RU2493387C2 - Device for energy conversion, system and method for hydrogen and oxygen burning - Google Patents

Abstract

FIELD: power engineering.

SUBSTANCE: device comprises a chamber and a supply system equipped with at least one valve for serial injection of hydrogen and oxygen into the chamber. The chamber is partially filled with water. The combustion chamber ignites the mixture of hydrogen and oxygen in the chamber, which results in higher pressure and water movement in the chamber. Energy-receiving elements (EE) are built into the chamber to receive movement and pressure of water. EE may be made in the form of pistons equipped with electromagnets. EE may convert mechanical energy into hydraulic one. The chamber is equipped with a relief valve to discharge excessive water produced during burning. The method is described for energy conversion device operation, and also a system using such a device.

EFFECT: development of a closed system without gas emissions from the chamber.

3 cl, 4 dwg

Description

The present invention is an energy conversion device and a system operating by burning and expanding hydrogen and oxygen. The expansion forms a movement in the volume of the liquid, which is converted into the necessary form of energy. In addition, this invention relates to a method of operating an energy conversion device. Such an energy conversion device operates in a closed system, therefore, it is not necessary to add liquid to the working unit. Therefore, the operating unit can operate as a mechanical fuel battery. After burning and expansion, the void that forms during the expansion process may disappear. This disappearance causes a sharp drop in pressure, which can be used during operation of the unit. The considered operating unit combines the combustion unit / reactor and units for using the generated energy.

The method of using hydrocarbon as a fuel is well known in certain industries. For example, hydrogen is used in standard piston engines, usually together with atmospheric air. However, in such systems, the cycle is not closed, and the energy conversion device is not integrated into the operating unit. As a rule, motors and electric generators or pumps of individual devices are separated from each other.

WO2005085614 describes a power generation system together with a combustion unit and an ignition unit, a main accumulator, a hydraulic rotor, a control valve and an energy generator. Hydrogen, oxygen and water are supplied to the combustion unit. The ignition system ignites a mixture of hydrogen and oxygen in the combustion unit. The expansion of the fluid inside the combustion units directly leads to an increase in pressure in the hydraulic fluid. Under pressure, the hydraulic fluid inside the combustion chamber moves to the main hydraulic accumulator. The hydraulic rotor directs the energy of the pressurized hydraulic fluid to rotate the output shaft.

The pressure conversion device according to the present invention does not emit any gases. The combustion and expansion of hydrogen and oxygen molecules leads to the formation of an aqueous phase in the first movement as well, and in the second, their disappearance and pressure decrease take place. The forming water flows out of the block and can be sent to any block to restore hydrogen and oxygen, thereby forming a closed system. Expansion with the subsequent disappearance of the gas filling the void that forms during the expansion can be used to create pressure fluctuations and the movement of the layers in a liquid medium, it is recommended to use water, which again can be converted into other forms of energy.

Movement and pressure can be converted to electricity. The energy generation in the block is one of the variants of the invention and is carried out using linear magnets that move inside the coil and generate electric current. During the expansion process, the magnet is fixed inside the coil and is pulled out of the coil due to implosion / pressure reduction. In other words, the magnet has a double acting cycle. The operating unit is protected by a bypass valve mounted on top, which can be retrofitted as a safety valve. Only H ₂ and O ₂ gases are supplied to the working unit. Water in its normal form, in the form of water dust, steam or other forms should not be used in the process if the original volume was added. The decrease in pressure in the upper part of the block after combustion allows the pistons to squeeze the water back to the upper part. The initially added volume of liquid will remain inside the reactor, since the system does not accept any liquid medium other than that which is added during the reaction between 2H ₂ and O ₂ to form 2H ₂ O. Thus, no gases are formed during the reaction, which avoids equipping the working unit with an exhaust device for venting gases.

The present invention — an engine or energy conversion device — is a hydrogen and oxygen generator. It is recommended to use an energy conversion device to generate electricity, however, it can also be used to pump hydraulic fluid / drive pneumatic devices, generate mechanical rotational motion, etc.

The chamber is adapted so that it is possible to include a part filled with a liquid medium, and in some situations a part without liquid due to partial filling of the chamber with such a liquid medium, thereby forming a void without liquid above the surface of the liquid medium. The feed system pumps hydrogen and oxygen into a fluid-free void. An ignition system, equipped with, for example, a spark plug or plasma arc, is included in a void free of liquid to ignite and burn hydrogen and oxygen, thereby forming a pressure change in this void that spreads to the fluid in the chamber and makes it move.

The bypass valve is used exclusively to drain the water generated during the combustion process and forms a single outlet in the chamber so that it is basically a closed system. Energy-receiving elements that capture motion and pressure in a liquid medium are built into the chamber. This means, for example, that such elements are fixed on the openings of the chamber wall so that the liquid medium in the chamber acts directly on such energy-receiving elements.

The operation of the ignition system can be controlled by the natural frequency of the reciprocating movement, moving the weight of the system. The weight of the system is the weight of the liquid medium along with the weight of the energy-receiving elements, for example, pistons.

Energy-receiving elements capture the movement of a liquid medium resulting from pressure drops and convert this movement into electric current, pneumatic pressure, hydraulic pressure, or other energy described above.

Such energy-receiving elements allow the chamber volume to change due to pressure fluctuations in the chamber itself, and such a change in volume supplies energy to the energy-receiving elements.

Energy receiving elements may, for example, include pistons mounted on cylinders. Pistons can be connected to blocks that convert mechanical motion into electric current. As a rule, pistons move magnets fixed on the coils so that such a fixed magnet can move back and forth in the coil and thereby generate an electric current. The control unit coordinates and controls the process of generating electric current by coils.

As an additional option, the pistons can be connected to units that convert mechanical movement into hydraulic pressure, for example, with hydraulic pumps.

The supply system includes at least one adjustable valve for sequentially supplying oxygen and hydrogen to a void free of water, and the ignition system includes a sequential ignition unit connected to at least one adjustable valve.

The chamber can be connected to the outlet using a bypass valve to drain the water, which is formed by the combustion of hydrogen and oxygen.

An elastic diaphragm can be installed between the part of the chamber filled with the liquid medium and the part free of the liquid medium, which, for example, reduces the formation of vapor and separates the phases of the liquid and gaseous medium.

The energy-receiving elements may include pistons mounted on cylinders, and such pistons may be connected to a system holding the pistons in a resting position. This position can be maintained, for example, by a spring, an electric regulator or, for example, a magnet and a coil.

The energy conversion device may have a natural frequency of motion of the fluid beds, while the sequence of gas supply and its ignition can be controlled by the natural frequency of the fluid in motion.

The chamber can be formed in the form of an almost horizontal cylinder with hemispherical ends, and most of the energy-receiving elements are installed along such a cylinder.

The safety valve is used to prevent overpressure in the chamber of the preset values.

As a liquid medium, you can use water.

In addition, the invention relates to a method of operating an energy conversion device for burning hydrogen and oxygen in a chamber equipped with a delivery system with at least one valve. Such a valve provides sequential injection of hydrogen and oxygen into the chamber. The ignition system is used for ignition and ignition in order to create a pressure drop and the movement of water layers in the chamber.

The specified method includes the following steps:

injecting water into the chamber, supplying hydrogen and oxygen in a stoichiometric composition through at least one valve so that a liquid-free void is formed in the chamber, igniting the gas in the gas void using the ignition system, which leads to an increase in pressure and movement of the layers water in the chamber, the adoption of energy-receiving elements, the increase in pressure and the movement of water, while such elements must be built into the chamber, and also includes the discharge of water formed in the combustion process through knoy valve.

The discharged water can be pumped back into the working unit for splitting into hydrogen and oxygen, thereby forming a completely closed cycle.

Also, the described method may include introducing an additional volume of H ₂ into the chamber so that excess H _{2 is} formed there to thermally isolate the ignition system and the feed system, as well as to reduce heat loss during expansion.

A certain part of H ₂ not participating in the combustion can be controlled and used to restore the required volume and maintain the pre-set operating parameters.

In addition, the invention relates to a system using an energy conversion device together with a chamber, a supply system and at least one valve for sequentially pumping hydrogen and oxygen into the chamber, an ignition system for igniting and burning hydrogen and oxygen, thereby creating an increase in pressure and movement of water in the chamber. The system also includes a bypass valve for the discharge of water resulting from combustion, which forms the outlet in the chamber during its operation, which is the only one, therefore the chamber is a sealed system. Energy-receiving elements designed to accept the movement and pressure of a liquid medium are built into the chamber. The bypass valve can be connected to a unit for splitting water into hydrogen and oxygen to form a completely sealed system.

Brief description of the attached drawings:

figure 1 - detail of the cross section of the upper part of the device, which is the object of the invention in its first embodiment;

figure 2 - part of the energy conversion device in accordance with one embodiment of the invention;

figure 3 is a variant of the invention, shown partially in section and in perspective;

4 is a closed energy conversion system according to the present invention.

Figure 1 presents a schematic illustration of the invention, including an energy conversion device, while the engine or generator 9 is shown together with the camera 2 installed in its upper part. The spark plug 1 is located in the upper part of the chamber 2 on the side of the safety valve. One 3-way inlet fitting, which is recommended for use with a stoichiometric mixture of hydrogen and oxygen, is located in the chamber. The surface of the liquid medium 10 is depicted as the region between the part filled with liquid and the part filled with gas. The energy-receiving elements 7 are depicted in the form of pistons moving magnets in the coils 5. The spark plug, as a rule, is a device that generates a plasma arc.

Figure 2 shows the energy transformer 9 in accordance with the present invention, which is viewed from the outside of the power receiving devices 7. Coils 5 are also clearly visible.

Figure 3, the present invention is additionally presented so that the upper part of the chamber 2 is located below the two electrodes 1A and the safety valve 6. Energy-receiving elements 7 with pistons 4 are shown mounted on the side of the cylindrical chamber. Also shown is an image of six power receiving elements 7. The electronic control device 8 can control the gas supply, ignition, monitor pressure, temperature, level of the liquid medium, and can also control the valve for the descent of the liquid.

Figure 4 additionally presents a system in accordance with the present invention, when the chamber 2, not containing a liquid medium, is located below the plasma electrodes 1a, which determine that the plasma is in a high voltage field. The strength and duration of the plasma field is controlled by the plasma coil 18. The field is formed between two plasma electrodes 1a, which are connected to a high voltage source, and is presented in the form of a plasma coil in the figure. The plasma coil 18 is controlled by the control device 19. A voltage level in the range 400000-450000 Volts is supplied to the plasma electrodes 1a. The plasma arc formed between the electrodes, as a rule, begins to form between hydrogen and oxygen and gradually the speed of its formation reaches 12000 m / s. The plasma arc can be quite stable and have the ability to ignite when immersed in water. Plasma electrodes and gas inlets are specifically designed to provide complete electrode insulation.

The reaction between hydrogen and oxygen increases the pressure in chamber 2. As a result of this reaction, water is formed.

After completion of the reaction, the cavity formed during the reaction cools and a sharp decrease in pressure occurs in chamber 2. The pressure level in the chamber 2 will thus fluctuate between very high and very low, significantly less than atmospheric pressure levels. Such pressure fluctuations will move the water column inside the chamber, and the chamber will begin to move up and down. The assembly of parts in question may have a separate inlet for a liquid medium, for example, for water.

The volume of added water can be approximately half of the total volume of the reactor, taking into account the energy-receiving elements 7 with their corresponding external position. As a result, a void, not containing liquid, is formed above the surface of the liquid medium in the upper part of the working unit, if the energy-receiving elements 7 are not in the corresponding position inside. The liquid medium is pumped down during combustion and presses the pistons of energy-saving elements from the outside.

The energy-receiving elements 7 include pistons 4 with integrated magnets, which can move directly and in the opposite direction in the cylinders, surrounded by coils 5. However, the energy-receiving elements 7 can be designed in different ways, for example, with membranes instead of pistons 7. It should be noted that such elements can transform the movement of water layers into useful energy.

Using valve 3, adjustable volumes of oxygen and hydrogen, respectively, can enter the working unit. The operation of the valves is controlled by the control unit 19 and, as a rule, by valves with electromagnetic control. The water that results from the reaction between hydrogen and oxygen is discharged through an equalizing or bypass valve 21. The bypass valve 21 can also be controlled by a control unit. As a bypass valve, the use of a solenoid valve is allowed. The main characteristic of the bypass valve 21 is to ensure that excess water accumulated in the chamber is pushed out by means of installed pistons. Water passing through the bypass valve 21 can be transferred back to the conversion unit, where it will again be split into hydrogen and oxygen in the first return line 13 connected to the liquid return pump 14, as well as in the second return line 15. A larger volume injection is allowed hydrogen compared to oxygen in chamber 2 so that there is always an excess of hydrogen in the chamber. During the combustion process, only a stoichiometric volume of hydrogen and oxygen will be burned; therefore, theoretically, only a stoichiometric volume of hydrogen and oxygen should be added to the reaction that takes place at each step, when an additional volume of hydrogen is supplied. An additional volume of hydrogen will be placed at the top of the chamber and will be used as an insulating layer. Thus, most of the heat will sink down and take part in the expansion. At the same time, a smaller amount of heat will be pumped down, and the upper part of the chamber, together with the plasma arc electrodes and inlet valves, will be exposed to much less heat. The volume of hydrogen, which was introduced additionally, can be controlled by the control unit 18 based on the measured parameters or experimental data. For example, volume control may be performed depending on the temperature in the chamber and in the area around the exposed components that are located above. Alternatively, another inert insulating gas may be used. An additional volume of gas is pumped through a valve for hydrogen 3, through which hydrogen is also supplied to the combustion chamber, or through a separate valve.

The entire working unit can also be cooled as necessary, for example, by means of air or water flows supplied from the outside of the chamber through the coil of the cooling pipe located inside the chamber due to the circulation of water in the chamber through the cooling block, etc. The cooling process can be controlled using conventional thermostats of the control unit, etc.

The conversion device is connected to the storage tanks 11 and 12 so that hydrogen and oxygen can be pumped in compliance with all established precautions. Thus, the entire working unit is designed as a closed system without supplying a liquid medium / water. The water in chamber 2 also forms a closed system and does not participate in the exchange together with the circulation, which is formed as a result of the reaction of water formation between oxygen and hydrogen. The separation unit is shown in the figure as electrolyzer 17.

Pistons 4 with fixed magnets are located inside the cylinder, which at one end is in contact with the liquid medium in chamber 2, and the other end is in contact with the surrounding atmosphere. Alternatively, the other end of the cylinder may be in contact with the gas source through the pipe 20 to control or reduce the stroke of the pistons 4. The pistons 4 may be driven in the direction of the chamber 2 due to atmospheric pressure, by means of springs, a magnetic field or other influence or devices, which can exert force on the piston in the forward and reverse direction to the chamber 2.

If the pipes 20 are connected to appropriate valves (not shown) that can be used to pump the liquid medium together with power generation or autonomously. In this case, the energy-receiving elements 7 will include devices for ensuring the return of the pistons 4, for example, springs (not shown).

Pistons can also be mechanically connected to devices for transmitting force to the rotary shaft.

The safety valve 6 can be installed inside the chamber 2 to prevent excess pressure in the chamber above a predetermined level.

When the energy conversion device is started, the pistons 4 are transferred to the internal position relative to the chamber 2. This position is considered internal to the pistons, while the chamber is completely filled with water. Such a situation may occur, for example, when a liquid medium is aspirated through the upper part of the chamber 2 so that the pistons are drawn in and the chamber is filled with water. Such a decrease in pressure in the chamber may be necessary to displace gases and impurities dissolved in water. It is not recommended to use substances other than hydrogen, oxygen and water during the reaction.

Alternatively, the internal position for the pistons 4 may correspond to a chamber filled with a mixture of water and an insulating gas, preferably hydrogen.

The internal position of the pistons can also be monitored during their operation by means of a volume of water that can move through the bypass valve 21 and the added volume of insulating hydrogen.

Only clean water and possibly an insulating gas are allowed in the chamber. The advantage of a closed system is the ability to control the working environment without water pollution. Foreign impurities in water can have a negative effect on the entire system - combustion / reaction, as well as after combustion, if it is recommended that the pressure in the system drops to a minimum level very quickly. Foreign impurities may also have disadvantages associated with corrosion and wear. As an additional option, a membrane can be installed in a chamber that will separate two liquid media. Pure water formed as a result of the reaction / combustion of hydrogen and oxygen must be used as one liquid medium.

The electronic control unit may include sensors that monitor pressure, temperature, piston position, etc. and based on the data obtained during the measurements, control the process of gas injection and ignition of the plasma arc. All explanations related to the working device are presented in Fig. 4 and can also be attributed to other figures, and the device depicted in Fig. 4, of course, can be used without a device for generating and processing hydrogen and oxygen from water. In this case, it is allowed to lower the water through the drainage device into the environment.

The camera itself is designed in the form of a horizontal or vertical cylinder with spherical ends, while blocks for receiving energy are mounted on the wall of such a cylinder.

Claims (14)

1. An energy conversion device with a chamber, a supply system equipped with at least one valve for sequentially supplying hydrogen and oxygen to the chamber, an ignition system for ignition and ignition, which leads to an increase in pressure and movement of water in the chamber,
characterized by:
a bypass valve, which is used exclusively to drain the water generated during the combustion process, and is the only outlet in the chamber, so that the chamber forms a closed system; and
energy-receiving elements for receiving movement and pressure in a liquid medium, which are built into the chamber. 2. The device according to claim 1, characterized in that the energy-receiving elements include pistons located in the cylinders, while these pistons are connected to blocks that convert mechanical motion into electrical energy. 3. The device according to claim 1, characterized in that the energy-receiving elements include pistons located in the cylinders, while these pistons are connected to blocks that convert mechanical motion into hydraulic pressure. 4. The device according to claim 1, characterized in that the supply system includes at least two adjustable valves for sequential and separate supply of oxygen and hydrogen, respectively, into the cavity containing no liquid, and the ignition system, which includes a unit for sequential ignition controlled by two valves. 5. The device according to claim 1, characterized in that it further includes an elastic membrane that transfers pressure and movement between the first and second sections filled with liquids. 6. The device according to claim 5, characterized in that the energy-receiving elements include pistons located in the cylinders, while the pistons are connected to a system that holds the pistons in a resting position; and also, the energy conversion device has a characteristic frequency of fluid motion, consistent with the sequence of gas supply and ignition. 7. The device according to claim 1, characterized in that the camera is formed in an almost horizontal cylinder with spherical ends, with most of the energy-receiving elements located along such a cylinder. 8. The device according to claim 1, characterized in that it also includes a safety valve, ensuring that the pressure in the chamber does not exceed pre-set values. 9. The device according to claim 1, characterized in that the ignition system includes plasma electrodes that feed the plasma into the high voltage plasma field. 10. A method of using a device for converting the energy of combustion of hydrogen and oxygen in a chamber equipped with a supply system and at least one valve for sequentially injecting hydrogen and oxygen into the chamber and the ignition system to ignite and initiate combustion aimed at increasing pressure and movement in the water in the chamber, comprising the following steps:
- injection of water into the chamber;
- the supply of hydrogen and oxygen in a predominantly stoichiometric ratio through at least one valve, so that a cavity is formed in the chamber, filled with gas and without liquid;
- ignition of gas in the cavity filled with gas, using the ignition system, thereby forming an increase in pressure and movement of water in the chamber;
- adoption of the increase in pressure and movement in the water in the chamber to the energy-receiving elements built into the chamber; and
- drainage of water generated during the combustion process using an overflow valve. 11. The method according to claim 10, further comprising returning the discharged water to the working unit, for splitting the water into hydrogen and oxygen, thereby forming a completely sealed system. 12. The method according to claim 10 or 11, further comprising supplying any volume of H ₂ to the chamber so that excess H _{2 is} formed in the chamber to thermally isolate the ignition system and the supply system, as well as to reduce heat loss during expansion. 13. The method according to claim 10 or 11, further comprising monitoring a portion of H ₂ that is not involved in the combustion process; and replenishment of H ₂ during operation to achieve the set parameters. 14. A system with an energy conversion device equipped with a chamber and a delivery system with at least one valve for sequentially supplying hydrogen and oxygen to the chamber, as well as an ignition system for igniting and burning a mixture of gases in order to increase the pressure and movement in the water in the chamber,
characterized by:
- a bypass valve used exclusively to drain the water formed during the combustion process, which is the only outlet in the chamber, so that the chamber forms a closed system;
- energy-receiving elements for receiving movement and pressure in a liquid medium, which are built into the chamber;
- the specified bypass valve is connected to the working unit for splitting water into hydrogen and carbon, thereby forming a completely sealed circuit.

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