetic Grain generator unit, 12 magnetic fluid electromagnetism accelerators, 13 magnetic fluid generator units, 14 conductive particles electromagnetism accelerators, 15 lead Body granule generator unit, 16 conducting liquid electromagnetism accelerators, 17 conducting liquid generator units.

Detailed description of the invention

Embodiment 1

Electromotor as shown in Figure 1, including gas ionization unit 1, charged gas electromagnetism accelerator module 2, combustor 3 and band The electrically gas of body generator unit 4, the gas outlet of described gas ionization unit 1 and described charged gas electromagnetism accelerator module 2 Entrance connects, and the gas outlet of described charged gas electromagnetism accelerator module 2 is single with the generating of described charged gas through described combustor 3 The gas access connection of unit 4.

Embodiment 2

Electromotor as shown in Figure 2, on the basis of embodiment 1, makes the gas of described charged gas generator unit 4 further Body outlet connects with jet pipe 5.

As disposable embodiment (electromotor as shown in Figure 3), embodiment 1 and embodiment 2 all can be selected further Make to selecting property described charged gas generator unit 4 to described gas ionization unit 1 and/or described charged gas electromagnetism accelerator module 2 feed electric power.

Embodiment 3

Electromotor as shown in Figure 4, on the basis of embodiment 1, makes described charged gas generator unit 4 to institute further Stating gas ionization unit 1 and/or described charged gas electromagnetism accelerator module 2 feed electric power, described charged gas generator unit 4 is right Outer feed electric power.

Embodiment 4

Electromotor as shown in Figure 5, including gas ionization unit 1, charged gas electromagnetism accelerator module 2, heating chamber 6 and band The electrically gas of body generator unit 4, the gas outlet of described gas ionization unit 1 and described charged gas electromagnetism accelerator module 2 Entrance connects, and the gas outlet of described charged gas electromagnetism accelerator module 2 is single with the generating of described charged gas through described heating chamber 6 The gas access connection of unit 4.

Embodiment 5

Electromotor as shown in Figure 6, on the basis of embodiment 4, makes the gas of described charged gas generator unit 4 further Body outlet connects with jet pipe 5.

Described charged gas all can be the most optionally made as disposable embodiment, embodiment 4 and embodiment 5 Generator unit 4 is to described gas ionization unit 1 and/or described charged gas electromagnetism accelerator module 2 feed electric power.

Embodiment 6

Electromotor as shown in Figure 7, on the basis of embodiment 4, described charged gas generator unit 4 is to described gas electricity From unit 1 and/or described charged gas electromagnetism accelerator module 2 feed electric power, described charged gas generator unit 4 is externally for power transmission Power.

Embodiment 7

Electromotor as shown in Figure 8, including solid particle accelerator 7, gas ejector 8, gas-solid separator 9 and combustor 3, described solid particle accelerator 7, described gas ejector 8, described gas-solid separator 9 and described combustor 3 are sequentially communicated.

As disposable embodiment (electromotor as shown in Figure 9), on the basis of embodiment 7, can make further The solid particle outlet of described gas-solid separator 9 connects with the solid particle inlet of described solid particle accelerator 7.

Embodiment 8

Electromotor as shown in Figure 10, including solid particle accelerator 7, gas ejector 8, combustor 3 and gas solid separation Device 9, described solid particle accelerator 7, described gas ejector 8, described combustor 3 and described gas-solid separator 9 are sequentially communicated.

As disposable embodiment (electromotor as shown in figure 11), on the basis of embodiment 8, can make further The solid particle outlet of described gas-solid separator 9 connects with the solid particle inlet of described solid particle accelerator 7.

Embodiment 9

Electromotor as shown in figure 12, including solid particle accelerator 7, gas ejector 8, gas-solid separator 9 and heating Room 6, described solid particle accelerator 7, described gas ejector 8, described gas-solid separator 9 and described heating chamber 6 are sequentially communicated.

Embodiment 10

Electromotor as shown in fig. 13 that, on the basis of embodiment 9, makes the solid of described gas-solid separator 9 further Grain outlet connects with the solid particle inlet of described solid particle accelerator 7.

Embodiment 11

Electromotor as shown in figure 14, including solid particle accelerator 7, gas ejector 8, heating chamber 6 and gas solid separation Device 9, described solid particle accelerator 7, described gas ejector 8, described heating chamber 6 and described gas-solid separator 9 are sequentially communicated.

Embodiment 12

Electromotor as shown in figure 15, on the basis of embodiment 11, makes the solid of described gas-solid separator 9 further Grain outlet connects with the solid particle inlet of described solid particle accelerator 7.

Embodiment 13

Electromotor as shown in figure 16, including magnetic-particle electromagnetism accelerator 10, gas ejector 8, combustor 3 and magnetic Granule generator unit 11, described magnetic-particle electromagnetism accelerator 10, described gas ejector 8, described combustor 3 and described magnetic Granule generator unit 11 is sequentially communicated.

Embodiment 14

Electromotor as shown in figure 17, on the basis of embodiment 13, makes described magnetic-particle generator unit 11 further To described magnetic-particle electromagnetism accelerator 10 feed electric power.

Embodiment 15

Electromotor as shown in figure 18, including magnetic-particle electromagnetism accelerator 10, gas ejector 8, heating chamber 6 and magnetic Granule generator unit 11, described magnetic-particle electromagnetism accelerator 10, described gas ejector 8, described heating chamber 6 and described magnetic Granule generator unit 11 is sequentially communicated.

Embodiment 16

Electromotor as shown in figure 19, on the basis of embodiment 15, makes described magnetic-particle generator unit 11 further To described magnetic-particle electromagnetism accelerator 10 feed electric power.

Embodiment 17

Electromotor as shown in figure 20, including magnetic fluid electromagnetism accelerator 12, gas ejector 8, combustor 3 and magnetic Fluid generating unit 13, described magnetic fluid electromagnetism accelerator 12, described gas ejector 8, described combustor 3 and described magnetic Fluid generating unit 13 is sequentially communicated.

Embodiment 18

Electromotor as shown in figure 21, on the basis of embodiment 17, makes described magnetic fluid generator unit 13 further To described magnetic fluid electromagnetism accelerator 12 feed electric power.

Embodiment 19

Electromotor as shown in figure 22, including magnetic fluid electromagnetism accelerator 12, gas ejector 8, heating chamber 6 and magnetic Fluid generating unit 13, described magnetic fluid electromagnetism accelerator 12, described gas ejector 8, described heating chamber 6 and described magnetic Fluid generating unit 13 is sequentially communicated.

Embodiment 20

Electromotor as shown in figure 23, on the basis of embodiment 19, makes described magnetic fluid generator unit 13 further To described magnetic fluid electromagnetism accelerator 12 feed electric power.

As the embodiment that can convert, described in embodiment 19,20, magnetic fluid electromagnetism accelerator 12 may select Property ground select replace with conductive particles electromagnetism accelerator 14, conducting liquid electromagnetism accelerator 16, described heating chamber 6 is optionally Selection replaces with combustor 3, and described magnetic fluid generator unit 13 is selectively chosen and replaces with conductive particles generator unit 15, conducting liquid generator unit 17.

Embodiment 21

Electromotor as of fig. 24, including conducting liquid electromagnetism accelerator 16, gas ejector 8, combustor 3 and conduction Liquid generator unit 17, described conducting liquid electromagnetism accelerator 16, described gas ejector 8, described combustor 3 and described conduction Liquid generator unit 17 is sequentially communicated, and the gas access of described gas ejector 8 and described conducting liquid generator unit 17 Gas outlet connects.

Embodiment 22

Electromotor as shown in figure 25, on the basis of embodiment 21, makes described conducting liquid generator unit 17 further Conducting liquid outlet connect with the conducting liquid entrance of described conducting liquid electromagnetism accelerator 16.

As disposable embodiment (electromotor as shown in figure 26), embodiment 21 and embodiment 22 all can be further Make described conducting liquid generator unit 17 to described conducting liquid electromagnetism accelerator 16 feed electric power.

Embodiment 23

Electromotor as shown in figure 27, including conducting liquid electromagnetism accelerator 16, gas ejector 8, heating chamber 6 and conduction Liquid generator unit 17, described conducting liquid electromagnetism accelerator 16, described gas ejector 8, described heating chamber 6 and described conduction Liquid generator unit 17 is sequentially communicated, and the gas access of described gas ejector 8 and described conducting liquid generator unit 17 Gas outlet connects.

Embodiment 24

Electromotor as shown in figure 28, on the basis of embodiment 23, makes described conducting liquid generator unit 17 further Conducting liquid outlet connect with the conducting liquid entrance of described conducting liquid electromagnetism accelerator 16.

As disposable embodiment (electromotor as shown in figure 29), embodiment 23 and embodiment 24 all can be further Make described conducting liquid generator unit 17 to described conducting liquid electromagnetism accelerator 16 feed electric power.

As disposable embodiment, embodiment 21 to embodiment 24 and disposable embodiment thereof, one all can be entered Step makes to be set to helium by the gas of injection in described gas ejector 8.

As disposable embodiment, embodiment 21 to embodiment 24 and disposable embodiment thereof, one all can be entered Step makes the accelerated conducting liquid in described conducting liquid electromagnetism accelerator 16 be set to hydrargyrum.

It is clear that the invention is not restricted to above example, according to techniques known and technology disclosed in this invention Scheme, can derive or association goes out many flexible programs, all these flexible programs, and also being regarded as is the protection model of the present invention Enclose.

Claims (10)

1. an electromotor, including gas ionization unit (1), charged gas electromagnetism accelerator module (2), combustor (3) and charged Gas generator unit (4), it is characterised in that: the gas outlet of described gas ionization unit (1) adds with described charged gas electromagnetism The gas access connection of speed unit (2), the gas outlet of described charged gas electromagnetism accelerator module (2) is through described combustor (3) Connect with the gas access of described charged gas generator unit (4).

2. electromotor as claimed in claim 1, it is characterised in that: the gas outlet of described charged gas generator unit (4) and spray Pipe (5) connection.

3. electromotor as claimed in claim 1 or 2, it is characterised in that: described charged gas generator unit (4) is to described gas electricity From unit (1) and/or described charged gas electromagnetism accelerator module (2) feed electric power.

4. electromotor as claimed in claim 1, it is characterised in that: described charged gas generator unit (4) is to described gas ionization Unit (1) and/or described charged gas electromagnetism accelerator module (2) feed electric power, described charged gas generator unit (4) externally supplies Power transmission power.

5. an electromotor, including gas ionization unit (1), charged gas electromagnetism accelerator module (2), heating chamber (6) and charged Gas generator unit (4), it is characterised in that: the gas outlet of described gas ionization unit (1) adds with described charged gas electromagnetism The gas access connection of speed unit (2), the gas outlet of described charged gas electromagnetism accelerator module (2) is through described heating chamber (6) Connect with the gas access of described charged gas generator unit (4).

6. electromotor as claimed in claim 5, it is characterised in that: the gas outlet of described charged gas generator unit (4) and spray Pipe (5) connection.

7. electromotor as described in claim 5 or 6, it is characterised in that: described charged gas generator unit (4) is to described gas electricity From unit (1) and/or described charged gas electromagnetism accelerator module (2) feed electric power.

8. electromotor as claimed in claim 5, it is characterised in that: described charged gas generator unit (4) is to described gas ionization Unit (1) and/or described charged gas electromagnetism accelerator module (2) feed electric power, described charged gas generator unit (4) externally supplies Power transmission power.

9. an electromotor, including solid particle accelerator (7), gas ejector (8), gas-solid separator (9) and combustor (3), it is characterised in that: described solid particle accelerator (7), described gas ejector (8), described gas-solid separator (9) and institute State combustor (3) to be sequentially communicated.

10. electromotor as claimed in claim 9, it is characterised in that: the solid particle of described gas-solid separator (9) exports with described The solid particle inlet connection of solid particle accelerator (7).