DE2700106A1 - METHOD OF OPERATING A COMBUSTION ENGINE WITH A MIXTURE OF HYDROGEN, AIR AND A HYDROCARBON FUEL - Google Patents

Description

Dr. O. Loesenbeck DipUng. route

DipUng. L C ^ Seck January 14, 1976 RS / kh

«I BWeWd. HefSorder SJiJ * 17

Pier F. TALENTI, Crans-sur-Sierre

Method for operating an internal combustion engine with a mixture of hydrogen, air and a Hydrocarbon fuel

The> invention relates to a method for operating a combustion engine with a mixture of hydrogen, air and a hydrocarbon fuel, wherein the hydrocarbon fuel and the hydrogen are introduced into the intake manifold of the engine will.

It is known to reduce the harmful exhaust gases and to increase the efficiency of internal combustion engines in the carburetor generated a gasoline vapor-air mixture in addition

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Mix in hydrogen. A better and more complete oxidation of the fuels in the cylinder chamber of the engine can be achieved when driving with excess air. Now , however, with conventional hydrocarbon fuels, the combustion of lean mixtures, ie mixtures with an increased amount of air compared to the stoichiometric fuel-air ratio, leads to misfires, uncontrolled combustion and malfunctions. On the other hand, a hydrogen-air mixture can still be ignited with much poorer mixing ratios. This excellent flammability of hydrogen is largely retained even with a mixture of a hydrocarbon fuel with hydrogen and air, so that when the mixture is ignited by the spark plug, the hydrogen ignites first and contributes to the optimal combustion of the subsequently exploding hydrocarbon fuel.

This makes it possible to increase the ignition range of the engine and at the same time to burn mixtures with a large excess of air. The combustion temperature is lower due to the larger excess of air, which reduces heat losses. Due to the almost complete combustion and the possibility of using higher compression ratios, the economy of the engine is increased with a simultaneous reduction in harmful exhaust gases and less pollution of the cylinder space. 709830/0638

The use of these known advantages was previously with Difficulties are associated with the lack of suitable devices for generating and supplying hydrogen for the mobile internal combustion engine. For example, carrying heavy pressure bottles for the hydrogen are cumbersome, as these are periodically refilled or refilled at special filling stations. need to be replaced. There is also a great risk of accidents and explosions. Also the storage of liquefied Hydrogen at low temperatures is cumbersome and expensive and unsuitable for mobile use.

The invention has therefore set itself the task of eliminating the aforementioned disadvantages and a method of the above to create mentioned genus, which is characterized according to the invention in such a way that the hydrogen by electrolytic Water decomposition is produced in a hydrogen generator that feeds the electricity through a hydrogen generator The alternator driven by the engine takes place, and that the hydrogen generator self-regulates the hydrogen production Adjusts engine demand to hydrogen.

In an expedient embodiment of the invention takes place the self-regulation so that the hydrogen pressure in one closed inner container of the hydrogen generator

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the level of the electrolyte acts in such a way that the level is lowered or raised depending on the pressure, so that the wetted area of the cathode plates immersed in the electrolyte is changed.

So it is possible that after reaching a given hydrogen pressure, the level of the electrolyte falls below the Cathode plates sink, which automatically switches off the circuit and prevents hydrogen production will.

The device for carrying out the method is according to the invention designed in such a way that it has a self-regulating hydrogen generator working according to the electrolysis process and has an alternator which feeds this electricity and is driven by the internal combustion engine.

Exemplary embodiments of the invention are explained in more detail below with reference to the drawings. Show it:

1 schematically shows the device arranged in a vehicle,

FIG. 2 shows a section along the line H-II according to FIG. 3 by a hydrogen generator,

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3 shows a section along the line III-III according to FIG. and

Fig. 4 is a circuit diagram for operating the device.

In FIG. 1, a drive system accommodated in a vehicle is shown schematically, which includes the internal combustion engine 1, an alternator 2 driven by it, and a hydrogen generator 3. The hydrogen generated by the hydrogen generator 3 reaches the air intake port 6 of the engine 1, which in this case is an Otto engine , via a volume control valve 4 and via the hydrogen supply line 5. The gasoline supply line 7 of the gasoline coming from the carburetor 8 also opens into the. Intake connector 6 and is connected downstream of the hydrogen inlet. The gasoline is sucked in from the fuel tank 9 by means of the pump 10 in a known manner, the amount required for the respective power requirements reaching the carburetor 8 and the remaining amount flowing back to the tank 9 via the pressure reducing valve 11.

The hydrogen generator 3 works on the principle of electrolytic water decomposition according to the gross equation H ₂ O - » yi O ₂ + H ₂ , the direct current required for the electrolysis being supplied by the three-phase alternating current alternator 2

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will. The switching arrangement required for the control and current regulation is denoted by 12. A conventional vehicle battery 13 is only used to excite the alternator 2 in the start-up phase and plays no further role in hydrogen production.

With the drive system shown in FIG. 1, the vehicle can either only run with the usual gasoline vapor-air mixture be operated, or an addition of hydrogen gas can also be fed to this mixture. The oxygen generated during the electrolysis process is also generated via the Oxygen outlet nozzle 14 blown off into the open.

The oxygen could also be collected or used for improvement are fed separately to the engine for combustion while avoiding the risk of explosion.

The completely enclosed hydrogen generator 3 consists of an electrolysis cell 15 made of metal, the walls of which according to are provided with an insulating layer 16 on the outside. At the point 17, the cell 15 is connected to the positive current contact, so that it acts as an anode together with the electrode plates 18 protruding into it.

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An inner plastic container 19 protrudes like a diving bell into the electrolysis cell 15 and contains the cathode plates 20, which are connected in parallel and are connected to the negative current contact via the connection point 21. The iron cathode plates 20 protrude only about 2/3 into the cell 15, the latter expediently made of corrosion-resistant Steel is made.

An aqueous solution of KOH at a concentration of around 20-30 % is used as the electrolyte. As the water decomposes, water can be topped up through the filler neck 22, advantageously using distilled or demineralized water. To check the liquid level, a viewing window (not shown) can advantageously be arranged on the cell outer wall. In experiments the hydrogen generator reached the best efficiency in an electrolyte containing 28 X KOH, which corresponds to a density of about 30 ° Be. ¹ When using tap water instead of distilled water for refilling, no adverse effects could be determined because of the large container content. It is even assumed that the chlorine and fluorine gases that are also separated out further improve combustion.

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The anode plates 18 are expediently made of iron or nickel, which are available for the passage of current standing total electrode areas of cathode and anode and the plate spacing the performance of the hydrogen generator have a decisive say.

The hydrogen deposited at the cathode 20 passes through the opening 23 into the antechamber arranged at the top of the container 19 24 with an inclined bottom 25. From the antechamber 24 the hydrogen passes through the opening 26 into the collecting chamber 27, from where it is fed to the engine 1 via the outlet pipe 28 and the flow regulating valve 4.

The oxygen separated at the anodes 18 escapes through the outlet nozzle 29 into the open.

When the engine 1 is operating, a negative pressure is generated in the intake manifold 6 during the intake stroke, through which hydrogen reaches the intake manifold via line 5. By adjusting the valve 4 accordingly and by suitable means By choosing the dimensions of the line 5, the amount of hydrogen supplied to the engine 1 can be adapted to requirements, with the fine adjustment of the amount of hydrogen generated in the hydrogen generator 3 takes place automatically. If the water

Substance production occurs in the gas-filled space 30 of the container

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19 and in the chambers 24, 27 an overpressure which presses the level of the electrolyte downwards, the latter through the recesses 32 in the container wall and the holes 33 in the cathode plates 18 in the free, under atmospheric pressure standing space 34 on the anode side can escape. This reduces the wetted, electrically conductive surface of the cathodes 20, so that the hydrogen production is automatically throttled and the demand and the production of hydrogen to get used to it again. Should the line 5 clogged

or the valve 4 be closed, the level 31 drops below the cathode plates 20, and the current flow will be interrupted.

The chambers 24, 27 serve the purpose of a prefilter in order to separate out liquid droplets present in the hydrogen. The excreted liquid flows back into the cell 15 along the inclined bottom surface 25. Appropriate a further filter 35 is provided in the hydrogen line 5, so that no corrosive liquids can get into the engine.

Because the power-generating alternator 2 connects directly to the internal combustion engine 1 is coupled, less electricity and, accordingly, less hydrogen is generated at lower engine speeds, whereby a further, engine speed-dependent regulation of the

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Hydrogen production is given.

The electrical circuit S for operating the system is shown schematically in FIG.

The commercially available 12-volt car battery 13 is connected to the three-phase alternator 2 and is used in the start-up phase of the excitation of the same, with four parallel resistors R ₁ - R. with 5.7 ohms each in the plus line limit the excitation current. Instead of four resistors, a single resistor could of course also be provided at point 36. The three-phase alternating current generated by the alternator 2 is converted into direct current by the rectifier arrangement 37 and fed to the hydrogen generator 3. The rectifier arrangement 37 has a group of six diodes with a maximum load capacity of 500 amperes each. For the measurement of voltage and current, a voltmeter 38 and an ammeter 39 are switched in parallel or in series in this circuit.

Another rectifier arrangement 40, consisting of a group of six diodes, each with a load capacity of 25 amperes, is used to generate excitation current after the start-up phase so that the alternator 2 is self- exciting and independent of the battery during operation.

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The diode group 41 and the diode 42 prevent the self-exciting current of the alternator from entering the battery flows back.

These diodes

41, 42 can each be loaded with 50 amps. To start up the system, a switch 43 is in the positive line of the battery arranged.

The device described here was installed and tested in an automobile of the "PEUGEOT 404" brand. Of the Alternator achieved an average of approx. 8 KW at an output voltage of 12 - 20 volts and an amperage of approx. 350 - 500 amperes, depending on the Engine speed.

By adding hydrogen to the gasoline vapor-air mixture was able to save gasoline in individual test drives due to the optimal combustion of the fuel in the cylinder chamber of approx. 50 * can be achieved.

The proportion of harmful exhaust gases was extremely low and the engine's combustion chamber was even after a long period of operation perfectly clean. The engine also worked at low temperatures, as evidenced by measurements of the outlet temperature Has been confirmed.

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The hydrogen generator used for the experiments had a base area of 80 cm × 15 cm and a height of 35 cm. Due to the large content, no additional cooling of the electrolyte was necessary.

In future generators, which would be suitable for series production and designed to be much more compact, could an automatic water refill and cooling of the electrolyte can be provided. The external shape of the generator the ones in the engine compartment of the vehicle would be useful Adapt to the space available.

Since the hydrogen is generated locally according to the engine requirement, and since the system is self-regulating in the event of overproduction throttles or switches off, the risk of explosion is largely averted. It should also be noted that the outer chambers of the generator are under atmospheric pressure, so that no explosion due to excess pressure can occur here either.

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Claims (7)

EB / br 21.12.76 Claims Jl. l / learn how to operate an internal combustion engine with a Mixture of hydrogen, air and a hydrocarbon fuel, wherein the hydrocarbon fuel and the hydrogen is introduced in the intake manifold of the engine, characterized in that the hydrogen is carried out by electrolytic decomposition of water in a hydrogen generator is generated that the power supply of the hydrogen generator takes place by an alternator driven by the engine, and that the hydrogen generator self-regulating the hydrogen production adapts to the engine demand for hydrogen. 2. The method according to claim 1, characterized in that the self-regulation takes place so that the hydrogen pressure in a closed inner container of the hydrogen generator acts on the level of the electrolyte in such a way, and that the level depends on the pressure is lowered or raised so that the wetted area of the cathode plates immersed in the electrolyte changes will. 709830/0638 ORIGINAL INSPECTED - ■ * ■> - 3. The method according to claim 2, characterized in that that after reaching a given water pressure the level of electrolyte below the cathode plates will drop, which automatically turns the circuit off and hydrogen production is stopped. 4. The method according to claim 1, characterized in that the hydrogen generated in the hydrogen generator before the outlet from the generator flows through two chambers arranged at the top of the latter in the longitudinal direction, wherein liquid droplets mixed with the gas are excreted and flow back into the generator » 5. The method according to claim 1, characterized in that the alternator when starting by means of a Battery is externally excited, that it excites itself during operation and that the three-phase alternating current is converted into direct current by means of a rectifier to feed the hydrogen generator. 6. Device for performing the method according to claim 1, characterized in that it works according to the electrolysis process, self-regulating Hydrogen generator (3) and an alternator that supplies electricity and is driven by the internal combustion engine (2). 709830/0638 7. Apparatus according to claim 6, characterized in that the hydrogen generator (3) is insulated from the outside Has electrolyzing cell (15), in which a inner plastic container containing the cathode plates (20) (19) is inserted, and that above this container an antechamber (24) with an inclined Bottom (25) and a collection chamber (27) for the hydrogen are arranged. Θ. Device according to claim 7, characterized in that that the cathode plates (20) attached to the top of the plastic container (19) are shorter than the height of the container (19), in such a way that the hydrogen production can be changed as a function of the hydrogen pressure The level of electrolytes in the container (19) can be varied. 709830/0638