DE102013003982A1 - Applied fuels in the composition changed to apply energy. - Google Patents

Abstract

Applied fuels in the composition changed to use for energy production.

Description

In all fuels or gas combustion processes, the fuel is mainly atomized in the combustion chamber under pressure, so increases the liquid or gas surface and in the combustion chamber, for example: in diesel engines, which preferentially drive a car, the nebulized diesel fuel is compressed. Prior to compression, by preference, air will flow into the combustion chamber through the piston stroke at the same time. This can also take place separately, for example by turbocharging. Because without air there is no combustion process.

The inventor shows that fossil or biofuels and gas fuels as well as organically grown gas fuels, known as renewable energy, are used as, for example, fuel concentrates. Because the invention uses conventionally produced fuels or gases to enrich these fuels with, for example, before entering the combustion chamber, preferably with environmental air. Here, for example: fuel oil, subjected to a surface enlargement and enriched with preferential air. As a result, thanks to the invention, the volume of liquid is increased, depending on the introduced air in the fuel. For example, if 0.2 liter of air is introduced into one liter of liquid or gas fuel before it enters the preferred combustion chamber, the volume of liquid or gas increases by, for example, 0.2 liter. This has the advantage that consumption drops by 0.2 liters of liquid or gas fuels. Because the combustion chamber is supplied with the same volume of fuel as when no fuel enrichment with preferential air was applied. The inventor provides that the air, for example, with liquid fuel or gas fuel is so intense that the air is trapped by the applied fuels as high as possible and flows as a volume flow in the direction of the combustion chamber.

A further advantage of the invention is that fuel pretreated in this way becomes more explosive than untreated fuel and also has clean combustion, and thereby the increase in volume due to introduced air in the fuel is also expelled during the combustion process to produce less Co ² .

Another advantage of the invention is that it is possible to consume less fuel without sacrificing performance and at the same time increasing performance through more explosive fuel.

A further embodiment of the invention is that any type of fuels used for energy production is changed before entering the respective combustion chamber in the original composition. For example, the additional air feed into the combustion chamber is still applied but for example applied in a modified manner.

For example, the inventor contemplates, by method and arrangement, the following, for example, methods of generally enriching all possible types of fuel with preferred air before flowing into the combustion chambers or combustion chamber, under pressure, or through aspirated flow velocity. This was inventively so solved, commercial fuel, liquid or gas, is from the example storage tank ( 2 ) via at least one line ( 3 ) in, for example, a component ( 8th ) flows in, with or without pumps or gas support (pictorially shown only partially) at the same time air flows preferentially in the component ( 8th ) via the preferred check valve (16) into the air intake facility ( 5 ) on the component ( 8th ) one. The two media, such as air and liquid fuel flow through the component at the same time or with a time lag ( 8th ) in the direction of the pump ( 1 ) preferably as a separating slide displacement pump ( 1 ) designed. Now the still insufficiently connected two media or even more than two media by the rotation within the pump housing ( 6 ) simultaneously in centrifugal speed and under pressure in the direction of the pump outlet ( 7 ) pressed. This has the advantage that now already a better connection between, for example: air and liquid fuel has been completed and an increased liquid volume flow was produced and inevitably the composition of the example liquid fuel was changed before it in the component ( 8th ) had flowed. After discharging the preferred two communicated media from the pump ( 1 ) in the direction of component ( 18 ) which was preferably filled with bulk material in preferably different preferred granular form by a more tightly packed form in the component ( 18 ) to ensure. The so-flowing media vorzugshalber air and liquid fuel are nebulized when flowing through the introduced bulk material and the liquid mist takes at the same time with the inflowing air and is at leakage of the liquid air mixture from the component ( 18 ) and will not relax before entering the combustion chamber and separate the air as air bubbles from the liquid. In order to prevent liquid fogging in the component ( 18 ) (filled with bulk material), it has been inventively solved by the pump ( 1 ) and line ( 17 ) in connection with the component ( 8th ) and line ( 9 ) and component ( 10 ) a preferred liquid circuit during operation of the pump ( 1 ) achieved. The pump ( 1 ) is designed so that it circulates, for example, in one hour, preferably 400 liters of liquid under pressure. For example, the inventor contemplates that the circulation rate of the pump ( 1 ) for example, is higher than the decreased amount of liquid. Lines and components that are used to secure a liquid or gas circuit and to dimension that a high flow rate through the component ( 18 ) is guaranteed accordingly. The higher the flow velocity, the higher the surface enlargement of the introduced media used for energy production, and thus the more intense is, for example, the air enrichment in liquids. In the exemplary fluid circuit, an increased pressure will occur than the feed pressure before flowing into the fluid circuit. According to the invention, however, the gas feed, for example, by the use of air compressors used for air feed, the gas pressure may be higher than the circuit pressure during operation of the pump ( 1 ). An increase in pressure can also occur in the liquid area before entering the pump ( 1 ) can be applied, for example, via a nozzle for liquid on the component ( 18 ) (not pictorially shown) already atomized into the component ( 18 ) in order to be able to 18 ) to better connect the incoming air at the same time before entering the pump together ( 1 ) or from the pump ( 1 Preferably, a self-priming pump ( 1 ) applied. This has the advantage that at different consumed example diesel fuels for example diesel engine driven cars. To ensure this, a self-priming pump ( 1 ) is advantageous, because from the circulation system, the enriched and compositionally changed fuel is branched off in the direction of the engine via the component ( 10 ) without the pressure in the circuit drops. At the inflow low-pressure side ( 7 ) of the pump ( 1 ) the pressure will drop so controlled that trailing air and liquid fuel can flow in at the same time in the amount consumed as for example diesel engine which ensures that there is no lack of fluid in the pump ( 1 ) and can occur in the circulatory system and can lead to disorders (only partially shown).

By the pressure regulator ( 12 ), the fluid pressure from the circulation line is lowered in the desired pressure setting on the pressure regulator ( 12 ) and the enriched liquid over the component ( 10 ) in front of the pressure regulator ( 12 ) is seated after the pressure regulator, the liquid with reduced pressure in the direction of the combustion chamber ( 16 ) stream.

The inventor also provides, for example, liquid or any type of combustion fuels already in the tank ( 2 ) with air or gases in order to spread them over the component ( 18 ) to flow. Also, the inventor provides that the liquid or gas cycle over the tank ( 2 ) and then preferably via the pump ( 1 ) in the direction of the combustion chamber ( 16 ).

Thanks to the invention, it is also possible, for example, to atomize heavy oils and to communicate with, for example, air or combustible gases or liquid fuels and, for example, the component ( 18 ) filled with bulk material and by this measure the various media to unite intimately before it enters the combustion chamber (not shown pictorially).

The inventor also contemplates that the above methods be used to drive turbines, for example aircraft power turbines (not shown pictorially).

According to the invention, the component ( 10 ) Preferably, after the component ( 18 ) to ensure that only liquid fuel, for example enriched with air, reaches the applied combustion chamber. The required circulation pressure which is used is preferably via a setting on the pump ( 1 ) but can also be performed conditionally, for example, by cross-sectional constriction in line or components (not shown pictorially).

The inventor also provides that the complete system, for example, bring gases into contact with liquids in at least one housing and this housing, for example, as a collecting container for escaping liquid in conjunction with at least one leak protection, which shuts down the system and the combustion process ends (not figuratively shown).

The inventor also provides that the pump ( 1 ) is only preferably in operation when combustion takes place (not shown pictorially).

The inventor also provides that it is ensured via an independent programmable controller, pre and post run times for the pump ( 1 ) and applied electric solenoid valves is provided (not shown pictorially).

According to the invention, it has an advantage, for example liquid fuel enriched with air in circulation via the pump ( 1 ) to keep pumped as long as taken from the circulation, enriched liquid, the excess amount is enriched

Liquid in the pump ( 1 ) and recycled in the component and recirculated air newly introduced into the liquid, so the constantly getting well recycled fuel enters the combustion chamber. Because at rest of the pump ( 1 ) may occur in the circulatory system for the release of air when pressure drops occur in the circulatory system (shown only partially).

According to the invention, the inventor also proposes to use at least one continuous chiller device when the applied fuels require to reach the combustion chamber at a constant temperature. An increased liquid or gas temperature can occur if, for example, a continuous operation of the pump ( 1 ) is applied by friction inside and outside the pump ( 1 ) and can thereby negatively affect the preferential half enrichment of air in liquids (not shown pictorially).

Likewise, the inventor proposes to mention the applied fuel, for example, to achieve a better flow characteristics, for example, in heavy oil combustion (not shown pictorially).

The pumps ( 1 ) Drive is preferably driven by at least one electric motor (not shown pictorially).

The inventor also provides that combustible gases with air or other gases by surface flow volume increase is used (not shown pictorially).

The inventor also provides that so-called motor-driven power plants which also generate electricity and also heat by using the above-described system save even more energy.

The inventor provides, for example, that the motor of the pump ( 1 ) is connected to the electronics of the respective field of application requires the fuel for energy. This means that only with current combustion processes, the engine preferably moves the pump ( 1 ).

figure description

From the tank ( 2 ) is taken from conventional liquid or gas fuel via the line ( 3 ). The particular fuel used is used as fuel concentrate because it is in the component ( 18 ) is stretched with preference air. So that increases liquid or gas volume. Feeding into the component ( 8th ) of liquids and air is preferably carried out at the same time. In the pump ( 1 ), the different media are brought together by increased speed and pressure increase. Thereafter, under pressure, the fuel concentrate and the introduced air through the component ( 18 ) pressed. This results in a surface increase of the liquid and the air, since it is brought in an increased flow rate through the pump ( 1 ). The liquid and the air are preferably transported via bulk material in the component ( 18 ) completed (pictorially not shown). The fuel concentrate enriched with air leaves the component ( 18 ) intensively united in the direction of circulation ( 17 ) into the component ( 10 ) where it is split. The excess reaches the pump ( 1 ) over the component ( 8th ). The fuels needed for energy production are discharged via the outlet ( 11 ) in the direction of, for example, pressure regulator ( 12 ) in the preferred filter housing ( 14 ) and enter the preferred combustion chamber or combustion chambers ( 16 ). The unneeded fuel concentrate enriched with air is circulated in the circulation.

LIST OF REFERENCE NUMBERS

1

Pumpe

2

Tank

3

Leitung

4

Rückschlagventil

5

Lufteinspeisung und Magnetventil

6

Pumpen (1) – Innengehäuse

7

Niederdruckseite Pumpe (1)

8

Einspeisungsbauteil für Flüssigkeiten und Gase

9

Leitung

10

Abzweigbauteil

11

Leitung

12

Flüssigkeitsdruckregler

13

Leitung

14

Flüssigkeitsfiltergehäuse

15

Leitung

16

Brennkammer

17

Leitung

18

Gehäuse für vorzugshalber Schüttgut (bildlich nicht dargestellt) gesichert durch mindestens 2 Siebe (bildlich nicht dargestellt)

19

Ausström und Druckseite der Pumpe (1)

Fig. 1 Overview:

1

pump

2

tank

3

management

4

check valve

5

Air infeed and solenoid valve

6

Pump ( 1 ) - inner housing

7

Low-pressure side pump ( 1 )

8th

Infeed component for liquids and gases

9

management

10

branch component

11

management

12

Fluid pressure regulator

13

management

14

Liquid filter housing

15

management

16

combustion chamber

17

management

18

Housing for preferred bulk material (not pictured) secured by at least 2 screens (not shown pictorially)

19

Outflow and pressure side of the pump ( 1 )

Claims (11)

Applied fuels in the composition changed to apply energy. Applied fuels in the composition changed with gas enriched to use for energy. Applied fuels in the composition changed and enriched with gases to generate kinetic energy. Applied propellants in the composition modified according to the method and arrangement according to claims 1-4 characterized in that combustion chambers ( 16 ). Applied propellants in the composition enriched with air by the method and arrangement according to claim 1-5 thereby characterized in that the volume of liquid is increased by the introduced air. Applied propellants in the composition modified according to the method and arrangement according to claims 1-6, characterized in that the applied fuels in a pump ( 1 ) is pressurized. Applied propellants in the composition modified and enriched with gases according to the method and arrangement and claims 1-7 characterized in that the enriched liquid gas mixture through a component ( 18 ) with increased flow velocity through preferably increased bulk material surface from the component ( 18 ) flows out. Applied fuels in the composition modified and enriched with gases according to the method and arrangement and claim 1-8, characterized in that the enriched fuel is circulated in the circulation. Applied propellants in the composition modified and enriched with gases according to the method and arrangement and claim 1-9 characterized in that from the circulation line ( 17 ) enriched fuel via the component ( 10 ) is diverted. Applied propellants in the composition changed according to the method and arrangement and claim 1-10, characterized in that different media and gases at the same time in the pump ( 1 ). Applied propellants in the composition modified and enriched with gases according to the method and arrangement and claim 1-11, characterized in that liquids and gases at the same time in the component ( 8th ).

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