ES1289140U - Hydrogen generation system from water for maximum use of energy and economic production potential in companies (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Hydrogen generation system, for maximum harvesting of damaged energy, comprising means for generating hydrogen (200) comprising: - an electrolyser (101), configured to perform the water electrolysis previously conditioned and obtain hydrogen and oxygen. - A water conditioning system (102) configured for the conditioning of the water provided to the electrolyzer (101). Means for conditioning hydrogen (400) containing: - A hydrogen dryer (410). - A hydrogen compressor (402) configured to condition hydrogen until the operating pressure of the destination application. - A water content monitoring system (412). - A monitoring system of oxygen content (411). -Control valves (401, 413, 414, 106, 107, 108, 109). Means for the generation of energy in the form of heat (300). Means for the storage of hydrogen (105). Means for the delivery of hydrogen (600). (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

Hydrogen generation system from water for maximum use of the energy and economic production potential in companies

Object of the invention

The object of the present invention is a hydrogen generation and conditioning system for its storage, distribution and/or delivery at a recharging point which, coupled to a hydroelectric plant, allows the maximum use of its energy potential.

Background of the invention

The effects of climate change on the environment and indirectly on the health and well-being of people are undeniable. For this reason, there is an effort to reduce greenhouse gas emissions, which has caused electricity from renewable sources to become an element of vital importance. However, it is clear that transport and industry will continue to need fuel for many purposes.

The energy system used to date requires an imminent reform based on three basic pillars, which are economic, environmental and social welfare. Renewable energies are presented as the necessary key to opening up to a new model, since their use brings benefits at an economic level, due to the reduction in spending on fossil fuel imports. Likewise, from an environmental point of view, these are energies that do not generate greenhouse gas emissions, so their use will facilitate the achievement of the zero emission objectives established by the European Union for 2050, tending to slow down the notorious effects of climate change. Finally, they generate an increase in well-being in the health of the population as a result of the reduction of polluting emissions into the atmosphere and foster the creation of quality jobs.

Despite its advantages, the intermittency of renewable energies continues to be one of the limitations that justifies their not yet covering a much higher percentage of the total energy demand. Therefore, proposals capable of making the most of all the renewable potential are of vital importance to achieve the change in the energy model that our society and environment need and demand imminently.

In the race to promote renewable energies, which marks the path of the energy transition and decarbonisation, hydroelectric plants are the great forgotten, surely due to the high investments required for their start-up. Hence, achieving the highest production efficiency of the existing ones favors their economic performance and contributes to increasing the percentage of electricity demand that is covered day by day by clean energy.

Like the rest of renewable energies, the effects of climate change leave their mark on the operation of hydroelectric power plants. Drought periods do not allow the necessary levels of electricity production to be obtained; as well as during intervals of abundant rains, there is no maximum use of all the energy potential.

Therefore, it is essential to find a connecting factor that allows the new highly variable climate situation to be combined with the demand for greater production of clean energy. In this way, to solve the intrinsic variability of renewable sources and the need to continue having a fuel, hydrogen is presented as the best candidate allowing the development of innovative value chains.

The invention that is presented aims to be the facilitating system that allows the maximum energy potential of a hydraulic power plant to be available.

Under its design conditions, each dam efficiently generates hydropower when its water level is within a defined range. If the upper level established is exceeded, it becomes necessary to release the excess volume by opening gates. This relief system, vital to maintain the efficiency, safety and integrity of the dam, leads to the loss of energy potential from a not inconsiderable flow of water.

If, on the other hand, the level is below the minimum level, the volume of water will not be sufficient for the efficient operation of the turbine system, so that, in this case, the energy production would be zero.

In the situation that is presented, according to the episodes derived from climate change, it is estimated that periods of drought or abundant rains will be more and more frequent, so maintaining the optimal level of operation of any dam and combining this fact with the Satisfying a growing energy demand will become more and more complicated. Whatever the situation, be it an excessive or deficient level of water in the dam, the production of hydrogen is possible, which can be stored, distributed and/or delivered to recharging points for those applications that use it as the main energy source. and/or combined with other elements, for example, the delivery of hydrogen in refueling stations (HRS) for the refueling of vehicles powered by fuel cells (FCV).

Description of the invention

The present invention relates to a hydrogen generation system for maximum use of energy in dams. The system focuses on the use of certain flows of water from the dam by dissociating it into hydrogen. This gas is then conditioned for sale, through storage and/or distribution either in tanks or by pipeline.

In this way, the present invention consists of a system, which can be portable, that uses water from the dam, preferably, but not limited to, the relief water or inefficient flows to be turbined in it, to be dissociated into its component gases. This allows the energy use of a flow that until now was released without obtaining any energy benefit from it or that was not enough to generate energy. The generated hydrogen is stored, distributed in containers, channeled, and/or delivered to a recharging station for subsequent sale, either for use as base fuel, a component of another fuel, or reaction gas.

It is important to note that the commercialization of this new non-polluting fuel allows the opening of a new line of operation, creating a business network around hydrogen that can generate not only economic benefits but also new jobs and a facilitating path towards a more sustainable economy. .

On the other hand, the portability characteristic of our invention makes it possible to quickly install and uninstall it, allowing it to be moved to different renewable sites, to achieve the maximum return on investment.

Description of the drawings

In order to achieve a clearer and more detailed understanding of the invention, its description is accompanied by a series of figures.

In this way, Figure 1 presents a general scheme of the integration of the system in a dam for the integral use of the energy potential. Its component elements are described in detail in Figure 2, Figure 3, Figure 4, Figure 5 and Figure 6.

Figure 2 shows the scheme of the thread by which the generation of hydrogen from water takes place. Likewise, Figure 3 shows the scheme associated with the optional thread, which makes it possible to have a heat supply in the dependencies of the hydraulic power plant itself or third parties.

Next, Figure 4 shows the scheme of the sub-process in which the generated hydrogen is stored, distributed and/or sent to the refueling point.

Next, Figures 5 and Figure 6 show schemes associated with the optional sub-process of our invention, which consists of the hydrogen supply station that allows having a recharge point for this gas for its commercialization.

Preferred embodiment of the invention

In general, the present invention consists of a system designed in a modular and portable way, which will be integrated into the hydraulic power plant for the profitable use of water in conditions of excess or lack of its level, preferably ( Figure 1 ). Thus, the water enters the system from an ecological flow (107) or from a turbine (108), where it is conditioned (102) and dissociated (200) to extract hydrogen, which after its corresponding conditioning (106) is conducted to the recharging point (103), it is distributed (104) and/or stored (105) for later use (600).

To cover each of the points mentioned above, our invention has three main threads:

1- Hydrogen production

2- Conditioning of the generated hydrogen

3- Hydrogen delivery system

1. First thread: Hydrogen production

The first thread of our invention consists of obtaining hydrogen ( Figure 2 ). To do this, the water from the dam enters the system through a valve (201). Using a conditioning equipment (102) it is achieved that it has the requirements necessary for, after its passage controlled by another valve (203), to enter the electrolyser (101) where it dissociates into its component gases, hydrogen and oxygen.

The energy necessary for the hydrolysis reaction of the water to take place is extracted from the plant itself or can be obtained, optionally, by coupling one or several turbines with lower powers than those of the main installation.

Optionally, the generated oxygen can pass through a valve (205) to a compressor (206) to be compressed and stored for later sale for tertiary uses.

During the hydrogen generation reaction from the electrolysis of water, heat is released into the environment, which, optionally, through a channeled circuit preferably with water, can be used for use as heat in the facilities themselves or in those of third parties. To do this, as shown in Figure 3 , the water flows through the circuit driven by a pump (302) and its flow is controlled by valves (301 and 303). An arrangement composed of two heat exchangers (304 and 305) are used to adsorb the thermal energy released in the electrolyzer (101) and make it reach the terminal point.

2. Second thread: Hydrogen conditioning

At the outlet of the electrolyser ( Figure 4 ), controlled by the valve (401), the hydrogen is conditioned for later use. For this, optionally, it can be compressed by using a compressor (402), at the required pressure, for storage in external containers at the necessary pressure (105), distribution (104) and/or delivery, either channeled, at the recharging point (103); all controlled by valves (106, 107, 108 and 109). Optionally, the system can have a hydrogen dryer (410), and a monitoring system for the content of water (412) and oxygen (411), which is accessed by activating the metering valve (414). ; as well as a relief system in case the hydrogen produced does not have the necessary quality for the specific use to which its production is dedicated, activated by means of the vent valve (413).

3. Third Thread: Hydrogen Delivery System

As mentioned, hydrogen can be marketed at a refueling point for this fuel or incorporated into other fuels through a mixing process. It may be owned by the hydroelectric plant or it may belong to a third party whom the plant decides to supply. Figure 5 develops the scheme that corresponds to this optional element. The hydrogen that enters the system is compressed using the compressor (503), up to the operating pressure of the destination application, for example 700 bars for light vehicles equipped with FCV technology. In a preferred embodiment, the hydrogen can be analyzed in order to guarantee that it complies with the ISO 14687-2 standard in terms of contaminants. In a preferred embodiment, the hydrogen is cooled by means of a piping system (505 and 509) and a heat exchanger (504), for its subsequent exit from the system (506). Optionally, within the refrigeration it is possible to comply with the SAE J2601 protocol.

The entry of hydrogen into the compressor, if necessary due to process conditions (503, optionally 402 can be used), takes place from the entry point (501), through a valve (502). A system composed of a valve (507), a reducing valve (508), a water particle meter-transmitter (514), an oxygen molecule meter-transmitter (510) and a sampling outlet point (511) , which are used to monitor the quality of the gas that enters. In addition, the device has a point of inert gas inlet (512) and a valve (513) to carry out the prior inertization necessary to carry out maintenance tasks.

The hydrogen may not need to go through the compressor (503 / 402), instead passing directly through valve 515. Once compressed, the hydrogen travels from the entry point (506) to a monitoring system for delivery. at the terminal point, which has the necessary instruments to control and ensure the correct execution and supply of hydrogen in safe conditions. Optionally, the system can comply with the ISO 19880-1 standard, so it must include a temperature transmitter-meter (601), a pressure transmitter-meter (602), a flow meter (603), a breakaway device (604) that contains a particle filter (605) and a mechanical decoupling system (606), in case the fuel dispenser hose (607) is connected to the vehicle and it starts running ( Figure 6 ).

Claims (5)

1. Hydrogen generation system, for maximum use of energy in dams, comprising means for generating hydrogen (200) comprising: - an electrolyser (101), configured to carry out the electrolysis of previously conditioned water and obtain hydrogen and oxygen. - a water conditioning system (102) configured for conditioning the water supplied to the electrolyser (101). Hydrogen conditioning media (400) containing: - a hydrogen dryer (410). - a hydrogen compressor (402) configured to condition hydrogen up to the operating pressure of the destination application. - a water content monitoring system (412). - an oxygen content monitoring system (411). - control valves (401, 413, 414, 106, 107, 108, 109). means for generating energy in the form of heat (300). means for hydrogen storage (105). means for delivering hydrogen (600). 2. Hydrogen generation system, for maximum use of energy in dams, comprising means for generating energy in the form of heat (300) according to claim 1, containing a cooling circuit, preferably by water , associated with the electrolyser (101) comprising: - a water pump (302). - a heat exchanger (305) configured to release heat from the electrolyser. - a heat exchanger (304) configured as a terminal point of heat extraction for external consumers. - control valves (301, 303). 3. Hydrogen generation system, for maximum use of energy in dams, comprising means for storage according to claim 1, comprising: - the hydrogen generation system according to claim 1; Y - a system of tanks (105) for the storage of pressurized hydrogen at a pressure P. 4. Hydrogen generation system, for maximum use of energy in dams, comprising means for delivering hydrogen according to claims 1 and 3, comprising a fuel recharge point containing: - a hydrogen compressor (503) that compresses this gas up to the operating pressure of the destination application. - optionally, a heat exchanger (504). - a meter-transmitter of oxygen molecules (509). - an oxygen sampling outlet point (511). - an inert gas entry point for maintenance tasks (512). - a relative humidity or dew point meter (514). - a temperature transmitter-meter (601). - a pressure gauge-transmitter (602). - a flow meter (603). - a breakaway device (604) comprising a particulate filter (605) and a mechanical decoupling system (607). - control valves (502, 507, 508, 513, 515). 5. Hydrogen generation system, for maximum use of energy in dams, comprising means for generating oxygen according to claim 1, comprising: - an oxygen compressor (206) configured to compress the oxygen obtained from the electrolyser (101). - optionally, a system of tanks for the storage of pressurized oxygen at a pressure P (105).