CN209804809U - Power station system based on solid hydrogen technology - Google Patents

Abstract

The utility model discloses a power station system based on solid hydrogen technique, include: the solid hydrogen generating device comprises a parallel type hydrogen generating device, a water pump, solid hydrogen, a pressure detector, a temperature detector and a water circulation cooling system; a fuel cell device for generating electricity includes a series fuel cell stack, an air compressor, a cooling system, and a hydrogen circulation system. According to the utility model discloses, the solid hydrogen power station is an environment-friendly power generation facility, its final product is water, heat energy and electric energy, good environmental development sustainability has, resource utilization and safety controllability, operation security and economic benefits, through the production of electricity generation central control system control electric energy source, be different from traditional hydrogen energy power station and lie in need not high-pressure hydrogen cylinder, conversion efficiency is far above traditional thermal power station, power generation facility is simple, the fuel cell device need not traditional hydrogen circulation system and humidification system.

Description

A Power Station System Based on Solid Hydrogen Technology

technical field

The utility model relates to the technical field of power generation systems, in particular to a power station system based on solid hydrogen technology.

Background technique

As of November 2018, my country's thermal power accounted for 72.9%, hydropower accounted for 16.9%, nuclear power accounted for 4.2%, and solar energy accounted for 1.3%. Among them, thermal power generates electricity by burning coal resources, and the cost of transportation and environmental pollution is relatively high. Hydropower is concentrated in the southwest region, and the loss and cost of power transportation are high; at present, hydrogen energy as a source of electric energy accounts for a small proportion, and the purity of hydrogen, the safety of high-voltage transmission and the cost seriously affect its further wide application; considering cost and environmental factors comprehensively, Resource allocation, population distribution, and economic development are different, which will inevitably lead to a gap in the demand for electricity in some areas. In remote areas or areas where natural disasters occur, clean and stable sources of electricity are necessary to ensure the economy and people's livelihood;

40239 Chinese Announcement No. 2013800326813 relates to a hydrogen generating device having a cylindrical storage chamber for storing a mixed powder of magnesium-based hydride powder and acid powder containing magnesium hydride as a main component, a water storage chamber for storing water, and a fuel cell. A water injection pipe led out from the water storage chamber is inserted into the storage chamber, and water is supplied from the water storage chamber to the storage chamber. When water is supplied to the storage chamber, the magnesium-based hydride powder is hydrolyzed as described in the chemical formula to generate hydrogen. The generated hydrogen is supplied to the fuel cell and used for power generation.

However, there are certain problems in the current power generation system. First, the existing power stations use non-renewable energy to generate energy, which consumes a lot of resources. Moreover, the cost of power generation is greatly increased due to non-renewable energy. Second, the use of non-renewable resources in existing power stations will also cause environmental pollution to a certain extent. Third, traditional hydrogen power stations require high-pressure hydrogen cylinders, which are complicated in installation and complicated in operation procedures.

In view of this, it is necessary to develop a power plant system based on solid hydrogen technology to solve the above problems.

Utility model content

Aiming at the deficiencies in the prior art, the purpose of this utility model is to provide a power station system based on solid hydrogen technology. The solid hydrogen power station is an environmentally friendly power generation device, and its final products are water, heat and Electric energy has good environmental development sustainability, resource utilization rate, safety controllability, operational safety and economic benefits. The generation of electric energy is controlled through the power generation center control system, which is different from traditional hydrogen energy power stations in that high-pressure hydrogen is not required. bottle, the conversion efficiency is much higher than the traditional thermal power station, the power generation device is simple, and the fuel cell device does not need the traditional hydrogen circulation system and humidification system. In order to achieve the above purpose and other advantages according to the utility model, a solid hydrogen based Power station systems of technology, including:

A solid hydrogen generating device for producing hydrogen, the solid hydrogen generating device includes a parallel hydrogen generating device connected in parallel with a water pump, solid hydrogen, pressure detectors, temperature detectors and a water circulation cooling system ;

A fuel cell device for power generation, the fuel cell device includes a serial fuel cell stack, and an air compressor, a cooling system, and a hydrogen circulation system are connected in parallel with the serial fuel cell stack,

Wherein, the parallel hydrogen generating device comprises a plurality of hydrogen generating cabins, and the parallel hydrogen generating device is provided with a centralized pipeline, each of the hydrogen generating cabins is connected to the centralized pipeline in parallel, and each of the hydrogen generating cabins has a pressure The detector, the temperature detector, and the parallel hydrogen generating device are connected to the serial fuel cell group through a pipeline equipped with a humidity detector.

Preferably, the parallel hydrogen generating device is connected to the water pump through a pipeline equipped with a water valve, and the parallel hydrogen generating device is connected in parallel with solid hydrogen and a water circulation cooling system.

Preferably, a hydrogen inlet and a hydrogen outlet are provided at the top of the tandem fuel cell stack, one end of the hydrogen circulation system is connected to the hydrogen inlet, and the other end is connected to the hydrogen outlet, and a hydrogen detector is installed in the hydrogen circulation system.

Preferably, the serial fuel cell stack has a plurality of small fuel cell stacks, and the small fuel cell stacks are connected to the current rectifying device in series.

Preferably, the current rectifying device includes a DC/DC, an inverter and a transformer.

Preferably, the DC/DC is connected to the electric vehicle, the inverter is connected to civil and industrial use, the transformer is connected to the inverter through an electrical connection, and the transformer is connected to a long-distance power supply.

Preferably, a control system is also included, and the control system is connected with a pressure detector, a temperature detector, a humidity detector, the hydrogen detector and the water valve.

Compared with the prior art, the utility model has the beneficial effects that the solid hydrogen power station is an environment-friendly power generation device, and its final products are water, heat energy and electric energy, and has good environmental development sustainability and resource utilization rate As well as safety controllability, operational safety and economic benefits, the generation of electric energy is controlled through the power generation center control system, which is different from traditional hydrogen energy power stations in that no high-pressure hydrogen cylinders are required, and the conversion efficiency is much higher than that of traditional thermal power stations. The device is simple, and the fuel cell device does not need the traditional hydrogen circulation system and humidification system.

Description of drawings

Fig. 1 is the schematic flow diagram of the power station system based on solid hydrogen technology according to the utility model;

Fig. 2 is the principle schematic diagram of the power station system based on solid hydrogen technology according to the utility model;

Detailed ways

The utility model will be further described in detail below in conjunction with the accompanying drawings, and the aforementioned and other objectives, features, aspects and advantages of the utility model will become more obvious, so that those skilled in the art can implement it with reference to the description. In the drawings, the shapes and dimensions may be exaggerated for clarity, and the same reference numerals will be used throughout to designate the same or like parts. In the following description, terms such as center, thickness, height, length, front, back, rear, left, right, top, bottom, upper, lower, etc. are based on the orientation or positional relationship shown in the drawings. In particular, "height" corresponds to the dimension from top to bottom, "width" corresponds to the dimension from left to right, and "depth" corresponds to the dimension from front to back. These relative terms are for convenience of description and are generally not intended to require a specific orientation. Terms referring to attachment, coupling, etc. (e.g., "connected" and "attached") refer to a fixed or attached relationship, as well as a movable or rigid attachment or relationship, of structures to one another, directly or indirectly through intermediate structures, unless otherwise stated in The other way is clearly stated.

Referring to Figure 1-2, the power station system based on solid hydrogen technology includes:

A solid hydrogen generating device for producing hydrogen, the solid hydrogen generating device comprising a parallel hydrogen generating device 1, a water pump 5, solid hydrogen 6, a pressure detector 4, a temperature detector 7 and a water circulation cooling system 3;

A fuel cell device for power generation, the fuel cell device includes a serial fuel cell stack 2, an air compressor 10, a cooling system 9 and a hydrogen circulation system 8,

Wherein, the parallel hydrogen generating device 1 comprises a plurality of hydrogen generator cabins, each of the hydrogen generator cabins is centrally connected to a large-diameter pipeline through a pipeline, and each of the hydrogen generator cabins is equipped with a pressure detector 4 and a temperature detector 7 , the parallel hydrogen generating device 1 is connected to the serial fuel cell stack 2 through a pipeline equipped with a humidity detector 14, and the parallel solid hydrogen generating device 1, each hydrogen generating cabin operates independently, and is concentrated in the large-diameter tube through the pipeline. There will be no interference between each other, and when a certain device fails, the entire system can operate normally.

Further, the parallel hydrogen generator 1 is connected to the water pump 5 through a pipeline equipped with a water valve, and the parallel hydrogen generator 1 is connected to the solid hydrogen 6 and the water circulation cooling system 3 in sequence through the pipeline.

Further, the internal top of the serial fuel cell stack 2 is equipped with a hydrogen inlet and a hydrogen outlet, one end of the hydrogen circulation system 8 is connected to the hydrogen inlet, and the other end is connected to the hydrogen outlet, and the hydrogen circulation system 8 is equipped with a hydrogen detection device. The hydrogen humidity detector monitors the water vapor content in the hydrogen released in the cabin in real time, feeds back the information to the control system, adjusts the water pump, etc., to ensure that the hydrogen humidity generated in each cabin is within a constant range.

Further, the tandem fuel cell group 2 has a plurality of small fuel cell groups, and the small fuel cell groups are connected to the current rectifying device in series, and the tandem fuel cell group 2 can convert the current generated by each small cell group The current is integrated, and the small current is transformed into a large current.

The cooling system cools down the fuel cell in real time to ensure the safety of the fuel cell operation. The hydrogen detector monitors the hydrogen content in the gas outlet of the fuel cell in real time and feeds back the signal to the controller of the hydrogen generation device to adjust the hydrogen output to ensure There is basically no hydrogen flow out at the gas outlet of the fuel cell, so that the overall working efficiency is guaranteed and excessive waste of resources will not be caused.

Further, the current rectifying device includes a DC/DC 11 , an inverter 12 and a transformer 13 .

Further, the DC/DC11 is connected to the electric vehicle, and the DCDC11 can convert the collected current into a voltage value, so that the voltage is suitable for electric vehicles and other products that require DC power. The inverter 12 is connected to civil and industrial applications, and the transformer 13 passes through The electrical connection is connected to the inverter 12, and the transformer 13 is connected to the remote power supply.

Further, a control system is also included, and the control system is connected with a pressure detector 4, a temperature detector 7, a humidity detector 14, the hydrogen detector and the water valve.

Solid hydrogen 6, that is, solid hydrogen 6 reacts with water to produce hydrogen gas. Solid hydrogen 6 and water pump 5 provide the water source required for the reaction, equipped with a water valve to control the water flow, equipped with a water circulation cooling system 3 to control the temperature value in the reaction chamber, equipped with a pressure sensor 4 to detect the pressure value in the reaction chamber, and equipped with gas humidity The monitor 7 monitors the humidity coefficient of the gas in the gas outlet, the control system monitors the pressure value in the reaction chamber to control the hydrogen production, and the control system controls the water circulation cooling system 3 by monitoring the temperature value in the reaction chamber and the humidity value in the gas outlet water flow in

The power station has a fuel cell device, which is composed of a large number of fuel cell groups connected in series, and a plurality of small battery groups jointly generate power to provide the required high voltage;

The small fuel cell group has an anode, a cathode, a catalyst, and a proton membrane; high-purity hydrogen with a certain humidity enters the fuel cell device through a pipeline and a pressure valve, and the hydrogen is decomposed into hydrogen protons and electrons by catalyst action on the anode of the battery , positively charged protons pass through the proton membrane to reach the cathode, and negatively charged electrons run in an external circuit to generate electricity; oxygen on the cathode reacts with electrons and hydrogen ions under the action of a catalyst to generate water. The chemical reaction principle is It is the reverse reaction of water electrolysis, anode H ₂ →2H ⁺ +2e ^- (cation), cathode 1/2O ₂ +2e ^- +2H ⁺ =H2O.

The power station has an inverter 12 and a transformer 13, which can convert the collected DC power into AC power through the inverter 12, convert it into 220V/380V/high voltage current through the transformer 13, and then merge it into the national grid for daily civilian use industrial current. The power station has a DC-DC11 device, which converts the collected high-voltage DC power into low-voltage DC to charge electric vehicles and other industrial products that require low-voltage DC.

The number of devices and the scale of processing described here are used to simplify the description of the present invention. Applications, modifications and variations of the present invention will be apparent to those skilled in the art.

Although the embodiment of the utility model has been disclosed as above, it is not limited to the use listed in the specification and implementation, it can be applied to various fields suitable for the utility model, and for those familiar with the art, it can be Further modifications can readily be effected, so the invention is not limited to the specific details and examples shown and described herein without departing from the general concept defined by the claims and their equivalents.

Claims (7)

1. A power plant system based on solid hydrogen technology, comprising:

The solid hydrogen generating device comprises a parallel type hydrogen generating device (1), and a water pump (5), solid hydrogen (6), a pressure detector (4), a temperature detector (7) and a water circulating cooling system (3) are communicated with the parallel type hydrogen generating device (1) in parallel; and

A fuel cell device for generating electricity comprises a serial fuel cell set (2), an air compressor (10), a cooling system (9) and a hydrogen circulating system (8) which are communicated with the serial fuel cell set (2) in parallel,

The parallel hydrogen generation device (1) comprises a plurality of hydrogen generation cabins, the parallel hydrogen generation device (1) is provided with a concentration pipeline, each hydrogen generation cabin is communicated with the concentration pipeline in a parallel mode, each hydrogen generation cabin is provided with a pressure detector (4) and a temperature detector (7), and the parallel hydrogen generation device (1) is connected to the serial fuel cell set (2) through a pipeline provided with a humidity detector (14).

2. the power plant system based on the solid hydrogen technology according to claim 1, characterized in that the parallel hydrogen generating device (1) is connected with the water pump (5) through a pipeline with a water valve, and the parallel hydrogen generating device (1) is communicated with the solid hydrogen (6) and the water circulation cooling system (3) in parallel.

3. The solid hydrogen technology-based power station system according to claim 2, wherein the tandem fuel cell stack (2) is provided with a hydrogen inlet and a hydrogen outlet at the top end inside, one end of the hydrogen circulation system (8) is connected to the hydrogen inlet, the other end is connected to the hydrogen outlet, and a hydrogen detector is arranged in the hydrogen circulation system (8).

4. A solid hydrogen technology based power plant system according to claim 1, characterized in that the tandem fuel cell stack (2) comprises a plurality of small fuel cell stacks which connect the current to the current rectifying means in series.

5. The solid hydrogen technology based power plant system according to claim 4, characterized in that the current rectifying means comprise a DC/DC (11), an inverter (12) and a transformer (13).

6. the solid hydrogen technology based power plant system according to claim 5, characterized in that the DC/DC (11) is connected to an electric vehicle, the inverter (12) is connected to civil and industrial use, the transformer (13) is connected to the inverter (12) by an electric connection, and the transformer (13) is connected to a remote supply.

7. the solid hydrogen technology-based power plant system according to claim 3, further comprising a control system, to which a pressure detector (4), a temperature detector (7), a humidity detector (14), the hydrogen detector and the water valve are connected.