1. Hydrogen fuel cell industry chain In the hydrogen fuel cell industry
chain, the upstream is the production, transportation and storage of hydrogen,
and the filling of hydrogen fuel cell systems with hydrogen at hydrogen
refueling stations; the midstream is the production of key components such as
stacks. In production, the stack and accessories are integrated to form a
hydrogen fuel cell system; at the downstream application level, there are mainly
three directions: transportation, portable power supply and fixed power
supply.
2. Comparison of the advantages and disadvantages of power batteries
Currently, there are four main technical routes in terms of power sources for
transportation: lithium-ion batteries, hydrogen fuel cells, supercapacitors and
aluminum-air batteries. Among them, lithium-ion batteries, supercapacitors and
hydrogen fuel cells are widely used, while aluminum-air batteries are still in
the laboratory research stage. In terms of energy supply, lithium-ion batteries
and supercapacitors are suitable for pure electric vehicles, but require
external charging, while hydrogen fuel cell vehicles require external hydrogen
filling, and aluminum-air batteries require replenishing aluminum plates and
electrolytes.
Comparison of the advantages and disadvantages of four technical routes 1
Hydrogen fuel cell characteristics (1) Good environmental compatibility Hydrogen
fuel cells provide efficient and clean energy. The water they emit is not only
small, but also very clean, so there is no water pollution problem. At the same
time, because the fuel cell does not need to convert thermal energy into
mechanical energy like an engine, but directly converts chemical energy into
electrical energy and thermal energy, it has high energy conversion efficiency
and low noise. (2) Hydrogen fuel cell power generation with good operating
performance does not require complex and bulky configuration equipment, and the
battery stack can be assembled in a modular manner. For example, a 4.5MW power
generation device can be composed of 460 battery modules, and its power plant
occupies a much smaller area than a thermal power plant. Hydrogen fuel cells are
suitable as distributed power generation devices. In addition, compared with
thermal, hydropower and nuclear power generation, hydrogen fuel cell power
plants have a short construction period and are easy to expand, and can be
constructed in phases based on actual needs. At the same time, hydrogen fuel
cells have high operating quality and excellent characteristics in responding to
rapid changes in load (such as peak loads). They can convert from low power to
rated power in a few seconds. (3) Efficient output performance When the hydrogen
fuel cell works, it converts the energy stored in the fuel into electricity and
heat. The efficiency of converting electrical energy is more than 40%, while
only 1/3 of the steam turbine can be converted into electricity. (4) Flexible
structural characteristics Hydrogen fuel cells are very flexible to assemble,
and the power is easy to adjust. Compared with traditional engines, due to the
good modularity of hydrogen fuel cells, hydrogen fuel cells can be added or
reduced by increasing or decreasing the number of single cells without
increasing infrastructure investment. The output power and voltage can be
adjusted easily with just a few chips, so it is easy to build and it is
relatively easy to control the power grid. This feature of fuel cells improves
system stability. (5) Hydrogen comes from a wide range of sources. As a
secondary energy, hydrogen can be obtained through various methods, such as
hydrogen production from coal, hydrogen production from natural gas reforming,
hydrogen production from water electrolysis, etc. When fossil energy is
exhausted, hydrogen will become the world's main fuel and energy source. The use
of solar energy to electrolyze water to produce hydrogen has no carbon emissions
in the process, and hydrogen can be considered the ultimate energy source. (6)
Existing bottlenecks From the current stage of development, the popularization
of hydrogen fuel cells has encountered certain bottlenecks, such as the high
cost of the battery itself and the lack of popular infrastructure. 2 Lithium-ion
battery characteristics (1) Voltage platform Due to the different positive and
negative electrode materials used in lithium-ion batteries, the operating
voltage range of its single cell is 3.7~4V. Among them, the operating voltage of
the lithium iron phosphate single cell with larger application scale is 3.2V,
which is 3 times that of nickel-metal hydride batteries and 2 times that of
lead-acid batteries. (2) Large specific energy. The current energy density of
passenger car lithium-ion power batteries is close to 200Wh/kg, and is expected
to reach 300Wh/kg in 2020. (3) Short battery life. Due to the constraints of
electrochemical material characteristics, there has been no breakthrough in the
number of cycles of lithium-ion batteries. Taking lithium iron phosphate as an
example, the number of cycles of a single battery can reach more than 2,000
times, and the number of cycles in a group can only be more than 1,000 times. .
It cannot meet the requirement of 8 years of bus operation. (4) Large impact on
the environment Lithium-ion batteries use light metal lithium. Although they do
not contain harmful heavy metals such as mercury and lead, they are considered
green batteries and have less environmental pollution. But in fact, because its
positive and negative electrode materials and electrolytes contain nickel,
manganese and other metals, the United States has classified lithium-ion
batteries as a battery that contains toxic and harmful properties such as
flammability, leaching toxicity, corrosiveness, and reactivity. It is the
battery that contains the most toxic substances among all types of batteries at
present, and because its recycling process is more complicated and the cost is
higher, the current recycling rate is not high, and discarded batteries have a
greater impact on the environment. (5) The cost is still high. The initial
purchase cost of lithium-ion batteries is high. Taking the current mainstream
product of bus power batteries, lithium iron phosphate batteries, as an example,
the price is about 2,500 yuan/kWh. With the popularity of electric vehicles, it
is expected to be Reduced to less than 1,000 yuan/kWh. Due to the restriction of
the number of cycles of single batteries after being assembled, buses usually
need to replace batteries in about three years, which puts great pressure on
operating unit costs. (6) Large impact on the power grid. First of all, when
pure electric vehicles are used on a large scale, due to the large charging
demand, the harmonic interference of charging equipment on the power grid will
be prominent, affecting the power supply quality of the power grid; secondly,
during fast charging, due to the large Multiply charging, so the charging power
is high (passenger cars are around 50kW, buses are around 150~250kW), which has
a greater impact on the load of the power grid. Therefore, based on the current
technical level of lithium-ion batteries, its application in electric vehicles
is mainly in short-distance pure electric vehicles with a driving range of less
than 200km. 3 Supercapacitor characteristics (1) Extremely high charge and
discharge rates. Supercapacitors have high power density and can discharge
hundreds to thousands of amps in a short time. They can charge quickly, within
tens of seconds to minutes. Complete the charging process. Supercapacitor buses
and trams use this feature to complete charging in a short time and drive the
vehicle forward. (2) Long cycle life: Supercapacitors have very little loss
during the charging and discharging process, so theoretically their cycle life
is infinite. In fact, it can reach more than 100,000 times, which is 10 to 100
times higher than that of batteries. (3) Supercapacitors have good
low-temperature performance. Most of the charge transfer that occurs during the
charging and discharging process of supercapacitors occurs on the surface of the
electrode active material, so the capacity attenuation with temperature is very
small. In general, the capacity attenuation of lithium-ion batteries at low
temperatures is even as high as 70%. . (4) Energy density is too low. One of the
bottlenecks in the application of supercapacitors is that the energy density is
too low, which is only about 1/20 of that of lithium-ion batteries, about
10Wh/kg. Therefore, it cannot be used as the main power supply of electric
vehicles, but is mostly used as auxiliary power supply, mainly used for quick
start devices and braking energy recovery devices. 4 Characteristics of
aluminum-air batteries (1) Low material cost and high energy density. The
negative active material of aluminum-air batteries is rich metallic aluminum,
which is cheap and environmentally friendly. The positive active material is
oxygen in the air, and the positive capacity can be infinite. Therefore,
aluminum-air batteries have the advantages of light weight, small size and long
service life. (2) Key technologies have not made breakthroughs and have not yet
left the laboratory. Problems such as air electrode polarization and aluminum
hydroxide sedimentation are important obstacles affecting the marketization of
metal-air batteries. The improvement of aluminum-air battery performance has
encountered a big bottleneck.
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