ES2370320B2 - HEATING SYSTEM WITH OXHYDRIC COMBUSTION CONCRETE CHAMBER. - Google Patents

Abstract

Heating system with waterproof chamber oxyhydrogen combustion.

Hydrogen technology is emerging as a of the energy sources of the future, however, currently is developing half, which is to use hydrogen to feed fuel cells, the other half, the own hydrogen combustion, has been forgotten after the patent of Stan Meyer

This invention corrects the fundamental problem of the combustion of hydrogen in the open air: the creation of acid nitric. Our heating system with waterproof chamber Oxyhydrogen combustion combustes hydrogen in a closed chamber to the atmosphere, which prevents the reaction of nitrogen atmospheric in contact with combustion, the cause of production of nitric acid.

Description

Heating system with waterproof chamber oxyhydrogen combustion.

Object of the invention

The object of the present invention is to a heating system with a sealed chamber for combustion of hydrogen with oxygen (oxyhydrogen).

Research on the technology of hydrogen focus on fuel cells abandoning the combustion of hydrogen. The improvement proposed by our invention, the waterproof camera avoids, one of the most problems Common in the combustion of hydrogen outdoors: the creation of nitric acid. The presence of nitrogen in the atmosphere is the cause that, when the temperature rises above 600ºC, the nitrogen present in the air becomes nitric acid and corrodes all metal elements present, for later be emitted into the atmosphere Said acid is recognized as harmful at environmental level due to its high corrosive power. For example, the Naval engines have a nitric acid production limit for Be homologated

The creation of a waterproof camera submerged in water within which the oxyhydrogen combustion occurs prevents the presence of nitrogen and, consequently, the creation of acid nitric.

The design is suitable for connecting to a Water electrolyzer that jointly generates the two gases: hydrogen and oxygen, whose design is simpler than those separate both gases and that avoids the risks of explosion of the two gases separately.

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Background of the invention

Decomposition has long been known of water in hydrogen and oxygen by electrolysis. Initially, it was thought to harness the explosive power of hydrogen with the engines Internal combustion

During the 60s, Stan Meyer a car that moved thanks to water electrolization and its subsequent combustion in A commercial vehicle with small transformations. The patent of Injector system for internal combustion engines was filed in the US on June 28, 1983, and registered with the number 4,389,981.

Prototypes designed in the wake of such an invention they suffered the following inconveniences:

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Corrosion due to the presence of acid nitric.

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Lack of refrigeration given the high temperatures that reached the Oxyhydrogen reaction to fossil fuels for which They had been designed.

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Abnormal wear by the older explosive capacity of hydrogen.

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After the problems suffered, the invention remained Forgotten and until today research on the hydrogen consumption within fuel cells to power electric motors, which implies a loss of energy, both in the fuel cell and in the engine electric.

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Description of the invention

The waterproof oxy-combustion chamber is designed to take advantage of the heat capacity of combustion of hydrogen in the presence of oxygen, avoiding the presence of air atmospheric. It is a compact, economical and easy to use design.

It consists of six distinct parts:

one)

Heater tank filled with liquid heat exchanger for heating which access two tubes, one of the liquid inlet from the circuit heating and one output to the heating circuit. Internally, the heating circuit inputs (6) can be joined by a coil to improve heat exchange. This movement has to be driven by a bomb.

2)

Watertight Oxy Combustion Chamber, within which combustion occurs. The camera must be open at the bottom, submerged below in the water, so that combustion does not come into contact with air atmospheric. This tank must be specially reinforced to Withstand the working temperature.

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3)

Oxyhydrogen gas burner: Shaped conventional burner, must be made of a material temperature resistant. Burners that work in the air free must be platinum or a material that withstands corrosion of nitric acid, but in our case, as we avoid the presence of such acid, a larger range of metals can be used. Further, must have security features that prevent the flame exit the system, such as non-return valves, flame arrester (blackflush arrestor).

4)

Cuba water storage, whose function is to maintain a water level enough to prevent atmospheric air from entering the waterproof chamber and allow to eliminate the surpluses of generated water by oxyhydrogen combustion. However, one liter of distilled water it can generate more than 1200 m3 of hydrogen, with which the generation of water will be virtually invaluable. Can also go producing evaporations by the temperature of the water obtained after combustion, so you have to maintain the level with a overflow and a tank of distilled water.

5)

Igniter circuit, whose function consists in igniting the flame that will later burn the hydrogen gas. He ignitor can, for example be by voltaic arc, usual in gas boilers

6)

Heating circuit, which will be the final consumer of the heat generated by the system, for example a heating system or domestic hot water (ACS).

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As security elements, we will incorporate a thermostat inside the chamber to check that the system works at working temperature. If it falls, it can mean that it He extinguished the flame and the gas passage must be closed. This mechanism of protection is necessary to detect that it is being consumed suitably the hydrogen gas.

It is necessary to minimize losses of Oxyhydrogen gas, because in closed spaces they could exist accumulations and possible explosions. In open spaces, the hydrogen rises rapidly and reacts with other components of the atmosphere losing its explosive capacity, therefore, no there would be inconvenience in hydrogen leaks caused by vehicles. We must remember that the explosion and subsequent fire of the German airship Hinderburg was caused by hydrogen that contained

Another thermostat closes the gas passage if the chamber and / or heat exchanger liquid reach a higher temperature than work. Liquid sensors control the presence of adequate levels of liquid exchanger heat and water in the tank and in the tank.

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Function Description

The process starts when the arc is lit voltaic at the burner outlet. Subsequently, gas is introduced Oxyhydric and it is detected if the flame ignited. If not, it will try to start combustion on other occasions, than not achieved in a reasonable time the boiler will stop and will be given message to notify the technical service.

If the flame is ignited, the sensor temperature detects an increase of it until reaching the optimum working temperature, after which the arc is cut voltaic ignitor, for maintaining combustion without the need for ignition. The flow of hydrogen gas is regulated at the time of commissioning to ensure an optimum performance level of form that remains constant while caloric needs of the system are maintained and turned off if it is not necessary to provide more hot.

Inside the chamber (2), the hydrogen gas is ignites with combustion and the temperature present, generating heat. The flame of hydrogen combustion is colorless, so no We can use flame presence sensors by light.

The chemical reaction generates water, initially in gaseous state but little by little, the concentration of water molecules inside the chamber and will precipitate in shape liquid to the water storage tank (4). For this reason, this tank must have a device that allows to get rid of excess or overflow water.

The small amount of atmospheric air that remains inside the chamber when it closes contains a Nitrogen concentration that will generate nitric acid. This acid is dissolves in the water of the water storage tank (4), so which poses no problems.

Normally, the system keeps running until reaching the desired temperature within the system heating. Eventually, you can stop because some of the Parameters escapes the specified level. Caution is vital. in the design of this system because hydrogen is the most flammable of those known.

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Brief description of the drawings

For the best understanding of how much is left described herein is attached a drawing (figure 1) in which, just as an example, represents a case study of construction of the sealed chamber of hydrogen gas for heating.

The drawing reflects a longitudinal section of the different components of the chamber heating system Watertight oxyhydrogen gas in which you can see the different cavities and parts that compose it.

Note the hole that allows to eliminate excess water in the water storage tank (4), if well these excesses will require prolonged periods of functioning. This water may contain small concentrations. of nitric acid at the beginning of its operation. Later, This water is practically pure. The water generated by the cells of International Space Station fuel (ISS) is what The astronauts drink.

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Description of a preferred embodiment

We consider the realization with steel sufficient quality stainless steel, although other metals can be used similar.

The heater tank (1) filled with liquid heat exchanger can contain in a coil of a heat resistant material, over time and with good conductive characteristics of temperature. Said design avoids the liquid contact used in the heating circuit (6) (for example, water in a domestic hot water system) with the heat exchanger liquid The largest surface of the coil Improves heat exchange.

The camera must be open on the side lower, partially submerged in water, so that no come into contact with atmospheric air and collect the water that is it is generating in the combustion of the oxyhydrogen gas. In this way get the water is not stored irremissibly in the part get off the camera. Once the water level reaches the drain, It can be reused to regenerate hydrogen gas. That cuba must be specially reinforced to withstand the temperature of work, although being in contact with the exchange fluid It prevents it from reaching very high temperatures. This system is more Efficient than using a simple coil. The waterproof camera (2) must be specially designed to withstand high temperatures You should keep the electrodes of the ignitor system on position to get a voltaic arc that ignites the flame. Is it is necessary that the elements that hold the electrodes support high temperatures and be electrical insulators, because the arc voltaic must pass over the burner (3). You can go screwed with an insulating material to a base on which let's put the burner (3). In turn, there must be sensors temperature as flame detectors (control the temperature decrease below working temperature) and control of the temperature reached inside the chamber (control temperature increases above temperature of work). The sealed chamber closed below with water separates the combustion receptacle with atmospheric air, avoiding creation of nitric acid as well as pressure increases that They could trigger an explosion.

The burner (3) of hydrogen gas must consist of with several holes to get a uniform flame that allows adequate heat distribution over the entire lower surface of the heater tank (1). It will have a burner shape conventional, must be made of a material resistant to temperature. Oxyhydric burners that work outdoors they must be made of platinum or a material that can withstand the corrosion of nitric acid, but in our case, as we avoid the presence of such acid, a larger range of metals can be used. In addition, you must have security elements that prevent the flame from leaving the system, such as check valves, flame arresters (blackflush arrestor).

The water storage tank (4), whose function is to maintain a sufficient water level to prevent between atmospheric air inside the waterproof chamber and allow eliminate water leftovers generated by oxyhydrogen combustion for which it will be necessary to maintain the level with an overflow as well as a tank of distilled water to supply in the case of possible evaporations

Igniter circuit (5), whose function consists of ignite the flame that will later burn the oxyhydrogen gas. He ignitor can, for example be a high voltage transformer similar to those used to ignite boilers conventional gas.

Heating circuit (6), must be designed taking into account the characteristics of the premises or housing to heater (radiators, underfloor heating, fan coils) and peculiarities of this heating system described here.

Claims (4)

1. Heating system with waterproof chamber closed below with hydrogen peroxide combustion water comprising: A heater tank (1) of the heat exchanger liquid heating circuit (6), which consumes the heat generated by the heating system. A sealed chamber (2) where the combustion between oxygen and hydrogen that is partially submerged in the water contained in the storage tank (4), avoiding contact with atmospheric air, and serving to collect the water generated in combustion. An oxidic gas burner (3) which is housed inside the chamber consisting of security elements that prevent the flame from leaving the system and an igniter circuit (5) that generates the flame in the chamber. 2. Heating system with waterproof chamber oxyhydrogen combustion according to claim 1, wherein the water generated in combustion is reused as a source for electrolysis generation of the oxyhydrogen mixture. 3. Heating system with an oxidic combustion chamber, according to claim 1, characterized by having passive safety measures, such as check valves, flame arresters (blackflush arrests) and active safety measures such as automated stop systems due to excess or defective temperature in the watertight chamber. 4. Heating system with an oxidic combustion chamber, according to claim 1, characterized by having operating level indicators such as thermostats and liquid level detectors.