Alcohol fuel cell made from scrap materials. Fuel cell installations. DIY fuel cell at home. Fuel cells are also used in the civilian sector

Prepare everything you need. To make a simple fuel cell, you will need 12 inches of platinum or platinum-coated wire, a popsicle stick, a 9-volt battery and battery holder, clear tape, a glass of water, table salt (optional), a thin metal rod, and a voltmeter.

A 9-volt battery and battery holder can be purchased from an electronics or hardware store.

Cut two pieces of 15 centimeters long from platinum or platinum-coated wire. Platinum wire is used for special purposes and can be purchased at an electronics store. It will serve as a catalyst for the reaction.

Wrap pieces of wire around a thin metal rod to create the shape of springs. These will be the electrodes of the fuel cell. Grab the end of the wire and wrap it tightly around the rod to create a coil spring. Remove the first wire from the rod and wind the second piece of wire.

You can use a nail, a wire hanger, or a tester probe as a rod for winding the wire.

Cut the battery holder wires in half. Take the wire cutters, cut both wires attached to the holder in half and remove the insulation from them. You will attach these bare wires to the electrodes.

Using the appropriate part of the wire cutters, strip the insulation from the ends of the wire. Strip the insulation from the ends of the wires you cut from the battery holder.
Cut wire under adult supervision.

Attach the ends of the wires, stripped of insulation, to the electrodes. Connect the wires to the electrodes so that you can then connect a power source (battery holder) and a voltmeter to determine how much voltage the fuel cell is producing.

Twist the red battery holder wire and the cut red wire around the top end of one of the wire spools, leaving most of it free.
Wrap the top end of the second coil with the black battery holder wire and the cut black wire.

Attach the electrodes to a popsicle stick or wooden rod. The popsicle stick should be longer than the neck of the glass of water so that it can rest on top of it. Glue the electrodes so that they hang down from the stick and fall into the water.

You can use clear tape or electrical tape. The main thing is that the electrodes are securely attached to the stick.

Pour tap or salt water into a glass. For the reaction to occur, water must contain electrolytes. Distilled water is not suitable for this, since it does not contain impurities that can serve as electrolytes. For the chemical reaction to proceed normally, you can dissolve salt or baking soda in water.

Regular tap water also contains mineral impurities, so it can be used as an electrolyte if you don't have salt on hand.
Add salt or baking soda at the rate of one tablespoon (20 grams) per glass of water. Stir the water until the salt or baking soda is completely dissolved.

Place a stick with electrodes on the neck of a glass of water. In this case, the electrodes in the form of wire springs should be submerged under water for most of their length, with the exception of contacts with the wires of the battery holder. Only the platinum wire should be under water.

If necessary, secure the stick with tape to keep the electrodes in the water.

Connect the wires coming from the electrodes to a voltmeter or LED light bulb. Using a voltmeter, you can determine the voltage produced by the activated fuel cell. Connect the red wire to the positive terminal and the black wire to the negative terminal of the voltmeter.

At this stage, the voltmeter may show a small value, for example 0.01 volts, although the voltage across it should be zero.
You can also connect a small light bulb, such as a flashlight or LED.

Hydrogen fuel cells convert the chemical energy of fuel into electricity, bypassing the ineffective processes of combustion and conversion of thermal energy into mechanical energy, which involve large losses. A hydrogen fuel cell is electrochemical The device directly generates electricity as a result of highly efficient “cold” combustion of fuel. The hydrogen-air proton exchange membrane fuel cell (PEMFC) is one of the most promising fuel cell technologies.

Eight years ago, six liquid diesel pumps were discovered in Western Europe; they must be two hundred before the end. We are a far cry from the thousands of fast charging terminals that are hatching all over the place to encourage the spread of electric propulsion. And that's where the rub hurts. And we better announce graphene.

The batteries haven't had their last word

There's more to it than autonomy, which is why limiting charging times is slowing EV adoption. However, he recalled in a note this month to his customers that batteries have a limitation, limited to this type of probe at very high voltages. Thomas Brachman will be told that a hydrogen distribution network still needs to be built. The argument is that he sweeps his hand, recalling that the multiplication of fast charge terminals is also very expensive, due to the high cross-section of high-voltage copper cables. “It is easier and cheaper to transport liquefied hydrogen by truck from buried tanks near production sites.”

A proton-conducting polymer membrane separates two electrodes—anode and cathode. Each electrode is a carbon plate (matrix) coated with a catalyst. At the anode catalyst, molecular hydrogen dissociates and gives up electrons. Hydrogen cations are conducted through the membrane to the cathode, but electrons are given into the external circuit, since the membrane does not allow electrons to pass through.

Hydrogen is not yet a pure vector of electricity

As for the cost of the battery itself, which is a very sensitive information, Thomas Brachmann has no doubt that it can be significantly reduced as efficiency increases. “Platinum is the element that costs more.” Unfortunately, almost all hydrogen comes from fossil energy sources. Moreover, dihydrogen is just a vector of energy, and not a source from which a non-negligible part is consumed during its production, its liquefaction, and then its conversion into electricity.

At the cathode catalyst, an oxygen molecule combines with an electron (which is supplied from the electrical circuit) and an incoming proton and forms water, which is the only product of the reaction (in the form of vapor and/or liquid).

Membrane-electrode units, which are the key generating element of the energy system, are made from hydrogen fuel cells.

The car of the future behaves like a real one

The battery balance is approximately three times higher, despite losses due to heat in the drivers. Alas, the miracle car will not hit our roads except as part of public demonstrations. Brachmann, who reminds us that the natural silence of an electric car enhances the impression of living in a noisy world. Despite all the difficulties, the steering and brake pedal provide a natural consistency.

Miniature battery but improved performance

The gadget is visible, the central screen diffuses the images of the camera placed in the right mirror as soon as the turn signal is activated. Most of our American customers no longer require, and this allows us to keep prices down - justifies the chief engineer, who offers a lower tariff than. It's actually worth talking about a fuel cell stack since there are 358 that work together. The main reservoir, with a capacity of 117 liters, is pressed against the rear wall of the bench, preventing it from being folded, and the second - 24 liters, is hidden under the seat.

Advantages of hydrogen fuel cells compared to traditional solutions:

- increased specific energy intensity (500 ÷ 1000 Wh/kg),

- extended operating temperature range (-40 0 C / +40 0 C),

- absence of heat spot, noise and vibration,

- reliability at cold start,

- practically unlimited energy storage period (no self-discharge),

First two-stroke fuel cell

Despite its compact size, this new fuel cell converts dihydrogen into electrical current faster and better than its predecessor. It delivers oxygen to the pile elements at a rate previously considered incompatible with their durability. Excess water that previously limited the flow rate is best evacuated. As a result, the power per element increases by half, and efficiency reaches 60%.

This is due to the presence of a 1.7 kWh lithium-ion battery - located under the front seats, which allows additional current to be delivered under strong accelerations. Or the forecast autonomy is 460 km, ideally consistent with what the manufacturer claims.

- the ability to change the energy intensity of the system by changing the number of fuel cartridges, which provides almost unlimited autonomy,

The ability to provide almost any reasonable energy intensity of the system by changing the hydrogen storage capacity,

- high energy intensity,

- tolerance to impurities in hydrogen,

But a thousand parts facilitate air flow and optimize cooling. Even more than its predecessor, this electric car shows that the fuel cell is front and center. A big challenge for the industry and our leaders. Meanwhile, it is very smart who will know which fuel cell or battery will prevail.

A fuel cell is an electrochemical energy conversion device that can produce electricity in the form of direct current by combining a fuel and an oxidizer in a chemical reaction to produce a waste product, typically a fuel oxide.

- long service life,

- environmental friendliness and quiet operation.

Power supply systems based on hydrogen fuel cells for UAVs:

Installation of fuel cells on unmanned vehicles instead of traditional batteries, it multiplies the flight duration, weight payload, allows you to increase the reliability of the aircraft, expand the temperature range of launch and operation of the UAV, reducing the limit to -40 0C. Compared to internal combustion engines, fuel cell-based systems are silent, vibration-free, operate at low temperatures, are difficult to detect during flight, do not produce harmful emissions, and can efficiently perform tasks from video surveillance to payload delivery.

Each fuel cell has two electrodes, one positive and the other negative, and the reaction that produces electricity occurs at the electrodes in the presence of an electrolyte, which carries charged particles from electrode to electrode, while electrons circulate in external wires located between the electrodes to create electricity.

The fuel cell can generate electricity continuously as long as the required flow of fuel and oxidizer is maintained. Some fuel cells produce only a few watts, while others can produce several hundred kilowatts, while smaller batteries are likely to be found in laptops and cell phones, but fuel cells are too expensive to become small generators used to produce electricity for homes and businesses.

Composition of the power supply system for UAVs:

Economic Dimensions of Fuel Cells

Using hydrogen as a fuel source entails significant costs. For this reason, hydrogen is now an uneconomic source, particularly because other less expensive sources can be used. Hydrogen production costs can vary as they reflect the cost of the resources from which it is extracted.

Battery fuel sources

Fuel cells are generally classified into the following categories: hydrogen fuel cells, organic fuel cells, metallic fuel cells, and redox batteries. When hydrogen is used as a fuel source, chemical energy is converted into electricity during the reverse hydrolysis process to produce only water and heat as waste. A hydrogen fuel cell is very low, but can be more or less high in hydrogen production, especially if produced from fossil fuels.

- fuel cell battery,
- Li-Po buffer battery to cover short-term peak loads,
- electronic control system ,
- fuel system consisting of a cylinder with compressed hydrogen or a solid source of hydrogen.

The fuel system uses high-strength lightweight cylinders and reducers to ensure maximum supply of compressed hydrogen on board. It is allowed to use different sizes of cylinders (from 0.5 to 25 liters) with reducers that provide the required hydrogen consumption.

Hydrogen batteries are divided into two categories: low temperature batteries and high temperature batteries, where high temperature batteries can also use fossil fuels directly. The latter consist of hydrocarbons such as oil or gasoline, alcohol or biomass.

Other fuel sources in batteries include, but are not limited to, alcohols, zinc, aluminum, magnesium, ionic solutions and many hydrocarbons. Other oxidizing agents include, but are not limited to, air, chlorine and chlorine dioxide. Currently, there are several types of fuel cells.

Characteristics of the power supply system for UAVs:

Portable chargers based on hydrogen fuel cells:

Portable chargers based on hydrogen fuel cells are compact devices, comparable in weight and dimensions to existing battery chargers that are actively used in the world.

The ubiquitous portable technology in the modern world regularly needs to be recharged. Traditional portable systems are practically useless at low temperatures, and after performing their function they also require recharging using (electrical networks), which also reduces their efficiency and the autonomy of the device.

Each dihydrogen molecule acquires 2 electrons. The H ion moves from the anode to the cathode and causes an electric current by transferring an electron. What might fuel cells for airplanes look like? Today, tests are being carried out on aircraft to try to fly them using a lithium-ion hybrid fuel cell battery. The fuel cell's true benefit lies in its low-weight integrity: it is lighter, which helps reduce aircraft weight and therefore fuel consumption.

But for now, flying a fuel cell aircraft is not possible because it still has many drawbacks. Image of a fuel cell. What are the disadvantages of a fuel cell? First of all, if hydrogen were common, using it in large quantities would be problematic. Indeed, it is available not only on Earth. It is found in oxygen-containing water and ammonia. Therefore, it is necessary to electrolyze water to obtain it, and this is not yet a widespread method.

Hydrogen fuel cell systems require only the replacement of a compact fuel cartridge, after which the device is immediately ready for use.

Features of portable chargers:

Uninterruptible power supplies based on hydrogen fuel cells:

Guaranteed power supply systems based on hydrogen fuel cells are designed to organize backup power supply and temporary power supply. Guaranteed power supply systems based on hydrogen fuel cells offer significant advantages over traditional solutions for organizing temporary and backup power supply, using batteries and diesel generators.

Hydrogen is a gas, making it difficult to contain and transport. Another risk associated with the use of hydrogen is the risk of explosion, as it is a flammable gas. what supplies the battery for its production on a large scale requires another source of energy, be it oil, gas or coal, or nuclear energy, which makes its environmental balance significantly worse than kerosene and make heap, platinum, a metal that is even rarer and more expensive than gold.

The fuel cell provides energy by oxidizing the fuel at the anode and reducing the oxidizer at the cathode. The discovery of the fuel cell principle and the first implementations in the laboratory using sulfuric acid as an electrolyte is credited to chemist William Grove.

Characteristics of the uninterruptible power supply system:

Fuel cell is an electrochemical device similar to a galvanic cell, but differs from it in that the substances for the electrochemical reaction are supplied to it from the outside - in contrast to the limited amount of energy stored in a galvanic cell or battery.

Indeed, fuel cells have some advantages: those that use dihydrogen and dioxide only emit water vapor: it is therefore a clean technology. There are several types of fuel cells, depending on the nature of the electrolyte, the nature of the fuel, direct or indirect oxidation, and operating temperature.

The following table summarizes the main characteristics of these various devices. Several European programs are looking at other polymers, such as polybenzimidazole derivatives, which are more stable and cheaper. Battery compactness is also an ongoing challenge with membranes on the order of 15-50 microns, porous carbon anodes and stainless steel bipolar plates. Life expectancy can also be improved since, on the one hand, traces of carbon monoxide on the order of a few ppm in hydrogen are real poisons for the catalyst, and on the other hand, control of water in the polymer is mandatory.

Rice. 1. Some fuel cells

Fuel cells convert the chemical energy of fuel into electricity, bypassing ineffective combustion processes that occur with large losses. They convert hydrogen and oxygen into electricity through a chemical reaction. As a result of this process, water is formed and a large amount of heat is released. A fuel cell is very similar to a battery that can be charged and then use the stored electrical energy. The inventor of the fuel cell is considered to be William R. Grove, who invented it back in 1839. This fuel cell used a sulfuric acid solution as an electrolyte and hydrogen as a fuel, which was combined with oxygen in an oxidizing agent. Until recently, fuel cells were used only in laboratories and on spacecraft.

Unlike other power generators, such as internal combustion engines or turbines powered by gas, coal, fuel oil, etc., fuel cells do not burn fuel. This means no noisy high-pressure rotors, no loud exhaust noise, no vibrations. Fuel cells produce electricity through a silent electrochemical reaction. Another feature of fuel cells is that they convert the chemical energy of the fuel directly into electricity, heat and water.

Fuel cells are highly efficient and do not produce large amounts of greenhouse gases such as carbon dioxide, methane and nitrous oxide. The only emissions from fuel cells are water in the form of steam and a small amount of carbon dioxide, which is not released at all if pure hydrogen is used as fuel. Fuel cells are assembled into assemblies and then into individual functional modules.

Fuel cells have no moving parts (at least not within the cell itself) and therefore do not obey Carnot's law. That is, they will have greater than 50% efficiency and are especially effective at low loads. Thus, fuel cell vehicles can become (and have already proven to be) more fuel efficient than conventional vehicles in real-world driving conditions.

The fuel cell produces electrical current DC voltage, which can be used to drive an electric motor, lighting and other electrical systems in a vehicle.

There are several types of fuel cells, differing in the chemical processes used. Fuel cells are usually classified by the type of electrolyte they use.

Some types of fuel cells are promising for power plant propulsion, while others are promising for portable devices or to drive cars.

1. Alkaline fuel cells (ALFC)

Alkaline fuel cell- This is one of the very first elements developed. Alkaline fuel cells (AFC) are one of the most studied technologies, used since the mid-60s of the twentieth century by NASA in the Apollo and Space Shuttle programs. On board these spacecraft, fuel cells produce electrical energy and potable water.

Alkaline fuel cells are one of the most efficient cells used to generate electricity, with power generation efficiency reaching up to 70%.

Alkaline fuel cells use an electrolyte, an aqueous solution of potassium hydroxide, contained in a porous, stabilized matrix. The potassium hydroxide concentration may vary depending on the operating temperature of the fuel cell, which ranges from 65°C to 220°C. The charge carrier in SHTE is the hydroxyl ion (OH-), moving from the cathode to the anode, where it reacts with hydrogen, producing water and electrons. The water produced at the anode moves back to the cathode, again generating hydroxyl ions there. As a result of this series of reactions taking place in the fuel cell, electricity and, as a by-product, heat are produced:

Reaction at the anode: 2H2 + 4OH- => 4H2O + 4e

Reaction at the cathode: O2 + 2H2O + 4e- => 4OH

General reaction of the system: 2H2 + O2 => 2H2O

The advantage of SHTE is that these fuel cells are the cheapest to produce, since the catalyst needed on the electrodes can be any of the substances that are cheaper than those used as catalysts for other fuel cells. In addition, SHTEs operate at relatively low temperatures and are among the most efficient.

One of the characteristic features of SHTE is its high sensitivity to CO2, which may be contained in fuel or air. CO2 reacts with the electrolyte, quickly poisons it, and greatly reduces the efficiency of the fuel cell. Therefore, the use of SHTE is limited to enclosed spaces, such as space and underwater vehicles; they operate on pure hydrogen and oxygen.

2. Molten carbonate fuel cells (MCFC)

Fuel cells with molten carbonate electrolyte are high temperature fuel cells. The high operating temperature allows the direct use of natural gas without a fuel processor and low calorific value fuel gas from industrial processes and other sources. This process was developed in the mid-60s of the twentieth century. Since then, production technology, performance and reliability have been improved.

The operation of RCFC differs from other fuel cells. These cells use an electrolyte made from a mixture of molten carbonate salts. Currently, two types of mixtures are used: lithium carbonate and potassium carbonate or lithium carbonate and sodium carbonate. To melt carbonate salts and achieve a high degree of ion mobility in the electrolyte, fuel cells with molten carbonate electrolyte operate at high temperatures (650°C). Efficiency varies between 60-80%.

When heated to a temperature of 650°C, the salts become a conductor for carbonate ions (CO32-). These ions pass from the cathode to the anode, where they combine with hydrogen to form water, carbon dioxide and free electrons. These electrons are sent through an external electrical circuit back to the cathode, generating electric current and heat as a by-product.

Reaction at the anode: CO32- + H2 => H2O + CO2 + 2e

Reaction at the cathode: CO2 + 1/2O2 + 2e- => CO32-

General reaction of the element: H2(g) + 1/2O2(g) + CO2(cathode) => H2O(g) + CO2(anode)

The high operating temperatures of molten carbonate electrolyte fuel cells have certain advantages. The advantage is the ability to use standard materials (stainless steel sheets and nickel catalyst on the electrodes). The waste heat can be used to produce high pressure steam. High reaction temperatures in the electrolyte also have their advantages. The use of high temperatures requires a long time to achieve optimal operating conditions, and the system responds more slowly to changes in energy consumption. These characteristics allow the use of fuel cell installations with molten carbonate electrolyte under constant power conditions. High temperatures prevent damage to the fuel cell by carbon monoxide, “poisoning,” etc.

Fuel cells with molten carbonate electrolyte are suitable for use in large stationary installations. Thermal power plants with an electrical output power of 2.8 MW are commercially produced. Installations with output power up to 100 MW are being developed.

3. Phosphoric acid fuel cells (PAFC)

Fuel cells based on phosphoric (orthophosphoric) acid became the first fuel cells for commercial use. This process was developed in the mid-60s of the twentieth century, tests have been carried out since the 70s of the twentieth century. The result was increased stability and performance and reduced cost.

Phosphoric (orthophosphoric) acid fuel cells use an electrolyte based on orthophosphoric acid (H3PO4) at concentrations up to 100%. The ionic conductivity of phosphoric acid is low at low temperatures, so these fuel cells are used at temperatures up to 150-220 °C.

The charge carrier in fuel cells of this type is hydrogen (H+, proton). A similar process occurs in proton exchange membrane fuel cells (PEMFCs), in which hydrogen supplied to the anode is split into protons and electrons. Protons travel through the electrolyte and combine with oxygen from the air at the cathode to form water. The electrons are sent through an external electrical circuit, thereby generating an electric current. Below are reactions that generate electric current and heat.

Reaction at the anode: 2H2 => 4H+ + 4e

Reaction at the cathode: O2(g) + 4H+ + 4e- => 2H2O

General reaction of the element: 2H2 + O2 => 2H2O

The efficiency of fuel cells based on phosphoric (orthophosphoric) acid is more than 40% when generating electrical energy. With combined production of heat and electricity, the overall efficiency is about 85%. In addition, given operating temperatures, waste heat can be used to heat water and generate atmospheric pressure steam.

The high performance of thermal power plants using fuel cells based on phosphoric (orthophosphoric) acid in the combined production of thermal and electrical energy is one of the advantages of this type of fuel cells. The units use carbon monoxide with a concentration of about 1.5%, which significantly expands the choice of fuel. Simple design, low degree of electrolyte volatility and increased stability are also advantages of such fuel cells.

Thermal power plants with electrical output power of up to 400 kW are commercially produced. Installations with a capacity of 11 MW have passed appropriate tests. Installations with output power up to 100 MW are being developed.

4. Proton exchange membrane fuel cells (PEMFC)

Proton exchange membrane fuel cells are considered the best type of fuel cells for generating power for vehicles, which can replace gasoline and diesel internal combustion engines. These fuel cells were first used by NASA for the Gemini program. Installations based on MOPFC with power from 1 W to 2 kW have been developed and demonstrated.

The electrolyte in these fuel cells is a solid polymer membrane (a thin film of plastic). When saturated with water, this polymer allows protons to pass through but does not conduct electrons.

The fuel is hydrogen, and the charge carrier is a hydrogen ion (proton). At the anode, the hydrogen molecule is split into a hydrogen ion (proton) and electrons. Hydrogen ions pass through the electrolyte to the cathode, and electrons move around the outer circle and produce electrical energy. Oxygen, which is taken from the air, is supplied to the cathode and combines with electrons and hydrogen ions to form water. The following reactions occur at the electrodes: Reaction at the anode: 2H2 + 4OH- => 4H2O + 4eReaction at the cathode: O2 + 2H2O + 4e- => 4OH Overall cell reaction: 2H2 + O2 => 2H2O Compared to other types of fuel cells, fuel cells with a proton exchange membrane produce more energy for a given volume or weight of the fuel cell. This feature allows them to be compact and lightweight. In addition, the operating temperature is less than 100°C, which allows you to quickly start operation. These characteristics, as well as the ability to quickly change energy output, are just a few that make these fuel cells a prime candidate for use in vehicles.

Another advantage is that the electrolyte is a solid rather than a liquid. It is easier to retain gases at the cathode and anode using a solid electrolyte, so such fuel cells are cheaper to produce. With a solid electrolyte, there are no orientation issues and fewer corrosion problems, increasing the longevity of the cell and its components.

5. Solid oxide fuel cells (SOFC)

Solid oxide fuel cells are the highest operating temperature fuel cells. The operating temperature can vary from 600°C to 1000°C, allowing the use of different types of fuel without special pre-treatment. To handle such high temperatures, the electrolyte used is a thin solid metal oxide on a ceramic base, often an alloy of yttrium and zirconium, which is a conductor of oxygen ions (O2-). The technology of using solid oxide fuel cells has been developing since the late 50s of the twentieth century and has two configurations: planar and tubular.

The solid electrolyte provides a sealed transition of gas from one electrode to another, while liquid electrolytes are located in a porous substrate. The charge carrier in fuel cells of this type is the oxygen ion (O2-). At the cathode, oxygen molecules from the air are separated into an oxygen ion and four electrons. Oxygen ions pass through the electrolyte and combine with hydrogen, creating four free electrons. The electrons are sent through an external electrical circuit, generating electric current and waste heat.

Reaction at the anode: 2H2 + 2O2- => 2H2O + 4e

Reaction at the cathode: O2 + 4e- => 2O2-

General reaction of the element: 2H2 + O2 => 2H2O

The efficiency of electrical energy production is the highest of all fuel cells - about 60%. In addition, high operating temperatures allow for the combined production of thermal and electrical energy to generate high-pressure steam. Combining a high-temperature fuel cell with a turbine makes it possible to create a hybrid fuel cell to increase the efficiency of generating electrical energy by up to 70%.

Solid oxide fuel cells operate at very high temperatures (600°C-1000°C), resulting in significant time required to reach optimal operating conditions and a slower system response to changes in energy consumption. At such high operating temperatures, no converter is required to recover hydrogen from the fuel, allowing the thermal power plant to operate with relatively impure fuels resulting from gasification of coal or waste gases, etc. The fuel cell is also excellent for high power applications, including industrial and large central power plants. Modules with an electrical output power of 100 kW are commercially produced.

6. Direct methanol oxidation fuel cells (DOMFC)

Direct methanol oxidation fuel cells They are successfully used in the field of powering mobile phones, laptops, as well as to create portable power sources, which is what the future use of such elements is aimed at.

The design of fuel cells with direct oxidation of methanol is similar to the design of fuel cells with a proton exchange membrane (MEPFC), i.e. A polymer is used as an electrolyte, and a hydrogen ion (proton) is used as a charge carrier. But liquid methanol (CH3OH) oxidizes in the presence of water at the anode, releasing CO2, hydrogen ions and electrons, which are sent through an external electrical circuit, thereby generating an electric current. Hydrogen ions pass through the electrolyte and react with oxygen from the air and electrons from the external circuit to form water at the anode.

Reaction at the anode: CH3OH + H2O => CO2 + 6H+ + 6eReaction at the cathode: 3/2O2 + 6H+ + 6e- => 3H2O General reaction of the element: CH3OH + 3/2O2 => CO2 + 2H2O The development of such fuel cells has been carried out since the beginning of the 90s s of the twentieth century and their specific power and efficiency were increased to 40%.

These elements were tested in the temperature range of 50-120°C. Because of their low operating temperatures and the absence of the need for a converter, such fuel cells are a prime candidate for use in mobile phones and other consumer products, as well as in car engines. Their advantage is also their small size.

7. Polymer electrolyte fuel cells (PEFC)

In the case of polymer electrolyte fuel cells, the polymer membrane consists of polymer fibers with water regions in which conduction water ions H2O+ (proton, red) attaches to a water molecule. Water molecules pose a problem due to slow ion exchange. Therefore, a high concentration of water is required both in the fuel and at the outlet electrodes, which limits the operating temperature to 100°C.

8. Solid acid fuel cells (SFC)

In solid acid fuel cells, the electrolyte (CsHSO4) does not contain water. The operating temperature is therefore 100-300°C. The rotation of the SO42 oxyanions allows the protons (red) to move as shown in the figure. Typically, a solid acid fuel cell is a sandwich in which a very thin layer of solid acid compound is sandwiched between two electrodes that are tightly pressed together to ensure good contact. When heated, the organic component evaporates, exiting through the pores in the electrodes, maintaining the ability of multiple contacts between the fuel (or oxygen at the other end of the element), the electrolyte and the electrodes.

9. Comparison of the most important characteristics of fuel cells

Characteristics of fuel cells

Fuel cell type	Operating temperature	Power generation efficiency	Fuel type	Scope of application
				Medium and large installations
			Pure hydrogen	installations
			Pure hydrogen	Small installations
			Most hydrocarbon fuels	Small, medium and large installations
				Portable installations
			Pure hydrogen	Space researched
			Pure hydrogen	Small installations

10. Use of fuel cells in cars

Ecology of knowledge. Science and technology: Mobile electronics are improving every year, becoming more widespread and accessible: PDAs, laptops, mobile and digital devices, photo frames, etc. They are all replenished all the time

DIY fuel cell at home

Mobile electronics are improving every year, becoming more widespread and accessible: PDAs, laptops, mobile and digital devices, photo frames, etc. All of them are constantly updated with new functions, larger monitors, wireless communications, stronger processors, while decreasing in size . Power technologies, unlike semiconductor technology, are not advancing by leaps and bounds.

The existing batteries and accumulators to power the achievements of the industry are becoming insufficient, so the issue of alternative sources is very acute. Fuel cells are by far the most promising area. The principle of their operation was discovered back in 1839 by William Grove, who generated electricity by changing the electrolysis of water.

What are fuel cells?

Video: Documentary, fuel cells for transport: past, present, future

Fuel cells are of interest to car manufacturers, and spaceship designers are also interested in them. In 1965, they were even tested by America on the Gemini 5 spacecraft launched into space, and later on Apollo. Millions of dollars are being poured into fuel cell research today as pollution issues persist. environment, increasing emissions of greenhouse gases generated during the combustion of organic fuel, the reserves of which are also not infinite.

A fuel cell, often called an electrochemical generator, operates in the manner described below.

Being, like accumulators and batteries, a galvanic element, but with the difference that the active substances are stored in it separately. They are supplied to the electrodes as they are used. Natural fuel or any substance obtained from it burns on the negative electrode, which can be gaseous (hydrogen, for example, and carbon monoxide) or liquid, like alcohols. Oxygen usually reacts at the positive electrode.

But the seemingly simple principle of operation is not easy to translate into reality.

DIY fuel cell

Unfortunately, we do not have photographs of what this fuel element should look like, we rely on your imagination.

You can make a low-power fuel cell with your own hands even in a school laboratory. You need to stock up on an old gas mask, several pieces of plexiglass, alkali and an aqueous solution of ethyl alcohol (more simply, vodka), which will serve as “fuel” for the fuel cell.

First of all, you need a housing for the fuel cell, which is best made from plexiglass, at least five millimeters thick. The internal partitions (there are five compartments inside) can be made a little thinner - 3 cm. To glue plexiglass, use glue of the following composition: six grams of plexiglass shavings are dissolved in one hundred grams of chloroform or dichloroethane (work is done under a hood).

Now you need to drill a hole in the outer wall, into which you need to insert a glass drain tube with a diameter of 5-6 centimeters through a rubber stopper.

Everyone knows that in the periodic table the most active metals are in the lower left corner, and highly active metalloids are in the upper right corner of the table, i.e. the ability to donate electrons increases from top to bottom and from right to left. Elements that can, under certain conditions, manifest themselves as metals or metalloids are in the center of the table.

Now we pour gas mask into the second and fourth compartments Activated carbon(between the first partition and the second, as well as the third and fourth), which will act as electrodes. To prevent coal from spilling out through the holes, you can place it in nylon fabric (women's nylon stockings are suitable).

The fuel will circulate in the first chamber, and in the fifth there should be an oxygen supplier - air. There will be an electrolyte between the electrodes, and in order to prevent it from leaking into the air chamber, you need to soak it with a solution of paraffin in gasoline (ratio of 2 grams of paraffin to half a glass of gasoline) before filling the fourth chamber with carbon for the air electrolyte. On the layer of coal you need to place (by slightly pressing) copper plates to which the wires are soldered. Through them, the current will be diverted from the electrodes.

All that remains is to charge the element. For this you need vodka, which needs to be diluted with water 1:1. Then carefully add three hundred to three hundred fifty grams of caustic potassium. For the electrolyte, 70 grams of potassium hydroxide is dissolved in 200 grams of water.

The fuel cell is ready for testing. Now you need to simultaneously pour fuel into the first chamber and electrolyte into the third. A voltmeter connected to the electrodes should show from 07 volts to 0.9. To ensure continuous operation of the element, it is necessary to remove spent fuel (drain into a glass) and add new fuel (through a rubber tube). The feed rate is adjusted by squeezing the tube. This is what the operation of a fuel cell looks like under laboratory conditions, the power of which is understandably low.

To ensure greater power, scientists have been working on this problem for a long time. The active steel in development houses methanol and ethanol fuel cells. But, unfortunately, they have not yet been put into practice.

Why the fuel cell is chosen as an alternative power source

A fuel cell was chosen as an alternative power source, since the end product of hydrogen combustion in it is water. The only problem is finding an inexpensive and efficient way to produce hydrogen. Enormous funds invested in the development of hydrogen generators and fuel cells cannot but bear fruit, so a technological breakthrough and their real use in everyday life is only a matter of time.

Already today, the monsters of the automotive industry: General Motors, Honda, Draimler Coyler, Ballard, are demonstrating buses and cars that run on fuel cells, the power of which reaches 50 kW. But the problems associated with their safety, reliability, and cost have not yet been resolved. As already mentioned, unlike traditional power sources - batteries and accumulators, in this case the oxidizer and fuel are supplied from the outside, and the fuel cell is only an intermediary in the ongoing reaction of burning fuel and converting the released energy into electricity. “Combustion” occurs only if the element supplies current to the load, like a diesel electric generator, but without a generator and a diesel engine, and also without noise, smoke and overheating. At the same time, the efficiency is much higher, since there are no intermediate mechanisms.

Great hopes are placed on the use of nanotechnology and nanomaterials, which will help miniaturize fuel cells while increasing their power. There have been reports that ultra-efficient catalysts have been created, as well as designs for fuel cells that do not have membranes. In them, fuel (methane, for example) is supplied to the element along with the oxidizer. Interesting solutions use oxygen dissolved in air as an oxidizer, and organic impurities that accumulate in polluted waters are used as fuel. These are so-called biofuel elements.

Fuel cells, according to experts, may enter the mass market in the coming years. published

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I would like to warn you right away that this topic is not entirely on the subject of Habr, but in the comments to the post about the element developed at MIT, the idea seemed to be supported, so below I will describe some thoughts about biofuel elements.
The work on which this topic is written was done by me in 11th grade, and took second place at the international conference INTEL ISEF.

A fuel cell is a chemical current source in which the chemical energy of a reducing agent (fuel) and an oxidizing agent, continuously and separately supplied to the electrodes, is directly converted into electrical energy
energy. The schematic diagram of a fuel cell (FC) is presented below:

The fuel cell consists of an anode, cathode, ionic conductor, anode and cathode chambers. At the moment, the power of biofuel cells is not enough for use on an industrial scale, but low-power BFCs can be used for medical purposes as sensitive sensors since the current strength in them is proportional to the amount of fuel being processed.
To date, a large number of design varieties of fuel cells have been proposed. In each specific case, the design of the fuel cell depends on the purpose of the fuel cell, the type of reagent and the ionic conductor. A special group includes biofuel cells that use biological catalysts. An important distinguishing feature of biological systems is their ability to selectively oxidize various fuels at low temperatures.
In most cases, immobilized enzymes are used in bioelectrocatalysis, i.e. enzymes isolated from living organisms and fixed to a carrier, but retaining catalytic activity (partially or completely), which allows them to be reused. Let us consider the example of a biofuel cell in which an enzymatic reaction is coupled with an electrode reaction using a mediator. Scheme of a biofuel cell based on glucose oxidase:

A biofuel cell consists of two inert electrodes made of gold, platinum or carbon, immersed in a buffer solution. The electrodes are separated by an ion exchange membrane: the anode compartment is purged with air, the cathode compartment with nitrogen. The membrane allows spatial separation of the reactions occurring in the electrode compartments of the cell, and at the same time ensures the exchange of protons between them. Membranes suitable for biosensors different types are produced in the UK by many companies (VDN, VIROKT).
The introduction of glucose into a biofuel cell containing glucose oxidase and a soluble mediator at 20 °C results in a flow of electrons from the enzyme to the anode through the mediator. The electrons travel through the external circuit to the cathode, where, under ideal conditions, water is formed in the presence of protons and oxygen. The resulting current (in the absence of saturation) is proportional to the addition of the rate-determining component (glucose). By measuring stationary currents, you can quickly (5 s) determine even low concentrations of glucose - up to 0.1 mM. As a sensor, the described biofuel cell has certain limitations associated with the presence of a mediator and certain requirements for the oxygen cathode and membrane. The latter must retain the enzyme and at the same time allow low molecular weight components to pass through: gas, mediator, substrate. Ion exchange membranes generally satisfy these requirements, although their diffusion properties depend on the pH of the buffer solution. Diffusion of components through the membrane leads to a decrease in the efficiency of electron transfer due to side reactions.
Today, there are laboratory models of fuel cells with enzyme catalysts, whose characteristics do not meet the requirements of their practical application. The main efforts in the next few years will be aimed at refining biofuel cells and further applications of the biofuel cell will be more related to medicine, for example: an implantable biofuel cell using oxygen and glucose.
When using enzymes in electrocatalysis, the main problem that needs to be solved is the problem of coupling the enzymatic reaction with the electrochemical one, that is, ensuring effective electron transport from the active center of the enzyme to the electrode, which can be achieved in the following ways:
1. Transfer of electrons from the active center of the enzyme to the electrode using a low-molecular carrier - mediator (mediator bioelectrocatalysis).
2. Direct, direct oxidation and reduction of active sites of the enzyme on the electrode (direct bioelectrocatalysis).
In this case, the mediator coupling of the enzymatic and electrochemical reactions, in turn, can be carried out in four ways:
1) the enzyme and mediator are in the bulk of the solution and the mediator diffuses to the surface of the electrode;
2) the enzyme is on the surface of the electrode, and the mediator is in the volume of the solution;
3) the enzyme and mediator are immobilized on the surface of the electrode;
4) the mediator is sewn to the surface of the electrode, and the enzyme is in solution.

In this work, laccase served as a catalyst for the cathodic reaction of oxygen reduction, and glucose oxidase (GOD) served as a catalyst for the anodic reaction of glucose oxidation. Enzymes were used as part of composite materials, the creation of which is one of the most important stages in the creation of biofuel cells that simultaneously serve as an analytical sensor. In this case, biocomposite materials must provide selectivity and sensitivity for determining the substrate and at the same time have high bioelectrocatalytic activity, approaching enzymatic activity.
Laccase is a Cu-containing oxidoreductase, the main function of which under native conditions is the oxidation of organic substrates (phenols and their derivatives) with oxygen, which is reduced to water. The molecular weight of the enzyme is 40,000 g/mol.

To date, it has been shown that laccase is the most active electrocatalyst for oxygen reduction. In its presence on the electrode in an oxygen atmosphere, a potential close to the equilibrium oxygen potential is established, and oxygen reduction occurs directly to water.
A composite material based on laccase, acetylene black AD-100 and Nafion was used as a catalyst for the cathodic reaction (oxygen reduction). A special feature of the composite is its structure, which ensures the orientation of the enzyme molecule relative to the electron-conducting matrix, necessary for direct electron transfer. The specific bioelectrocatalytic activity of laccase in the composite approaches that observed in enzymatic catalysis. The method of coupling the enzymatic and electrochemical reactions in the case of laccase, i.e. a method of transferring an electron from a substrate through the active center of the laccase enzyme to an electrode - direct bielectrocatalysis.

Glucose oxidase (GOD) is an enzyme of the oxidoreductase class, has two subunits, each of which has its own active center - (flavin adenine dinucleotide) FAD. GOD is an enzyme selective for the electron donor, glucose, and can use many substrates as electron acceptors. The molecular weight of the enzyme is 180,000 g/mol.

In this work, we used a composite material based on GOD and ferrocene (FC) for the anodic oxidation of glucose via a mediator mechanism. The composite material includes GOD, highly dispersed colloidal graphite (HCG), Fc and Nafion, which made it possible to obtain an electron-conducting matrix with a highly developed surface, ensure efficient transport of reagents into the reaction zone and stable characteristics of the composite material. A method of coupling enzymatic and electrochemical reactions, i.e. ensuring efficient transport of electrons from the active center of GOD to the mediator electrode, while the enzyme and mediator were immobilized on the surface of the electrode. Ferrocene was used as a mediator - electron acceptor. When an organic substrate, glucose, is oxidized, ferrocene is reduced and then oxidized at the electrode.

If anyone is interested, I can describe in detail the process of obtaining electrode coating, but for this it is better to write in a personal message. And in the topic I will simply describe the resulting structure.

1. AD-100.
2. laccase.
3. hydrophobic porous substrate.
4. Nafion.

After the electors were received, we moved directly to the experimental part. This is what our work cell looked like:

1. Ag/AgCl reference electrode;
2. working electrode;
3. auxiliary electrode - Рt.
In the experiment with glucose oxidase - purging with argon, with laccase - with oxygen.

The reduction of oxygen on soot in the absence of laccase occurs at potentials below zero and occurs in two stages: through the intermediate formation of hydrogen peroxide. The figure shows the polarization curve of the electroreduction of oxygen by laccase immobilized on AD-100, obtained in an oxygen atmosphere in a solution with pH 4.5. Under these conditions, a stationary potential is established close to the equilibrium oxygen potential (0.76 V). At cathodic potentials of 0.76 V, catalytic reduction of oxygen is observed at the enzyme electrode, which proceeds through the mechanism of direct bioelectrocatalysis directly to water. In the potential region below 0.55 V cathode, a plateau is observed on the curve, which corresponds to the limiting kinetic current of oxygen reduction. The limiting current value was about 630 μA/cm2.

The electrochemical behavior of the composite material based on GOD Nafion, ferrocene and VKG was studied by cyclic voltammetry (CV). The state of the composite material in the absence of glucose in a phosphate buffer solution was monitored using charging curves. On the charging curve at a potential of (–0.40) V, maxima are observed related to the redox transformations of the active center of GOD - (FAD), and at 0.20-0.25 V there are maxima of oxidation and reduction of ferrocene.

From the results obtained it follows that based on a cathode with laccase as a catalyst for the oxygen reaction, and an anode based on glucose oxidase for the oxidation of glucose, there is a fundamental possibility of creating a biofuel cell. True, there are many obstacles on this path, for example, peaks of enzyme activity are observed at different pH levels. This led to the need to add an ion exchange membrane to the BFC. The membrane allows for spatial separation of the reactions occurring in the electrode compartments of the cell, and at the same time ensures the exchange of protons between them. Air enters the anode compartment.
The introduction of glucose into a biofuel cell containing glucose oxidase and a mediator results in a flow of electrons from the enzyme to the anode through the mediator. The electrons travel through the external circuit to the cathode, where, under ideal conditions, water is formed in the presence of protons and oxygen. The resulting current (in the absence of saturation) is proportional to the addition of the rate-determining component, glucose. By measuring stationary currents, you can quickly (5 s) determine even low concentrations of glucose - up to 0.1 mM.

Unfortunately, I was not able to bring the idea of this BFC to practical implementation, because Immediately after 11th grade, I went to study to become a programmer, which I still do diligently today. Thanks to everyone who completed it.

You will no longer surprise anyone with either solar panels or wind turbines, which generate electricity in all regions of the world. But the output from these devices is not constant and it is necessary to install backup power sources or connect to the network to obtain electricity during the period when renewable energy sources do not generate electricity. However, there are plants developed in the 19th century that use “alternative” fuels to generate electricity, i.e. do not burn gas or petroleum products. Such installations are fuel cells.

HISTORY OF CREATION

Fuel cells (FC) or fuel cells were discovered back in 1838-1839 by William Grove (Grove, Grove), when he was studying the electrolysis of water.

Help: Electrolysis of water is the process of decomposition of water under the influence of electric current into hydrogen and oxygen molecules

Having disconnected the battery from the electrolytic cell, he was surprised to find that the electrodes began to absorb the released gas and generate current. The discovery of the process of electrochemical “cold” combustion of hydrogen was a significant event in the energy industry. He later created the Grove battery. This device had a platinum electrode immersed in nitric acid and a zinc electrode in zinc sulfate. It generated a current of 12 amperes and a voltage of 8 volts. Grow himself called this design "wet battery". He then created a battery using two platinum electrodes. One end of each electrode was in sulfuric acid, and the other ends were sealed in containers with hydrogen and oxygen. There was a stable current between the electrodes, and the amount of water inside the containers increased. Grow was able to decompose and improve the water in this device.

"Battery Grow"

(source: Royal Society of the National Museum of Natural History)

The term “fuel cell” (English “Fuel Cell”) appeared only in 1889 by L. Mond and
C. Langer, who tried to create a device for generating electricity from air and coal gas.

HOW IT WORKS?

A fuel cell is a relatively simple device. It has two electrodes: anode (negative electrode) and cathode (positive electrode). A chemical reaction occurs at the electrodes. To speed it up, the surface of the electrodes is coated with a catalyst. FCs are equipped with one more element - membrane. The conversion of the chemical energy of the fuel directly into electricity occurs thanks to the work of the membrane. It separates the two chambers of the element into which fuel and oxidizer are supplied. The membrane allows only protons, which are produced as a result of fuel splitting, to pass from one chamber to another at an electrode coated with a catalyst (electrons then travel through an external circuit). In the second chamber, protons combine with electrons (and oxygen atoms) to form water.

Working principle of a hydrogen fuel cell

At the chemical level, the process of converting fuel energy into electrical energy is similar to the conventional combustion process (oxidation).

During normal combustion in oxygen, oxidation of organic fuel occurs, and the chemical energy of the fuel is converted into thermal energy. Let's see what happens during the oxidation of hydrogen with oxygen in an electrolyte environment and in the presence of electrodes.

By supplying hydrogen to an electrode located in an alkaline environment, a chemical reaction occurs:

2H 2 + 4OH - → 4H 2 O + 4e -

As you can see, we get electrons that, passing through the external circuit, arrive at the opposite electrode, to which oxygen flows and where the reaction takes place:

4e- + O 2 + 2H 2 O → 4OH -

It can be seen that the resulting reaction 2H 2 + O 2 → H 2 O is the same as during normal combustion, but The fuel cell produces electric current and some heat.

TYPES OF FUEL CELLS

It is customary to classify fuel cells according to the type of electrolyte used for the reaction:

Note that fuel cells can also use coal, carbon monoxide, alcohols, hydrazine, and other organic substances as fuel, and air, hydrogen peroxide, chlorine, bromine, nitric acid, etc. as oxidizing agents.

FUEL CELL EFFICIENCY

A feature of fuel cells is no strict limitation on efficiency, like heat engines.

Help: EfficiencyCarnot cycle is the highest possible efficiency among all heat engines with the same minimum and maximum temperatures.

Therefore, the efficiency of fuel cells in theory can be higher than 100%. Many smiled and thought, “The perpetual motion machine has been invented.” No, here we should go back to the school chemistry course. The fuel cell is based on the conversion of chemical energy into electrical energy. This is where miracles happen. Certain chemical reactions as they occur can absorb heat from the environment.

Help: Endothermic reactions are chemical reactions accompanied by the absorption of heat. For endothermic reactions, changes in enthalpy and internal energy have positive values (Δ H >0, Δ U >0), thus the reaction products contain more energy than the starting components.

An example of such a reaction is the oxidation of hydrogen, which is used in most fuel cells. Therefore, theoretically, the efficiency can be more than 100%. But today, fuel cells heat up during operation and cannot absorb heat from the environment.

Help: This limitation is imposed by the second law of thermodynamics. The process of heat transfer from a “cold” body to a “hot” one is not possible.

Plus, there are losses associated with nonequilibrium processes. Such as: ohmic losses due to the specific conductivity of the electrolyte and electrodes, activation and concentration polarization, diffusion losses. As a result, part of the energy generated in fuel cells is converted into heat. Therefore, fuel cells are not perpetual motion machines and their efficiency is less than 100%. But their efficiency is greater than that of other machines. Today Fuel cell efficiency reaches 80%.

Reference: In the forties, the English engineer T. Bacon designed and built a battery of fuel cells with a total power of 6 kW and an efficiency of 80%, running on pure hydrogen and oxygen, but the power-to-weight ratio of the battery turned out to be too small - such elements were unsuitable for practical use and too expensive (source: http://www.powerinfo.ru/).

FUEL CELL PROBLEMS

Almost all fuel cells use hydrogen as fuel, so the logical question arises: “Where can I get it?”

It seems that a fuel cell was discovered as a result of electrolysis, so it is possible to use the hydrogen released as a result of electrolysis. But let's look at this process in more detail.

According to Faraday's law: the amount of a substance that is oxidized at the anode or reduced at the cathode is proportional to the amount of electricity passing through the electrolyte. This means that in order to get more hydrogen, you need to spend more electricity. Existing methods of water electrolysis operate with an efficiency of less than one. Then we use the resulting hydrogen in fuel cells, where the efficiency is also less than unity. Therefore, we will spend more energy than we can produce.

Of course, you can use hydrogen produced from natural gas. This method of producing hydrogen remains the cheapest and most popular. Currently, about 50% of the hydrogen produced worldwide comes from natural gas. But there is a problem with storing and transporting hydrogen. Hydrogen has a low density ( one liter of hydrogen weighs 0.0846 g), so in order to transport it to long distances it needs to be compressed. And these are additional energy and monetary costs. Also, don’t forget about safety.

However, there is also a solution here - liquid hydrocarbon fuel can be used as a source of hydrogen. For example, ethyl or methyl alcohol. True, this requires a special additional device - a fuel converter, when high temperature(for methanol this will be somewhere around 240°C) converting alcohols into a mixture of gaseous H 2 and CO 2. But in this case, it is already more difficult to think about portability - such devices are good to use as stationary or car generators, but for compact mobile equipment you need something less bulky.

Catalyst

To enhance the reaction in the fuel cell, the anode surface is usually treated with a catalyst. Until recently, platinum was used as a catalyst. Therefore, the cost of the fuel cell was high. Secondly, platinum is a relatively rare metal. According to experts, with the industrial production of fuel cells, proven reserves of platinum will run out in 15-20 years. But scientists around the world are trying to replace platinum with other materials. By the way, some of them achieved good results. So Chinese scientists replaced platinum with calcium oxide (source: www.cheburek.net).

USING FUEL CELLS

The first fuel cell in automotive technology was tested in 1959. The Alice-Chambers tractor used 1008 batteries to operate. The fuel was a mixture of gases, mainly propane and oxygen.

Source: http://www.planetseed.com/

Since the mid-60s, at the height of the “space race,” spacecraft creators became interested in fuel cells. The work of thousands of scientists and engineers allowed us to reach a new level, and in 1965. fuel cells were tested in the United States on the Gemini 5 spacecraft, and later on the Apollo spacecraft for flights to the Moon and the Shuttle program. In the USSR, fuel cells were developed at NPO Kvant, also for use in space (source: http://www.powerinfo.ru/).

Since in a fuel cell the final product of hydrogen combustion is water, they are considered the cleanest in terms of environmental impact. Therefore, fuel cells began to gain popularity against the backdrop of general interest in the environment.

Already, car manufacturers such as Honda, Ford, Nissan and Mercedes-Benz have created cars powered by hydrogen fuel cells.

Mercedes-Benz - Ener-G-Force powered by hydrogen

When using hydrogen cars, the problem with hydrogen storage is solved. The construction of hydrogen gas stations will make it possible to refuel anywhere. Moreover, refueling a car with hydrogen is faster than charging an electric car at a gas station. But when implementing such projects, we encountered a problem similar to that of electric vehicles. People are ready to switch to a hydrogen car if there is infrastructure for them. And the construction of gas stations will begin if there are a sufficient number of consumers. Therefore, we again came to the dilemma of the egg and the chicken.

Fuel cells are widely used in mobile phones and laptops. The time has already passed when the phone was charged once a week. Now the phone is charged almost every day, and the laptop works for 3-4 hours without a network. Therefore, mobile technology manufacturers decided to synthesize a fuel cell with phones and laptops for charging and operation. For example, the Toshiba company in 2003. demonstrated a finished prototype of a methanol fuel cell. It produces a power of about 100 mW. One refill of 2 cubes of concentrated (99.5%) methanol is enough for 20 hours of operation of the MP3 player. Again, the same Toshiba demonstrated a cell for powering laptops measuring 275x75x40mm, allowing the computer to operate for 5 hours on a single charge.

But some manufacturers have gone further. The PowerTrekk company has released a charger of the same name. PowerTrekk is the world's first water charger. It is very easy to use. The PowerTrekk requires the addition of water to provide instant electricity via the USB cord. This fuel cell contains silicon powder and sodium silicide (NaSi) when mixed with water, the combination generates hydrogen. Hydrogen is mixed with air in the fuel cell itself, and it converts hydrogen into electricity through its membrane-proton exchange, without fans or pumps. You can buy such a portable charger for 149 € (

Fuel cells (electrochemical generators) represent a very efficient, durable, reliable and environmentally friendly method of generating energy. Initially, they were used only in the space industry, but today electrochemical generators are increasingly used in various fields: power supplies for mobile phones and laptops, vehicle engines, autonomous power sources for buildings, and stationary power plants. Some of these devices operate as laboratory prototypes, while others are used for demonstration purposes or are undergoing pre-production testing. However, many models are already used in commercial projects and are mass-produced.

Device

Fuel cells are electrochemical devices capable of providing a high conversion rate of existing chemical energy into electrical energy.

The fuel cell device includes three main parts:

Power generation section;
CPU;
Voltage transformer.

The main part of the fuel cell is the power generation section, which is a battery made of individual fuel cells. A platinum catalyst is included in the structure of the fuel cell electrodes. Using these cells, a constant electric current is created.

One of these devices has the following characteristics: at a voltage of 155 volts, 1400 amperes are produced. The battery dimensions are 0.9 m in width and height, and 2.9 m in length. The electrochemical process in it is carried out at a temperature of 177 °C, which requires heating of the battery at the time of start-up, as well as heat removal during its operation. For this purpose, a separate water circuit is included in the fuel cell, and the battery is equipped with special cooling plates.

The fuel process converts natural gas into hydrogen, which is required for an electrochemical reaction. The main element of the fuel processor is the reformer. In it, natural gas (or other hydrogen-containing fuel) interacts at high pressure and high temperature (about 900 ° C) with water vapor under the action of a nickel catalyst.

To maintain the required temperature of the reformer there is a burner. The steam required for reforming is created from the condensate. An unstable direct current is generated in the fuel cell battery and a voltage converter is used to convert it.

Also in the voltage converter block there are:

Control devices.
Safety interlock circuits that shut down the fuel cell during various faults.

Operating principle

The simplest proton exchange membrane cell consists of a polymer membrane that is located between the anode and cathode, as well as the cathode and anode catalysts. The polymer membrane is used as an electrolyte.

The proton exchange membrane looks like a thin solid organic compound of small thickness. This membrane works as an electrolyte; in the presence of water, it separates the substance into negatively and positively charged ions.
Oxidation begins at the anode, and reduction occurs at the cathode. The cathode and anode in a PEM cell are made of porous material; it is a mixture of platinum and carbon particles. Platinum acts as a catalyst, which promotes the dissociation reaction. The cathode and anode are made porous so that oxygen and hydrogen pass through them freely.
The anode and cathode are located between two metal plates, they supply oxygen and hydrogen to the cathode and anode, and remove electrical energy, heat and water.
Through channels in the plate, hydrogen molecules enter the anode, where the molecules are decomposed into atoms.
As a result of chemisorption under the influence of a catalyst, hydrogen atoms are converted into positively charged hydrogen ions H+, that is, protons.
Protons diffuse to the cathode through the membrane, and a flow of electrons goes to the cathode through a special external electrical circuit. A load is connected to it, that is, a consumer of electrical energy.
Oxygen, which is supplied to the cathode, upon exposure, enters into a chemical reaction with electrons from the external electrical circuit and hydrogen ions from the proton exchange membrane. As a result of this chemical reaction, water appears.

The chemical reaction that occurs in other types of fuel cells (for example, with an acidic electrolyte in the form of orthophosphoric acid H3PO4) is completely identical to the reaction of a device with a proton exchange membrane.

Kinds

Currently, several types of fuel cells are known, which differ in the composition of the electrolyte used:

Fuel cells based on orthophosphoric or phosphoric acid (PAFC, Phosphoric Acid Fuel Cells).
Devices with proton exchange membrane (PEMFC, Proton Exchange Membrane Fuel Cells).
Solid oxide fuel cells (SOFC, Solid Oxide Fuel Cells).
Electrochemical generators based on molten carbonate (MCFC, Molten Carbonate Fuel Cells).

Currently, electrochemical generators using PAFC technology have become more widespread.

Application

Today, fuel cells are used in the Space Shuttle, reusable spacecraft. They use 12 W units. They generate all the electricity on the spacecraft. The water that is formed during the electrochemical reaction is used for drinking, including for cooling equipment.

Electrochemical generators were also used to power the Soviet Buran, a reusable spacecraft.

Fuel cells are also used in the civilian sector.

Stationary installations with a power of 5–250 kW and above. They are used as autonomous sources for heat and power supply to industrial, public and residential buildings, emergency and backup power supplies, and uninterruptible power supplies.
Portable units with a power of 1–50 kW. They are used for space satellites and ships. Instances are created for golf carts, wheelchairs, railway and freight refrigerators, and road signs.
Mobile installations with a power of 25–150 kW. They are beginning to be used in military ships and submarines, including cars and other vehicles. Prototypes have already been created by such automotive giants as Renault, Neoplan, Toyota, Volkswagen, Hyundai, Nissan, VAZ, General Motors, Honda, Ford and others.
Microdevices with a power of 1–500 W. They find application in advanced handheld computers, laptops, consumer electronic devices, mobile phones, and modern military devices.

Peculiarities

Some of the energy from the chemical reaction in each fuel cell is released as heat. Refrigeration required. In an external circuit, the flow of electrons creates a direct current that is used to do work. Stopping the movement of hydrogen ions or opening the external circuit leads to the stop of the chemical reaction.
The amount of electricity that fuel cells create is determined by gas pressure, temperature, geometric dimensions, and type of fuel cell. To increase the amount of electricity produced by the reaction, fuel cells can be made larger, but in practice several cells are used, which are combined into batteries.
The chemical process in some types of fuel cells can be reversed. That is, when a potential difference is applied to the electrodes, water can be decomposed into oxygen and hydrogen, which will be collected on the porous electrodes. When the load is turned on, such a fuel cell will generate electrical energy.

Prospects

Currently, electrochemical generators require large initial costs to be used as the main source of energy. With the introduction of more stable membranes with high conductivity, efficient and cheap catalysts, and alternative sources of hydrogen, fuel cells will become highly economically attractive and will be implemented everywhere.

Cars will run on fuel cells; there will be no internal combustion engines at all. Water or solid-state hydrogen will be used as an energy source. Refueling will be simple and safe, and driving will be environmentally friendly - only water vapor will be produced.
All buildings will have their own portable fuel cell power generators.
Electrochemical generators will replace all batteries and will be installed in any electronics and household appliances.

Advantages and disadvantages

Each type of fuel cell has its own disadvantages and advantages. Some require high quality fuel, others have a complex design and require high operating temperatures.

In general, the following advantages of fuel cells can be noted:

environmental safety;
electrochemical generators do not need to be recharged;
electrochemical generators can create energy constantly, they do not care about external conditions;
flexibility in scale and portability.

Among the disadvantages are:

technical difficulties with fuel storage and transportation;
imperfect elements of the device: catalysts, membranes, and so on.

Fuel cell ( Fuel Cell) is a device that converts chemical energy into electrical energy. It is similar in principle to a conventional battery, but differs in that its operation requires a constant supply of substances from the outside for the electrochemical reaction to occur. Hydrogen and oxygen are supplied to the fuel cells, and the output is electricity, water and heat. Their advantages include environmental friendliness, reliability, durability and ease of operation. Unlike conventional batteries, electrochemical converters can operate virtually indefinitely as long as fuel is supplied. They don't have to be charged for hours until they're fully charged. Moreover, the cells themselves can charge the battery while the car is parked with the engine turned off.

The most widely used fuel cells in hydrogen vehicles are proton membrane fuel cells (PEMFCs) and solid oxide fuel cells (SOFCs).

A proton exchange membrane fuel cell works as follows. Between the anode and cathode there is a special membrane and a platinum-coated catalyst. Hydrogen is supplied to the anode, and oxygen (for example, from air) is supplied to the cathode. At the anode, hydrogen is decomposed into protons and electrons with the help of a catalyst. Hydrogen protons pass through the membrane and reach the cathode, and electrons are transferred to the external circuit (the membrane does not allow them to pass through). The potential difference thus obtained leads to the generation of electric current. On the cathode side, hydrogen protons are oxidized by oxygen. As a result, water vapor appears, which is the main element of car exhaust gases. Possessing high efficiency, PEM cells have one significant drawback - their operation requires pure hydrogen, the storage of which is a rather serious problem.

If such a catalyst is found that replaces expensive platinum in these cells, then a cheap fuel cell for generating electricity will immediately be created, which means the world will get rid of oil dependence.

Solid Oxide Cells

Solid oxide SOFC cells are much less demanding on fuel purity. In addition, thanks to the use of a POX reformer (Partial Oxidation), such cells can consume regular gasoline as fuel. The process of converting gasoline directly into electricity is as follows. In a special device - a reformer, at a temperature of about 800 ° C, gasoline evaporates and decomposes into its constituent elements.

This releases hydrogen and carbon dioxide. Further, also under the influence of temperature and using SOFC directly (consisting of a porous ceramic material based on zirconium oxide), hydrogen is oxidized by oxygen in the air. After obtaining hydrogen from gasoline, the process continues according to the scenario described above, with only one difference: the SOFC fuel cell, unlike devices operating on hydrogen, is less sensitive to impurities in the original fuel. So the quality of gasoline should not affect the performance of the fuel cell.

The high operating temperature of SOFC (650–800 degrees) is a significant drawback; the warm-up process takes about 20 minutes. But excess heat is not a problem, since it is completely removed by the remaining air and exhaust gases produced by the reformer and the fuel cell itself. This allows the SOFC system to be integrated into a vehicle as a separate device in a thermally insulated housing.

The modular structure allows you to achieve the required voltage by connecting a set of standard cells in series. And, perhaps most importantly from the point of view of the implementation of such devices, SOFC does not contain very expensive platinum-based electrodes. It is the high cost of these elements that is one of the obstacles in the development and dissemination of PEMFC technology.

Types of fuel cells

Currently, there are the following types of fuel cells:

A.F.C.– Alkaline Fuel Cell (alkaline fuel cell);
PAFC– Phosphoric Acid Fuel Cell (phosphoric acid fuel cell);
PEMFC– Proton Exchange Membrane Fuel Cell (fuel cell with a proton exchange membrane);
DMFC– Direct Methanol Fuel Cell (fuel cell with direct breakdown of methanol);
MCFC– Molten Carbonate Fuel Cell (fuel cell of molten carbonate);
SOFC– Solid Oxide Fuel Cell (solid oxide fuel cell).

Advantages of fuel cells/cells

A fuel cell/cell is a device that efficiently produces direct current and heat from hydrogen-rich fuel through an electrochemical reaction.

A fuel cell is similar to a battery in that it produces direct current through a chemical reaction. The fuel cell includes an anode, a cathode and an electrolyte. However, unlike batteries, fuel cells cannot store electrical energy and do not discharge or require electricity to recharge. Fuel cells/cells can continuously produce electricity as long as they have a supply of fuel and air.

Unlike other power generators, such as internal combustion engines or turbines powered by gas, coal, fuel oil, etc., fuel cells/cells do not burn fuel. This means no noisy high pressure rotors, no loud exhaust noise, no vibration. Fuel cells/cells produce electricity through a silent electrochemical reaction. Another feature of fuel cells/cells is that they convert the chemical energy of the fuel directly into electricity, heat and water.

Fuel cells are highly efficient and do not produce large amounts of greenhouse gases such as carbon dioxide, methane and nitrous oxide. The only emission products during operation are water in the form of steam and a small amount of carbon dioxide, which is not released at all if pure hydrogen is used as fuel. Fuel elements/cells are assembled into assemblies and then into individual functional modules.

History of development of fuel cells/cells

In the 1950s and 1960s, one of the most pressing challenges for fuel cells arose from the National Aeronautics and Space Administration's (NASA) need for energy sources for long-duration space missions. NASA's alkaline fuel cell uses hydrogen and oxygen as fuel by combining the two chemical elements in an electrochemical reaction. The output is three useful byproducts of the reaction in space flight - electricity to power the spacecraft, water for drinking and cooling systems, and heat to warm the astronauts.

The discovery of fuel cells dates back to the beginning of the 19th century. The first evidence of the effect of fuel cells was obtained in 1838.

In the late 1930s, work began on fuel cells with an alkaline electrolyte and by 1939 a cell using high-pressure nickel-plated electrodes was built. During the Second World War, fuel cells/cells were developed for British Navy submarines and in 1958 a fuel assembly consisting of alkaline fuel cells/cells with a diameter of just over 25 cm was introduced.

Interest increased in the 1950s and 1960s, and also in the 1980s, when the industrial world experienced a shortage of petroleum fuels. During the same period, world countries also became concerned about the problem of air pollution and considered ways to generate electricity in an environmentally friendly manner. Fuel cell technology is currently undergoing rapid development.

Operating principle of fuel cells/cells

Fuel cells/cells produce electricity and heat due to an electrochemical reaction taking place using an electrolyte, a cathode and an anode.

The anode and cathode are separated by an electrolyte that conducts protons. After hydrogen flows to the anode and oxygen to the cathode, a chemical reaction begins, as a result of which electric current, heat and water are generated.

At the anode catalyst, molecular hydrogen dissociates and loses electrons. Hydrogen ions (protons) are conducted through the electrolyte to the cathode, while electrons are passed through the electrolyte and travel through an external electrical circuit, creating a direct current that can be used to power equipment. At the cathode catalyst, an oxygen molecule combines with an electron (which is supplied from external communications) and an incoming proton, and forms water, which is the only reaction product (in the form of vapor and/or liquid).

Below is the corresponding reaction:

Reaction at the anode: 2H 2 => 4H+ + 4e -
Reaction at the cathode: O 2 + 4H+ + 4e - => 2H 2 O
General reaction of the element: 2H 2 + O 2 => 2H 2 O

Types and variety of fuel elements/cells

Just as there are different types of internal combustion engines, there are different types of fuel cells - choosing the right type of fuel cell depends on its application.

Fuel cells are divided into high temperature and low temperature. Low temperature fuel cells require relatively pure hydrogen as fuel. This often means that fuel processing is required to convert the primary fuel (such as natural gas) into pure hydrogen. This process consumes additional energy and requires special equipment. High temperature fuel cells do not need this additional procedure as they can "internally convert" the fuel at elevated temperatures, meaning there is no need to invest in hydrogen infrastructure.

Molten Carbonate Fuel Cells/Cells (MCFC)

Molten carbonate electrolyte fuel cells are high temperature fuel cells. The high operating temperature allows the direct use of natural gas without a fuel processor and low calorific value fuel gas from industrial processes and other sources.

When heated to a temperature of 650°C, the salts become a conductor for carbonate ions (CO 3 2-). These ions pass from the cathode to the anode, where they combine with hydrogen to form water, carbon dioxide and free electrons. These electrons are sent through an external electrical circuit back to the cathode, generating electric current and heat as a by-product.

Reaction at the anode: CO 3 2- + H 2 => H 2 O + CO 2 + 2e -
Reaction at the cathode: CO 2 + 1/2O 2 + 2e - => CO 3 2-
General reaction of the element: H 2 (g) + 1/2O 2 (g) + CO 2 (cathode) => H 2 O (g) + CO 2 (anode)

The high operating temperatures of molten carbonate electrolyte fuel cells have certain advantages. At high temperatures, natural gas is internally reformed, eliminating the need for a fuel processor. In addition, advantages include the ability to use standard construction materials such as stainless steel sheets and nickel catalyst on the electrodes. The waste heat can be used to generate high pressure steam for a variety of industrial and commercial purposes.

High reaction temperatures in the electrolyte also have their advantages. The use of high temperatures requires significant time to achieve optimal operating conditions, and the system responds more slowly to changes in energy consumption. These characteristics allow the use of fuel cell installations with molten carbonate electrolyte under constant power conditions. High temperatures prevent carbon monoxide from damaging the fuel cell.

Fuel cells with molten carbonate electrolyte are suitable for use in large stationary installations. Thermal power plants with an electrical output power of 3.0 MW are commercially produced. Installations with output power up to 110 MW are being developed.

Phosphoric acid fuel cells/cells (PAFC)

Phosphoric (orthophosphoric) acid fuel cells were the first fuel cells for commercial use.

Phosphoric (orthophosphoric) acid fuel cells use an electrolyte based on orthophosphoric acid (H 3 PO 4) with a concentration of up to 100%. The ionic conductivity of phosphoric acid is low at low temperatures, for this reason these fuel cells are used at temperatures up to 150–220°C.

The charge carrier in fuel cells of this type is hydrogen (H+, proton). A similar process occurs in fuel cells with a proton exchange membrane, in which hydrogen supplied to the anode is split into protons and electrons. Protons travel through the electrolyte and combine with oxygen from the air at the cathode to form water. The electrons are sent through an external electrical circuit, thereby generating an electric current. Below are reactions that generate electric current and heat.

Reaction at the anode: 2H 2 => 4H + + 4e -
Reaction at the cathode: O 2 (g) + 4H + + 4e - => 2 H 2 O
General reaction of the element: 2H 2 + O 2 => 2H 2 O

The high performance of thermal power plants using fuel cells based on phosphoric (orthophosphoric) acid in the combined production of thermal and electrical energy is one of the advantages of this type of fuel cells. The units use carbon monoxide with a concentration of about 1.5%, which significantly expands the choice of fuel. In addition, CO 2 does not affect the electrolyte and the operation of the fuel cell; this type of cell works with reformed natural fuel. Simple design, low degree of electrolyte volatility and increased stability are also advantages of this type of fuel cell.

Thermal power plants with electrical output power of up to 500 kW are commercially produced. The 11 MW installations have passed the appropriate tests. Installations with output power up to 100 MW are being developed.

Solid Oxide Fuel Cells (SOFC)

Solid oxide fuel cells are the highest operating temperature fuel cells. The operating temperature can vary from 600°C to 1000°C, allowing the use of different types of fuel without special pre-treatment. To handle such high temperatures, the electrolyte used is a thin solid metal oxide on a ceramic base, often an alloy of yttrium and zirconium, which is a conductor of oxygen ions (O2-).

The solid electrolyte provides a sealed transition of gas from one electrode to another, while liquid electrolytes are located in a porous substrate. The charge carrier in fuel cells of this type is the oxygen ion (O 2-). At the cathode, oxygen molecules from the air are separated into an oxygen ion and four electrons. Oxygen ions pass through the electrolyte and combine with hydrogen, creating four free electrons. The electrons are sent through an external electrical circuit, generating electric current and waste heat.

Reaction at the anode: 2H 2 + 2O 2- => 2H 2 O + 4e -
Reaction at the cathode: O 2 + 4e - => 2O 2-
General reaction of the element: 2H 2 + O 2 => 2H 2 O

The efficiency of the produced electrical energy is the highest of all fuel cells - about 60-70%. High operating temperatures allow combined production of thermal and electrical energy to generate high pressure steam. Combining a high-temperature fuel cell with a turbine makes it possible to create a hybrid fuel cell to increase the efficiency of generating electrical energy by up to 75%.

Solid oxide fuel cells operate at very high temperatures (600°C–1000°C), resulting in significant time to reach optimal operating conditions and a slower system response to changes in energy consumption. At such high operating temperatures, no converter is required to recover hydrogen from the fuel, allowing the thermal power plant to operate with relatively impure fuels resulting from gasification of coal or waste gases, etc. The fuel cell is also excellent for high power applications, including industrial and large central power plants. Modules with an electrical output power of 100 kW are commercially produced.

Direct Methanol Oxidation Fuel Cells/Cells (DOMFC)

The technology of using fuel cells with direct methanol oxidation is undergoing a period of active development. It has successfully proven itself in the field of powering mobile phones, laptops, as well as for creating portable power sources. This is what the future use of these elements is aimed at.

The design of fuel cells with direct oxidation of methanol is similar to fuel cells with a proton exchange membrane (MEPFC), i.e. A polymer is used as an electrolyte, and a hydrogen ion (proton) is used as a charge carrier. However, liquid methanol (CH 3 OH) oxidizes in the presence of water at the anode, releasing CO 2, hydrogen ions and electrons, which are sent through an external electrical circuit, thereby generating an electric current. Hydrogen ions pass through the electrolyte and react with oxygen from the air and electrons from the external circuit to form water at the anode.

Reaction at the anode: CH 3 OH + H 2 O => CO 2 + 6H + + 6e -
Reaction at the cathode: 3/2O 2 + 6 H + + 6e - => 3H 2 O
General reaction of the element: CH 3 OH + 3/2O 2 => CO 2 + 2H 2 O

The advantage of this type of fuel cells is their small size, due to the use of liquid fuel, and the absence of the need to use a converter.

Alkaline fuel cells/cells (ALFC)

Alkaline fuel cells are one of the most efficient cells used to generate electricity, with power generation efficiency reaching up to 70%.

Alkaline fuel cells use an electrolyte, an aqueous solution of potassium hydroxide, contained in a porous, stabilized matrix. The potassium hydroxide concentration may vary depending on the operating temperature of the fuel cell, which ranges from 65°C to 220°C. The charge carrier in SHTE is the hydroxyl ion (OH -), moving from the cathode to the anode, where it reacts with hydrogen, producing water and electrons. The water produced at the anode moves back to the cathode, again generating hydroxyl ions there. As a result of this series of reactions taking place in the fuel cell, electricity and, as a by-product, heat are produced:

Reaction at the anode: 2H 2 + 4OH - => 4H 2 O + 4e -
Reaction at the cathode: O 2 + 2H 2 O + 4e - => 4 OH -
General reaction of the system: 2H 2 + O 2 => 2H 2 O

The advantage of SHTE is that these fuel cells are the cheapest to produce, since the catalyst required on the electrodes can be any of the substances that are cheaper than those used as catalysts for other fuel cells. SFCs operate at relatively low temperatures and are among the most efficient fuel cells - such characteristics can consequently contribute to faster power generation and high fuel efficiency.

One of the characteristic features of SHTE is its high sensitivity to CO 2, which may be contained in fuel or air. CO 2 reacts with the electrolyte, quickly poisons it, and greatly reduces the efficiency of the fuel cell. Therefore, the use of SHTE is limited to enclosed spaces, such as space and underwater vehicles, they must run on pure hydrogen and oxygen. Moreover, molecules such as CO, H 2 O and CH4, which are safe for other fuel cells, and even act as fuel for some of them, are harmful to SHFC.

Polymer Electrolyte Fuel Cells (PEFC)

In the case of polymer electrolyte fuel cells, the polymer membrane consists of polymer fibers with water regions in which there is conduction of water ions H2O+ (proton, red) attaches to a water molecule). Water molecules pose a problem due to slow ion exchange. Therefore, a high concentration of water is required both in the fuel and at the outlet electrodes, limiting the operating temperature to 100°C.

Solid acid fuel cells/cells (SFC)

In solid acid fuel cells, the electrolyte (CsHSO 4) does not contain water. The operating temperature is therefore 100-300°C. The rotation of the oxy anions SO 4 2- allows the protons (red) to move as shown in the figure. Typically, a solid acid fuel cell is a sandwich in which a very thin layer of solid acid compound is sandwiched between two electrodes that are tightly pressed together to ensure good contact. When heated, the organic component evaporates, exiting through the pores in the electrodes, maintaining the ability of multiple contacts between the fuel (or oxygen at the other end of the element), the electrolyte and the electrodes.

Various fuel cell modules. Fuel cell battery

Fuel cell battery
Other equipment operating at high temperatures (integrated steam generator, combustion chamber, heat balance changer)
Heat resistant insulation

Fuel cell module

Comparative analysis of types and varieties of fuel cells

Innovative energy-efficient municipal heat and power plants are typically built on solid oxide fuel cells (SOFC), polymer electrolyte fuel cells (PEFC), phosphoric acid fuel cells (PAFC), proton exchange membrane fuel cells (PEMFC) and alkaline fuel cells (ALFC). . Typically have the following characteristics:

The most suitable should be considered solid oxide fuel cells (SOFC), which:

operate at higher temperatures, reducing the need for expensive precious metals (such as platinum)
can work for various types hydrocarbon fuels, mainly natural gas
have a longer start-up time and are therefore better suited for long-term action
demonstrate high power generation efficiency (up to 70%)
Due to high operating temperatures, the units can be combined with heat transfer systems, bringing the overall system efficiency to 85%
have virtually zero emissions, operate silently and have low operating requirements compared to existing power generation technologies

Fuel cell type	Working temperature	Power generation efficiency	Fuel type	Application area
RKTE	550–700°C	50-70%		Medium and large installations
FCTE	100–220°C	35-40%	Pure hydrogen	Large installations
MOPTE	30-100°C	35-50%	Pure hydrogen	Small installations
SOFC	450–1000°C	45-70%	Most hydrocarbon fuels	Small, medium and large installations
PEMFC	20-90°C	20-30%	Methanol	Portable
SHTE	50–200°C	40-70%	Pure hydrogen	Space research
PETE	30-100°C	35-50%	Pure hydrogen	Small installations

Since small thermal power plants can be connected to a conventional gas supply network, fuel cells do not require a separate hydrogen supply system. When using small thermal power plants based on solid oxide fuel cells, the heat generated can be integrated into heat exchangers to heat water and ventilation air, increasing the overall efficiency of the system. This innovative technology is best suited to efficiently generate electricity without the need for expensive infrastructure and complex instrument integration.

Application of fuel cells/cells

Application of fuel cells/cells in telecommunication systems

Due to the rapid proliferation of wireless communication systems throughout the world, as well as the increasing socio-economic benefits of mobile phone technology, the need for reliable and cost-effective power backup has become critical. Electricity grid losses throughout the year due to bad weather conditions, natural disasters or limited grid capacity pose an ongoing challenge for grid operators.

Traditional telecom power backup solutions include batteries (valve-regulated lead-acid battery cell) for short-term backup power and diesel and propane generators for longer-term backup power. Batteries are a relatively cheap source of backup power for 1 - 2 hours. However, batteries are not suitable for longer-term backup power because they are expensive to maintain, become unreliable after long periods of use, are sensitive to temperatures, and are hazardous to the environment after disposal. Diesel and propane generators can provide long-term power backup. However, generators can be unreliable, require labor-intensive maintenance, and emit high levels of pollutants and greenhouse gases.

To overcome the limitations of traditional power backup solutions, innovative green fuel cell technology has been developed. Fuel cells are reliable, quiet, contain fewer moving parts than a generator, have a wider operating temperature range than a battery: from -40°C to +50°C and, as a result, provide extremely high levels of energy savings. In addition, the lifetime costs of such an installation are lower than those of a generator. Lower fuel cell costs result from just one maintenance visit per year and significantly higher plant productivity. At the end of the day, the fuel cell is a green technology solution with minimal environmental impact.

Fuel cell installations provide backup power for critical communications network infrastructures for wireless, permanent and broadband communications in the telecommunications system, ranging from 250 W to 15 kW, they offer many unrivaled innovative features:

RELIABILITY– few moving parts and no discharge in standby mode
ENERGY SAVING
SILENCE– low noise level
SUSTAINABILITY– operating range from -40°C to +50°C
ADAPTABILITY– installation outdoors and indoors (container/protective container)
HIGH POWER– up to 15 kW
LOW MAINTENANCE REQUIREMENT– minimal annual maintenance
ECONOMICAL- attractive total cost of ownership
GREEN ENERGY– low emissions with minimal impact on the environment

The system senses the DC bus voltage at all times and smoothly accepts critical loads if the DC bus voltage drops below a user-defined set point. The system runs on hydrogen, which is supplied to the fuel cell stack in one of two ways - either from an industrial hydrogen source or from a liquid fuel of methanol and water, using an integrated reforming system.

Electricity is produced by the fuel cell stack in the form of direct current. The DC power is transferred to a converter, which converts the unregulated DC power coming from the fuel cell stack into high quality regulated DC power for the required loads. Fuel cell installations can provide backup power for many days as the duration is limited only by the amount of hydrogen or methanol/water fuel available.

Fuel cells offer superior energy savings, improved system reliability, more predictable performance in a wide range of climates, and reliable operational durability compared to industry standard valve-regulated lead-acid battery packs. Lifetime costs are also lower due to significantly lower maintenance and replacement requirements. Fuel cells offer environmental benefits to the end user as disposal costs and liability risks associated with lead-acid cells are a growing concern.

The performance of electric batteries can be adversely affected by a wide range of factors such as charge level, temperature, cycling, life and other variables. The energy provided will vary depending on these factors and is not easy to predict. The performance of a proton exchange membrane fuel cell (PEMFC) is relatively unaffected by these factors and can provide critical power as long as fuel is available. Increased predictability is an important benefit when moving to fuel cells for mission-critical backup power applications.

Fuel cells generate power only when fuel is supplied, similar to a gas turbine generator, but have no moving parts in the generation area. Therefore, unlike a generator, they are not subject to rapid wear and do not require constant maintenance and lubrication.

The fuel used to drive the extended duration fuel converter is a fuel mixture of methanol and water. Methanol is a widely available, commercially produced fuel that currently has many uses, including windshield washer, plastic bottles, engine additives, emulsion paints. Methanol is easily transported, can be mixed with water, has good biodegradability and does not contain sulfur. It has a low freezing point (-71°C) and does not decompose during long-term storage.

Application of fuel cells/cells in communication networks

Secure communications networks require reliable backup power solutions that can operate for hours or days in emergency situations if the power grid is no longer available.

With few moving parts and no standby power loss, innovative fuel cell technology offers an attractive solution to current backup power systems.

The most compelling argument for using fuel cell technology in communications networks is the increased overall reliability and safety. During events such as power outages, earthquakes, storms and hurricanes, it is important that systems continue to operate and are provided with reliable backup power over an extended period of time, regardless of temperature or the age of the backup power system.

The line of fuel cell-based power devices are ideal for supporting classified communications networks. Thanks to their energy-saving design principles, they provide environmentally friendly, reliable backup power with extended duration (up to several days) for use in the power range from 250 W to 15 kW.

Application of fuel cells/cells in data networks

Reliable power supply for data networks, such as high-speed data networks and fiber optic backbones, is of key importance throughout the world. The information transmitted over such networks contains critical data for institutions such as banks, airlines or medical centers. A power outage in such networks not only poses a danger to the transmitted information, but also, as a rule, leads to significant financial losses. Reliable, innovative fuel cell installations that provide backup power supply provide the reliability needed to ensure uninterrupted power supply.

Fuel cell units, powered by a liquid fuel mixture of methanol and water, provide reliable backup power with extended duration, up to several days. In addition, these units have significantly reduced maintenance requirements compared to generators and batteries, requiring only one maintenance visit per year.

Typical application site characteristics for using fuel cell installations in data networks:

Applications with power consumption quantities from 100 W to 15 kW
Applications with battery life requirements > 4 hours
Repeaters in fiber optic systems (hierarchy of synchronous digital systems, high-speed Internet, voice over IP...)
Network nodes for high-speed data transmission
WiMAX transmission nodes

Fuel cell power backup installations offer numerous benefits for mission-critical data network infrastructures compared to traditional battery or diesel generators, allowing for increased on-site deployment options:

Liquid fuel technology solves the problem of hydrogen placement and provides virtually unlimited backup power.
Thanks to their quiet operation, low weight, resistance to temperature changes and virtually vibration-free operation, fuel cells can be installed outside buildings, in industrial buildings/containers or on rooftops.
Preparations for the use of the system on site are quick and economical, and operating costs are low.
The fuel is biodegradable and provides an environmentally friendly solution for urban environments.

Application of fuel cells/cells in security systems

The most carefully designed building security and communications systems are only as reliable as the power supply that supports them. While most systems include some type of uninterruptible power backup system for short-term power losses, they do not accommodate the longer-term power outages that can occur after natural disasters or terrorist attacks. This could be a critical issue for many corporate and government agencies.

Vital systems such as CCTV access monitoring and control systems (ID card readers, door lock devices, biometric identification technology, etc.), automatic fire alarm and fire extinguishing systems, elevator control systems and telecommunication networks, are at risk in the absence of a reliable, long-lasting alternative power supply.

Diesel generators make a lot of noise, are difficult to locate, and have well-known reliability and maintenance problems. In contrast, a fuel cell installation that provides backup power is quiet, reliable, produces zero or very low emissions, and can be easily installed on a rooftop or outside a building. It does not discharge or lose power in standby mode. It ensures the continued operation of critical systems, even after the facility ceases operations and the building is vacated.

Innovative fuel cell installations protect expensive investments in critical applications. They provide environmentally friendly, reliable backup power with extended duration (up to many days) for use in the power range from 250 W to 15 kW, combined with numerous unrivaled features and, especially, high levels of energy savings.

Fuel cell power backup installations offer numerous advantages for use in mission-critical applications such as security and building control systems over traditional battery-powered or diesel generator applications. Liquid fuel technology solves the problem of hydrogen placement and provides virtually unlimited backup power.

Application of fuel cells/cells in municipal heating and power generation

Solid oxide fuel cells (SOFCs) provide reliable, energy-efficient, and emission-free thermal power plants to generate electricity and heat from widely available natural gas and renewable fuel sources. These innovative installations are used in a variety of markets, from home power generation to remote power supply, as well as auxiliary power supplies.

Application of fuel cells/cells in distribution networks

Small thermal power plants are designed to operate in a distributed power generation network consisting of a large number of small generator sets instead of one centralized power plant.

The figure below shows the loss in efficiency of electricity generation when it is generated at a thermal power plant and transmitted to homes through the traditional power transmission networks currently in use. Efficiency losses in centralized generation include losses from the power plant, low-voltage and high-voltage transmission, and distribution losses.

The figure shows the results of the integration of small thermal power plants: electricity is generated with generation efficiency of up to 60% at the point of use. In addition to this, a household can use the heat generated by the fuel cells to heat water and space, which increases the overall efficiency of fuel energy processing and increases energy savings.

Use of fuel cells to protect the environment - utilization of associated petroleum gas

One of the most important tasks in the oil industry is the utilization of associated petroleum gas. Existing methods of utilizing associated petroleum gas have a lot of disadvantages, the main one being that they are not economically viable. Associated petroleum gas is burned, which causes enormous harm to the environment and human health.

Innovative thermal power plants using fuel cells using associated petroleum gas as fuel open the way to a radical and cost-effective solution to the problems of associated petroleum gas utilization.

One of the main advantages of fuel cell installations is that they can operate reliably and stably on associated petroleum gas of variable composition. Due to the flameless chemical reaction that underlies the operation of the fuel cell, a decrease in the percentage of, for example, methane only causes a corresponding decrease in power output.
Flexibility in relation to the electrical load of consumers, drop, load surge.
For the installation and connection of thermal power plants on fuel cells, their implementation does not require capital costs, because The units can be easily installed on unprepared sites near fields, are easy to use, reliable and efficient.
High automation and modern remote control do not require permanent presence of personnel at the installation.
Simplicity and technical perfection of the design: the absence of moving parts, friction, and lubrication systems provides significant economic benefits from the operation of fuel cell installations.
Water consumption: none at ambient temperatures up to +30 °C and negligible at higher temperatures.
Water outlet: none.
In addition, thermal power plants using fuel cells do not make noise, do not vibrate, do not produce harmful emissions into the atmosphere