1. A stable natural gas hydrogen loading control method is characterized by comprising the following steps:

firstly, delivering the hydrogen-doped natural gas of a natural gas valve station to downstream community users through a gas pipe network, wherein the gas pipe network is provided with a multi-stage pressure reducing valve;

step two, installing the solid fuel cell at a specific point of a downstream community user;

and step three, the hydrogen-doped natural gas firstly enters the solid fuel cell before entering the home, and the solid fuel cell generates electricity to enter the home.

2. The method for controlling stable loading of natural gas as claimed in claim 1, wherein in the first step, the pressure of the pressure reducing valve is controlled to be 0.5MPa-8 MPa.

3. The method for controlling stable loading of natural gas according to claim 1, wherein in the first step, the multistage pressure reducing valve is set in a manner that: the proportional pressure reducing valve and the stable pressure reducing valve are applied in series, firstly, the outlet pressure is proportionally adjusted according to the inlet pressure, and then the outlet pressure enters the stable pressure reducing valve to reduce the pressure to a set value.

4. The method for controlling stable hydrogen loading of natural gas as claimed in claim 1, wherein in the first step, the natural gas loading at the natural gas valve station can be from an upstream pipeline, or hydrogen can be loaded in situ at the valve station, the hydrogen content of the gas at the outlet of the natural gas valve station is 5% -20%, the hydrogen content entering the gas conveying pipeline is dynamically controlled by the natural gas content in the pipeline, and the hydrogen loading ratio is a rated value under the working condition.

5. The method for controlling stable loading of natural gas as claimed in claim 1, wherein in the first step, the gate station local loading device can control the amount of hydrogen blended into the gas pipeline according to the amount of natural gas entering the gas pipeline at the downstream by a built-in logic control system, and the natural gas and the hydrogen are uniformly mixed.

6. The method for controlling stable loading of natural gas according to claim 1, wherein in the first step, part of the aboveground gas pipelines are made of multiple materials in parallel.

7. The method for controlling stable hydrogen loading of natural gas as claimed in claim 1, wherein in the second step, the arrangement of the mounting points adopts a K-means algorithm for optimal arrangement, a star-branch combined distribution mode is adopted, and the mounting points adopt a one-use-one-standby mode for arranging the solid fuel cells.

8. The method for controlling stable loading of natural gas as claimed in claim 1, wherein in the third step, a flow follow-up pressure regulating valve is installed in front of the solid fuel cell, and the opening of the flow follow-up pressure regulating valve can be controlled according to the gas flow and the power generation capacity of the solid fuel cell.

9. Use of the method for controlling stable loading of natural gas according to any one of claims 1 to 8 in fuel cell charging piles.

10. Use of the method for controlling stable loading of natural gas according to any one of claims 1 to 8 in urban power supply.

Background

The information in this background section is only for enhancement of understanding of the general background of the invention and is not necessarily to be construed as an admission or any form of suggestion that this information forms the prior art that is already known to a person of ordinary skill in the art.

The hydrogen energy source is wide, clean, low-carbon, efficient and flexible, and plays a key role in promoting global energy transformation and realizing green sustainable development. The hydrogen transportation is an important link for hydrogen energy utilization, and the problem of long-distance transportation is widely concerned. At present, hydrogen is mainly conveyed by a high-pressure hydrogen bottle long-tube trailer, a liquid hydrogen tank truck, a liquid hydrogen barge and the like, but the methods have high storage and transportation efficiency and low efficiency, and the difficult problem of long-distance, large-scale and low-cost conveying of the hydrogen is difficult to solve. Therefore, under the condition that the existing hydrogen gas transmission and distribution infrastructure is still incomplete, the hydrogen gas is mixed with the natural gas in a certain proportion, and the mixed transmission of the hydrogen gas by utilizing the existing natural gas pipe network is a feasible mode for transition to the hydrogen energy source. In recent years, many domestic and foreign researchers have been studying how to mix natural gas and hydrogen in existing natural gas pipeline networks in service to reduce greenhouse gas emission and improve hydrogen delivery efficiency. According to research, the patents related to the hydrogen-doped natural gas pipeline transportation process at home and abroad at the present stage mainly include:

chinese patent CN111732077A discloses an energy-saving and high-efficiency utilization system for hydrogen production, which comprises a tank body, wherein a plurality of groups of heating pipes are arranged in the tank body, a water adding device is arranged on the tank body at one side of each heating pipe, one side of the water adding device is movably communicated with a water inlet, the water inlet is arranged on the side wall of the tank body, a heating device is arranged on the outer side wall of the tank body, a fixing plate is fixedly connected on the inner wall of the tank body above the water adding device, a plurality of groups of air outlet devices are clamped on the fixing plate in a sliding way, a plurality of groups of raw material treatment devices are arranged above the air outlet devices, so that the water adding work can be carried out without stopping equipment, the condition that the temperature is too low and the working efficiency and the effect are influenced due to the direct addition of cold water is avoided, the system is convenient for customers to use, the hydrogen raw material can be heated more uniformly and has better heat preservation effect, meanwhile, sufficient steam is ensured to react with the raw material, and the reaction efficiency is improved, the invention has the advantages of simple operation, strong inventiveness and convenient popularization and use.

Chinese patent CN111717889A discloses a portable hydrogen production device, relates to the hydrogen production technology, including reactor, purger, absorption filter, hydrogen bag and atomizer bottle, wherein reactor, purger, absorption filter, hydrogen bag and atomizer bottle all pass through the pipe connection the reactor is connected with first inlet tube be connected with on the atomizer bottle and connect and inhale the hydrogen pipe be provided with the valve on the first inlet tube pipeline and hydrogen bag between absorption filter and the hydrogen bag with pipeline between the atomizer bottle all is provided with the valve. The device disclosed by the invention can prepare clean hydrogen with humidity, and the quality of the hydrogen is ensured.

Chinese patent CN107314242A discloses a blending, transporting and separating device for hydrogen and natural gas, which comprises a conveying pipeline for conveying materials, wherein the conveying pipeline is provided with a hydrogen energy input port and a blending device for blending hydrogen energy and materials; the other end of the conveying pipeline is also provided with a separation and purification device for separating hydrogen energy, and the separation and purification device is provided with a hydrogen energy output port. The application provides a mixing transportation and separator of hydrogen natural gas reforms transform the pipeline of current material, establishes hydrogen energy input port and hydrogen energy delivery outlet through adding to through mixing and separating hydrogen energy and material in input and output process, realize the transport to realizing the hydrogen energy. The invention realizes a large amount of efficient and stable hydrogen energy transportation by utilizing the existing material conveying pipeline, can realize the most economic hydrogen energy transportation mode, and provides necessary support for the hydrogen energy application in urban areas.

The existing patent mostly adopts a hydrogen production device to produce, store and utilize hydrogen, mostly mixes and conveys hydrogen and natural gas and then separates the hydrogen and the natural gas, and has high cost and difficult popularization and application. Meanwhile, the density of hydrogen gas was 0.090Kg/Nm³The density of methane is 0.717Kg/Nm³The density difference between the two is very large, and the layering phenomenon is easy to generate, thereby influencing the utilization efficiency.

Therefore, the method for controlling stable hydrogen addition of the natural gas is provided, so that reasonable layout optimization is performed on hydrogen generation, mixing, conveying, utilization and the like, investment is reduced, safety risks are reduced, stable operation of a system is guaranteed, and feasibility of hydrogen utilization is improved, and the method has important significance.

Disclosure of Invention

Aiming at the technical problems in the prior art, the invention aims to provide a stable natural gas hydrogen-loading control method, which solves the problems of high difficulty, high cost and layering in hydrogen storage, transportation and utilization and increases the feasibility and the applicability of hydrogen utilization.

In order to solve the technical problems, the technical scheme of the invention is as follows:

in a first aspect of the invention, a method for controlling stable hydrogen loading of natural gas is provided, which comprises the following steps:

firstly, delivering the hydrogen-doped natural gas of a natural gas valve station to downstream community users through a gas pipe network, wherein the gas pipe network is provided with a multi-stage pressure reducing valve;

step two, installing the solid fuel cell at a specific point of a downstream community user;

and step three, the hydrogen-doped natural gas firstly enters the solid fuel cell before entering the home, and the solid fuel cell generates electricity to enter the home.

In a second aspect of the invention, the application of the method for controlling stable hydrogen loading of natural gas in the aspect of fuel cell charging piles is provided.

The third aspect of the invention provides the application of the natural gas stable hydrogen loading control method in the aspect of urban power supply.

Compared with the prior art, the beneficial technical effects of one or more of the embodiments of the invention are as follows:

(1) the stable natural gas hydrogen-loading control method provided by the invention adopts a distributed mode, solves the problem of utilization of hydrogen-loading natural gas pipeline transportation, has low cost and high safety, is beneficial to reducing carbon dioxide emission, and promotes the hydrogen energy industry. Meanwhile, the hydrogen-doped natural gas can be sent into the residential and domestic rooms after being sent into the solid fuel cell, and compared with the traditional mode that the hydrogen-doped natural gas is separated and then sent into residential users, the method not only saves the flow and reduces the cost, but also can improve the efficiency.

(2) The control method can be used for charging piles, is safe and reliable, and has a charging effect even superior to that of a mode of directly accessing a power grid in the prior art. Because can be independent of the electric wire netting, can supply the power demand in city at the peak period of power consumption, can also be applied to the charging of remote area, power supply operation demand.

(3) The multistage pressure reducing valve is arranged in the gas pipe network, so that the hydrogen-doped gas can stably flow in the pipeline without layering, and the multistage pressure reducing valve can be applied to various fields, expands the application field and improves the application flexibility.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this application, illustrate embodiments of the application and, together with the description, serve to explain the application and are not intended to limit the application.

Fig. 1 is a flow chart of a method for controlling stable loading of natural gas according to embodiment 1 of the present invention.

1. The natural gas valve station 2, the natural gas-doped natural gas 3, the natural gas-hydrogen mixing device 4, a gas conveying pipeline 5, a solid oxide fuel cell 6 and a resident user.

Detailed Description

It should be noted that the following detailed description is exemplary and is intended to provide further explanation of the disclosure. Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs.

It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of example embodiments according to the present application. As used herein, the singular forms "a", "an" and "the" are intended to include the plural forms as well, and it should be understood that when the terms "comprises" and/or "comprising" are used in this specification, they specify the presence of stated features, steps, operations, devices, components, and/or combinations thereof, unless the context clearly indicates otherwise.

As mentioned above, most of the existing mixed transportation of hydrogen and natural gas requires separation after mixing, which is high in cost, difficult to popularize and apply, and has layering phenomenon, thus affecting the utilization efficiency.

In view of the above, the invention designs a method for controlling stable hydrogen doping of natural gas, which solves the problems of high difficulty, high cost and layering of hydrogen storage, transportation and utilization, and increases the feasibility and applicability of hydrogen utilization.

In a first aspect of the invention, a method for controlling stable hydrogen loading of natural gas is provided, which comprises the following steps:

firstly, delivering the hydrogen-doped natural gas of a natural gas valve station to downstream community users through a gas pipe network;

step two, installing the solid fuel cell at a specific point of a downstream community user;

and step three, the hydrogen-doped natural gas firstly enters the solid fuel cell before entering the home, and the solid fuel cell generates electricity to enter the home.

In a typical embodiment, in the step one, a multi-stage pressure reducing valve is installed in the gas pipe network, the pressure reducing valve in the prior art is a valve which reduces the inlet pressure to a certain required outlet pressure by adjusting and automatically keeps the outlet pressure stable by means of the energy of the medium, and the invention adopts the pressure reducing valve to change the flow rate and the kinetic energy of the fluid by changing the throttling area, so that different pressure losses are caused, the hydrogen-doped gas is in stable flow in the pipeline, and no layering occurs. The inventor finds that by reducing the system pressure with a pressure reducing valve, the pressure of the natural gas and the hydrogen gas can be in relative equilibrium, so that the occurrence of the stratification phenomenon of the hydrogen-loaded natural gas in the flowing process of the pipeline is improved. The applicant further finds that the improvement effect of different pressures of the pressure reducing valve on the layering phenomenon is different, the layering phenomenon can be improved to the maximum degree when the pressure of the pressure reducing valve is controlled within the range of 0.5-8 MPa, when the pressure is lower than 0.5MPa, the pressure of the hydrogen-doped natural gas is insufficient to enable the flowing state to be in a sufficient balanced state, and when the pressure is higher than 8MPa, the pressure of the hydrogen-doped natural gas is too large to enable the pressure oscillation amplitude to be large, the pressure stabilizing effect cannot be exerted, and the layering phenomenon of the hydrogen-doped natural gas cannot be improved. Preferably, in order to further improve the layering phenomenon, the pressure reducing valve is internally provided with fins, so that the gas in the pipe can be uniformly disturbed to be in a turbulent flow state, and the gas in the pipe is further prevented from being layered.

In an exemplary embodiment, in step one, the multistage pressure reducing valve is arranged in a manner that: the proportional pressure reducing valve and the stable pressure reducing valve are applied in series, firstly, the outlet pressure is proportionally adjusted according to the inlet pressure, and then the outlet pressure enters the stable pressure reducing valve to reduce the pressure to a set value.

In a typical embodiment, in the step one, the natural gas blended with hydrogen at the natural gas valve station can be sourced from an upstream pipeline, and hydrogen can also be blended in situ at the gas valve station, wherein the hydrogen content of the gas at the natural gas valve station is 5% -20%, and if the hydrogen content is higher than 20%, hydrogen damage such as hydrogen embrittlement, hydrogen induced cracking, hydrogen bulging, decarburization and the like can be caused; the hydrogen quantity entering the fuel gas conveying pipeline is dynamically controlled by the natural gas quantity in the pipeline, and the hydrogen adding proportion is a rated value under the working condition.

In a typical embodiment, in the first step, the gate station on-site hydrogen loading device can control the amount of hydrogen blended into a gas pipeline network according to the amount of natural gas entering the gas pipeline downstream and the rated hydrogen loading ratio through a built-in logic control system, and the natural gas and the hydrogen are uniformly mixed.

In a typical implementation mode, in the step one, part of the overground gas pipelines are in a multi-material (such as PE, carbon steel, cast iron and the like) parallel connection mode, so that the influence of the hydrogen-doped natural gas on pipelines and parts made of different materials can be monitored in real time in the operation process, and the reference comparison can be conveniently carried out on the operation condition and the inspection protection period of the whole system.

In a typical embodiment, in the second step, the arrangement of the mounting points adopts a K-means algorithm optimized arrangement, a combined distribution mode of star-shaped and branch-shaped is adopted, and the mounting points adopt a mode of one use and one standby to arrange the solid fuel cells, so that the number and the power of the solid fuel cells are adapted to the electricity consumption peak period of the resident users; the star-branch distribution mode can avoid the defect that when one mounting point breaks down, other mounting points cannot be used, and meanwhile, the mounting cost of the solid fuel cell can be reduced, so that the acceptance degree of the community on the solid fuel cell is improved.

In a typical embodiment, in step two, the specific process of the K-means algorithm is as follows: dividing the number of users into K groups in advance, randomly selecting K arrangement points as initial clustering centers, then calculating the distance between each user and each arrangement point, allocating each user to the arrangement point closest to the user, representing a cluster by the arrangement points and the users allocated to the arrangement points, and recalculating the arrangement points of the clusters according to the existing users in the clusters by allocating one user, and repeating the recalculating continuously until all the users in the community finish calculating.

In a typical embodiment, in the third step, a flow follow-up pressure regulating valve is installed in front of the solid fuel cell, and the opening degree of the flow follow-up pressure regulating valve can be controlled according to the gas flow and the power generation amount of the solid fuel cell, so that the processing pressure and the processing flow of the solid fuel cell can be met. Preferably, the inlet pressure of the solid fuel cell is more than 2.0KPa, the hydrogen-doped natural gas can be stably fed into the solid fuel cell system under the pressure, the power generation power is more than 3.0KW, and the supply requirement can be met.

In a second aspect of the invention, the application of the method for controlling stable hydrogen loading of natural gas in the aspect of fuel cell charging piles is provided.

In the prior art, the hydrogen-doped natural gas is used for a vehicle-mounted fuel cell, fuel of the hydrogen-doped natural gas is subjected to oxidation-reduction reaction with oxygen in the atmosphere in the fuel cell carried by an automobile to generate electric energy to drive an electric vehicle to work, and a motor drives a mechanical transmission structure in the automobile to further drive a front axle and other walking mechanical structures of the automobile to work, so that the electric vehicle is driven to move forward. The input end of the charging pile is directly connected with a power grid, and the output end of the charging pile is provided with a charging plug for charging the electric automobile. The difference of the working modes of the fuel cell and the fuel cell comes from the vehicle-mounted fuel cell, gas fuel can be supplied to the fuel cell stack through the decompression stage and the humidification of the humidifier, and the distribution state of mixed gas in the charging pile cannot be well matched with the power supply mode of the mixed gas, so that the power supply effect is influenced. This application can reach fine coordination effect with filling electric pile mode through relief pressure valve control loading natural gas's distribution state, and then satisfies the power supply demand.

The third aspect of the invention provides the application of the stable natural gas hydrogen-loading control method in urban power supply, comprehensive utilization of hydrogen energy and hydrogen supply.

Fill electric pile and can link to each other with urban power supply network, replenish the point of use demand in city by filling electric pile in the peak period of power consumption, owing to broken away from the electric wire netting, this kind of mode has important practical value to the charging of remote area, power supply operation.

Example 1

A stable natural gas hydrogen loading control method comprises the following steps:

firstly, conveying the natural gas blended with hydrogen of a natural gas valve station to a downstream user through a gas pipe network, wherein the content of hydrogen is 5%, and the in-situ hydrogen blending device of the valve station can control the amount of hydrogen blended with the gas pipe network according to the amount of natural gas entering a gas pipe at the downstream through a built-in logic control system at a rated hydrogen blending ratio and uniformly mix the natural gas and the hydrogen; the gas pipe network is provided with a multi-stage pressure reducing valve, the proportional pressure reducing valve and the stable pressure reducing valve are connected in series for application, the outlet pressure of the pressure reducing valve is controlled to be 1.0MPa, and the multi-stage pressure reducing valve enables the hydrogen-doped gas to stably flow in the pipeline without layering; the fins are further arranged in the multi-stage pressure reducing valve, so that gas in the tube can be uniformly disturbed, the tube is in a turbulent state, and the gas in the tube is further prevented from being layered. Meanwhile, the pipeline in the gas pipe network adopts a mode of connecting PE and carbon steel in parallel, so that the influence of the hydrogen-doped natural gas on pipelines and parts made of different materials can be monitored in real time in the operation process, and the reference comparison on the operation condition and the inspection protection period of the whole system can be conveniently carried out.

Step two, installing the solid fuel cell at specific points of downstream community users, optimally arranging the installation points by adopting a K-means algorithm, dividing the users into K groups in advance, randomly selecting K arrangement points as initial clustering centers, then calculating the distance between each user and each arrangement point, allocating each user to the arrangement point closest to the user, representing a cluster by the arrangement points and the users allocated to the arrangement points, allocating one user for each, recalculating the arrangement points of the clusters according to the existing users in the cluster, and repeating the recalculation until all the users in the community finish the calculation. The method adopts a star-branch combined distribution mode, and the installation points adopt a one-use one-standby mode to arrange the solid fuel cells, so that the number and the power of the solid fuel cells are adapted to the peak period of electricity consumption of resident users;

step three, the hydrogen-doped natural gas firstly enters a solid fuel cell before entering a home, the hydrogen-doped natural gas enters the home through the power generation of the solid fuel cell, a flow follow-up pressure regulating valve is arranged in front of the solid fuel cell, the opening degree of the flow follow-up pressure regulating valve can be controlled according to the gas flow and the power generation amount of the solid fuel cell, and the treatment pressure and the treatment flow of the solid fuel cell can be met; and controlling the inlet pressure of the solid fuel cell to be more than 2.0KPa and the generated power to be more than 3.0 KW.

Example 2

A stable natural gas hydrogen loading control method comprises the following steps:

firstly, conveying the natural gas blended with hydrogen of a natural gas valve station to downstream users through a gas pipe network, wherein the content of hydrogen is 15%, and the in-situ hydrogen blending device of the valve station can control the amount of hydrogen blended with the gas pipe network according to the amount of natural gas entering a gas pipe at the downstream by a rated hydrogen blending ratio through a built-in logic control system and uniformly mix the natural gas and the hydrogen; the gas pipe network is provided with a multi-stage pressure reducing valve, the proportional pressure reducing valve and the stable pressure reducing valve are connected in series for application, the outlet pressure of the pressure reducing valve is controlled to be 4.0MPa, and the multi-stage pressure reducing valve enables the hydrogen-doped gas to stably flow in the pipeline without layering; the fins are further arranged in the multi-stage pressure reducing valve, so that gas in the tube can be uniformly disturbed, the tube is in a turbulent state, and the gas in the tube is further prevented from being layered. Meanwhile, the pipeline in the gas pipe network adopts a mode of connecting PE and carbon steel in parallel, so that the influence of the hydrogen-doped natural gas on pipelines and parts made of different materials can be monitored in real time in the operation process, and the reference comparison on the operation condition and the inspection protection period of the whole system can be conveniently carried out.

Step two, installing the solid fuel cell at specific points of downstream community users, optimally arranging the installation points by adopting a K-means algorithm, dividing the users into K groups in advance, randomly selecting K arrangement points as initial clustering centers, then calculating the distance between each user and each arrangement point, allocating each user to the arrangement point closest to the user, representing a cluster by the arrangement points and the users allocated to the arrangement points, allocating one user for each, recalculating the arrangement points of the clusters according to the existing users in the cluster, and repeating the recalculation until all the users in the community finish the calculation. The method adopts a star-branch combined distribution mode, and the installation points adopt a one-use one-standby mode to arrange the solid fuel cells, so that the number and the power of the solid fuel cells are adapted to the peak period of electricity consumption of resident users;

step three, the hydrogen-doped natural gas firstly enters a solid fuel cell before entering a home, the hydrogen-doped natural gas enters the home through the power generation of the solid fuel cell, a flow follow-up pressure regulating valve is arranged in front of the solid fuel cell, the opening degree of the flow follow-up pressure regulating valve can be controlled according to the gas flow and the power generation amount of the solid fuel cell, and the treatment pressure and the treatment flow of the solid fuel cell can be met; and controlling the inlet pressure of the solid fuel cell to be more than 2.0KPa and the generated power to be more than 3.0 KW.

Example 3

A stable natural gas hydrogen loading control method comprises the following steps:

firstly, conveying the natural gas blended with hydrogen of a natural gas valve station to a downstream user through a gas pipe network, wherein the content of hydrogen is 20%, and the in-situ hydrogen blending device of the valve station can control the amount of hydrogen blended with the gas pipe network according to the amount of natural gas entering a gas pipe at the downstream through a built-in logic control system at a rated hydrogen blending ratio and uniformly mix the natural gas and the hydrogen; the proportional pressure reducing valve and the stable pressure reducing valve are applied in series, the outlet pressure of the pressure reducing valve is controlled to be 6.0MPa, and the multi-stage pressure reducing valve enables the hydrogen-doped fuel gas to stably flow in the pipeline without layering; the fins are further arranged in the multi-stage pressure reducing valve, so that gas in the tube can be uniformly disturbed, the tube is in a turbulent state, and the gas in the tube is further prevented from being layered. Meanwhile, the pipeline in the gas pipe network adopts a mode of connecting PE and carbon steel in parallel, so that the influence of the hydrogen-doped natural gas on pipelines and parts made of different materials can be monitored in real time in the operation process, and the reference comparison on the operation condition and the inspection protection period of the whole system can be conveniently carried out.

Step two, installing the solid fuel cell at specific points of downstream community users, optimally arranging the installation points by adopting a K-means algorithm, dividing the users into K groups in advance, randomly selecting K arrangement points as initial clustering centers, then calculating the distance between each user and each arrangement point, allocating each user to the arrangement point closest to the user, representing a cluster by the arrangement points and the users allocated to the arrangement points, allocating one user for each, recalculating the arrangement points of the clusters according to the existing users in the cluster, and repeating the recalculation until all the users in the community finish the calculation. The method adopts a star-branch combined distribution mode, and the installation points adopt a one-use one-standby mode to arrange the solid fuel cells, so that the number and the power of the solid fuel cells are adapted to the peak period of electricity consumption of resident users;

step three, the hydrogen-doped natural gas firstly enters a solid fuel cell before entering a home, the hydrogen-doped natural gas enters the home through the power generation of the solid fuel cell, a flow follow-up pressure regulating valve is arranged in front of the solid fuel cell, the opening degree of the flow follow-up pressure regulating valve can be controlled according to the gas flow and the power generation amount of the solid fuel cell, and the treatment pressure and the treatment flow of the solid fuel cell can be met; and controlling the inlet pressure of the solid fuel cell to be more than 2.0KPa and the generated power to be more than 3.0 KW.

Comparative example 1

The pressure of the control pressure reducing valve was set to 0.4MPa, and other parameter conditions were the same as in example 1.

Comparative example 2

The pressure of the control pressure reducing valve was set to 8.5MPa, and the other parameter conditions were the same as in example 1.

Performance testing

According to the control methods of examples 1 to 3 and comparative examples 1 to 2, a certain cell in Jinan, Shandong province was taken as an object of investigation, and compared with the charging effect of a conventional charging pile in the prior art, indexes such as safety and stability were investigated, as shown in Table 1 below.

Table 1 comparison of charging effects of examples 1 to 3, comparative examples 1 to 2 and prior art charging piles

	Efficiency of power generation	SecureProperty of (2)	Stability of
				Example 1	90％	Is very high	Is very good
Example 2	88％	Is very high	Is very good
				Example 3	85％	Is very high	Is very good
Comparative example 1	40％	In general	Is poor
				Comparative example 2	35％	In general	Is poor
Prior Art	60％	In general	In general

From the above, it can be seen that the best power supply effect can be obtained by controlling the pressure of the pressure reducing valve within the range described in the present application. The control method can achieve the technical effect equivalent to that of the charging mode in the prior art, and has important practical significance.

What is not considered necessary in the above embodiments is the known art.

The above description is only a preferred embodiment of the present application and is not intended to limit the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application.