RU103807U1 - SYSTEM FOR PRODUCING HEAT ENERGY - Google Patents

Abstract

1. A system for obtaining thermal energy, containing an electrolyzer made in the form of a container filled with water, a load in the form of a consumer of useful energy, control units made of semiconductor diodes, a hydraulic valve, a high-voltage unit, connecting elements and switches, high-voltage voltage is supplied to the polarizing solution electrodes , participating in electrolysis, characterized in that the electrolyzer is made in the form of an electrochemical activator with a water level regulator, in addition to In addition, the high-voltage unit is made according to the voltage multiplier circuit, with the parameters of the electrochemical activator: power 220 W and current 0.99 A, electrode area S = 18 · 10-3 m2. ! 2. A system for obtaining thermal energy, characterized in that the electrodes of the electrochemical activator are made in the form of coaxial cylinders.

Description

The technical solution relates to the field of energy generation and is intended for the production and use of thermal energy.

The creation and industrial development of a highly efficient technology for the electrolysis of the breakdown of water into hydrogen and oxygen is an urgent problem in modern energy.

There are a number of known methods of water decomposition: electrolytic splitting (electrolysis), high-temperature heat (thermolysis), radiation (photolysis and radiolysis), electropulse method (Zhukov VA “On the issue of using parametric resonance to generate fuel gas” // Vologda readings: materials of the scientific conference of the Far Eastern State Technical University. Section: electrical engineering, radio electronics. Vladivostok, - 2001. - 45 s). Any method that allows external energy to break the valence bond H = O = H is suitable for producing hydrogen from water. Extraction of hydrogen, which is a fuel gas, from water, followed by its flameless combustion, will allow to obtain thermal energy.

Known electrohydrogen generator (RF application No. 2009130354, for invention, priority date 08/10/2009), containing channels for supplying water and electrolysis products, an electrolyzer, electrodes, a heat exchanger and a mechanism that defines a whirlwind swirling motion of the electrolyte.

A disadvantage of the known hydrogen production device is its low productivity due to the lack of a highly efficient technology for the evaporation and splitting of liquid molecules, and explosion and fire safety are not ensured. In addition, this device is intended only for hydrogen production.

A device for producing hydrogen from water is known (RF patent No. 70895 for utility model), comprising a hollow chamber with water, electrodes placed in water, a high-voltage source of electricity, capillaries placed vertically in water, a voltage regulator.

A disadvantage of the known device for producing hydrogen is low productivity due to the lack of a highly efficient technology for the evaporation and splitting of liquid molecules, it does not provide explosion and fire safety. In addition, this device is intended only for hydrogen production.

A device for converting energy is known (RF patent No. 2344201 for an invention), comprising a container configured to rotate, electrodes and channels for supplying an aqueous electrolyte solution to the container and for removing electrolysis products.

A disadvantage of the known device is the complexity of the design of the electrodes, low productivity due to the lack of highly efficient technology for the splitting of liquid molecules. In addition, this device is intended only for receiving electric energy.

There is also known a system for generating energy (RF patent for utility model, H02J 15/00) containing an electrolyzer, a load in the form of an energy consumer, control units, for example from semiconductor diodes, a high-voltage unit, a hydraulic valve, switches and connectors. Electrolysis occurs when the voltage at the working electrodes of the electrolyzer is less than 1.23 V.

The disadvantages of the known system for energy include the fact that:

- the difficulty of regulating the performance of gas production;

- low efficiency;

- low productivity due to the lack of highly efficient technology for evaporation and splitting of liquid molecules;

- the electrolysis process is slowed down due to breaking intermolecular bonds, it is necessary to enter the resonance zone of molecular vibrations with their subsequent splitting, to spend more electrical energy.

The utility model is based on the task of developing a system for generating thermal energy during flameless combustion of fuel gas obtained from water, while reducing energy consumption.

The problem is solved in that the system uses electrokinetic evaporation (the use of the potential energy of the electric field of a low-power source of electric energy) to produce thermal energy and the breaking of water molecules into gas molecules occurs using the properties of parametric resonance created by a high-voltage power source with minimal consumption of electric current.

In a system for generating thermal energy containing an electrolyzer made in the form of a tank and filled with water, a load in the form of a consumer of useful energy, which is used as a tubular heat exchanger, control units, for example, from semiconductor diodes, a hydraulic valve, a high-voltage block, connecting elements and switches, high-voltage voltage is applied to the electrodes to conduct electrolysis polarizing the solution, the electrolyzer is made in the form of an electrochemical activator with a level regulator water. An electrokinetic evaporator, a parametric molecular resonator, a storage tank and a boiler (tubular heat exchanger) are connected to each other by means of connecting elements (pipelines) to produce thermal energy. The high-voltage block is made according to the scheme of the voltage multiplier. Parameters of the electrochemical activator: power 220 W and current 0.99 A, electrode area S = 18 · 10 ^-3 m ² .

In this case, the electrodes of the electrochemical activator are made in the form of coaxial cylinders, where the peripheral electrode (cathode) has a negative potential and the internal (anode) is respectively positive.

In the claimed thermal energy production system, the common essential features for it and for its prototype are:

- an electrolyzer in the form of a container and filled with water;

- load in the form of a consumer of useful energy;

- control units;

- high voltage block;

- connecting elements;

- switches;

- hydraulic valve;

- high voltage is applied to the solution polarizing electrodes involved in the electrolysis.

A comparative analysis of the essential features of the claimed system for generating thermal energy and the prototype shows that the first, unlike the prototype, has the following distinctive features:

- the electrolyzer is made in the form of an electrochemical activator with level control;

- electrokinetic evaporator;

- parametric molecular resonator;

- cumulative capacity;

- a boiler with a thermal bath;

- the high-voltage block is made according to the scheme of the voltage multiplier;

- parameters of the electrochemical activator: power 220 W and current 0.99 A, electrode area S = 18 · 10 ^-3 m ² .

This combination of common and distinctive essential features provides a technical result.

Based on the foregoing, it can be concluded that the set of essential features of the claimed utility model has a causal relationship with the achieved technical result, i.e. thanks to this combination of essential features of the invention, it has become possible to solve the problem.

Therefore, the claimed utility model is new and suitable for industrial use.

The utility model is illustrated in the drawing, which shows a block diagram of a system for generating thermal energy. It shows: an electrochemical activator (ECA) 1 with a water level 2 controller, an electrokinetic evaporator (ECI) 3, a voltage multiplier (high-voltage power supply) 4, a parametric molecular resonator (PMR) 5, a storage tank 6, a boiler 7 with a thermal bath 8, payload 9, hydraulic valves 10, 11 and 12, control unit 13 of semiconductor diodes, connecting elements 14-17.

In electrochemical activator 1, partial electrolysis is carried out due to stable resonant systems of “dipoles” of water (ions, molecules, OH - etc.). They are formed near the anode and cathode upon activation. A medium mainly consisting of oxygen ions will form near the anode, and mainly hydrogen ions near the cathode. To ensure electrochemical activation, an electrode system is used, where the anode and cathode groups are enclosed in semipermeable membranes. An ion pump operates in each of the capillaries with liquid under the action of an applied voltage, which raises a pole of a polarized and partially ionized field in a micron-sized capillary of water column from one potential of the electric field supplied to the water itself to the lower end of the capillary to the opposite electric potential, placed with clearance relative to the opposite end of this capillary. The source of electrical energy is rectified voltage. ECA parameters: power consumption P = U · I = 220 · 1 = 220 W .; current I = U · g = 0.99 A; g = 4.5 Ohm ^-1 cm ^-1 - electrical resistivity of tap water. Electrode material stainless steel. The area of the electrodes S = 18 · 10 ^-3 m ² . In the electrokinetic evaporator 2, the liquid aggregate state of water is converted into gas. Along the capillaries of the wick and the evaporator, under the action of the electrostatic forces of the longitudinal electric field, dipole polarized liquid molecules move from the capacitance (ECA) in the direction to the opposite electric potential of the electrode (electrocosm), these fields break away from the surface of the evaporator and turn into gas (fog), t .e. the liquid goes into another state of aggregation with minimal energy consumption of the electric field source, and the electroosmotic rise of the liquid begins along them. In the process of separation and collision of vaporized liquid molecules with air and ozone molecules, electrons in the ionization zone between the evaporator and the upper electrode, partial dissociation occurs with the formation of a combustible gas. The power source of the high voltage voltage is a voltage multiplier 4. The parameters of the power source: P = U · I = 15 · 10 ³ · 43 · 10 ^-3 = 650 watts. In the parametric molecular resonator 5, the molecules of the evaporated liquid dissociate, for example, water into hydrogen and oxygen molecules is effected by the force acting on them by an alternating electric field from the voltage multiplier 4. For each liquid in its vaporized state, there is a certain frequency of electric oscillations of this field and its intensity, in which the process occurs most intensively. As a source of alternating voltage, a sawtooth voltage generator (GLIN) with a voltage of U = 2 · 10 ³ V is used. Storage tank 6 is intended for accumulating combustible gases with subsequent supply to the heat bath 8, in which flameless combustion of hydrogen takes place. The performance of the system is regulated in the storage tank 6 by means of a device (not shown in the drawing) with a switching device included in the electric power circuit of the electrochemical activator 1. When a certain volume of gas is reached in the storage tank 6, the power is cut off.

The system for generating thermal energy is operated as follows. In the capacity of the electrochemical activator 1 through a hydraulic valve 10 controlled by a level 2 controller, pre-prepared water is supplied. Upon reaching 2/3 of the volume of the electrochemical activator 1, the water supply is shut off. Power is supplied to the electrochemical activator 1 through the control unit 13, and to the electrokinetic evaporator 3 through a voltage multiplier 4. Power is also supplied to the parametric molecular resonator 5. In the electrochemical activator 1 there is a separation of water molecules into hydrogen and oxygen. Through the connecting elements 14, the aqueous solution of the separated elements enters the electrokinetic evaporator 3, in which they transfer the liquid state of aggregation of water into gas. From the electrokinetic evaporator 3 through the connecting elements 15, the gas is supplied to the parametric molecular resonator 5. In the parametric molecular resonator 5, the molecules of the evaporated liquid dissociate. From the parametric molecular resonator 5, the gas through the connecting elements 16 to the storage tank 6. Then, through the connecting elements 17, the gas enters the heat bath 8, where it is flamelessly burned. Then, the combustion product through valves 11 and 12 enters the heat exchanger for the hot water system.

Claims (2)

1. System for generating thermal energy, containing an electrolyzer made in the form of a tank filled with water, a load in the form of a consumer of useful energy, control units from semiconductor diodes, a hydraulic valve, a high-voltage block, connecting elements and switches, a high-voltage voltage is applied to the solution polarizing electrodes participating in the electrolysis, characterized in that the electrolyzer is made in the form of an electrochemical activator with a water level regulator, additionally to the floor system Thermal energy exercises introduced an electrokinetic evaporator interconnected by means of connecting elements, a parametric molecular resonator, a storage tank and a boiler with a hot tub, in addition, the high-voltage unit is made according to the voltage multiplier scheme, while the parameters of the electrochemical activator are: power 220 W and current 0.99 A , the area of the electrodes S = 18 · 10 ^-3 m ² . 2. System for generating thermal energy, characterized in that the electrodes of the electrochemical activator are made in the form of coaxial cylinders.