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Review

A Review of Hydrogen Purification Technologies for Fuel Cell Vehicles

1
Tianjin Key Laboratory of Membrane and Desalination Technology, School of Chemical Engineering and Technology, Tianjin University, Tianjin 300350, China
2
National Institute of Clean-and-Low-Carbon Energy, Future Science City, Changping District, Beijing 102211, China
3
China Energy Hydrogen Technology, Guohua Investment Building, 3 South Street, Dongcheng District, Beijing 100007, China
*
Authors to whom correspondence should be addressed.
These authors contributed equally to this work.
Catalysts 2021, 11(3), 393; https://doi.org/10.3390/catal11030393
Submission received: 26 February 2021 / Revised: 17 March 2021 / Accepted: 18 March 2021 / Published: 19 March 2021

Abstract

:
Nowadays, we face a series of global challenges, including the growing depletion of fossil energy, environmental pollution, and global warming. The replacement of coal, petroleum, and natural gas by secondary energy resources is vital for sustainable development. Hydrogen (H2) energy is considered the ultimate energy in the 21st century because of its diverse sources, cleanliness, low carbon emission, flexibility, and high efficiency. H2 fuel cell vehicles are commonly the end-point application of H2 energy. Owing to their zero carbon emission, they are gradually replacing traditional vehicles powered by fossil fuel. As the H2 fuel cell vehicle industry rapidly develops, H2 fuel supply, especially H2 quality, attracts increasing attention. Compared with H2 for industrial use, the H2 purity requirements for fuel cells are not high. Still, the impurity content is strictly controlled since even a low amount of some impurities may irreversibly damage fuel cells’ performance and running life. This paper reviews different versions of current standards concerning H2 for fuel cell vehicles in China and abroad. Furthermore, we analyze the causes and developing trends for the changes in these standards in detail. On the other hand, according to characteristics of H2 for fuel cell vehicles, standard H2 purification technologies, such as pressure swing adsorption (PSA), membrane separation and metal hydride separation, were analyzed, and the latest research progress was reviewed.

1. Introduction

Energy resource depletion and global warming are severe challenges of our modern society. The transportation industry plays an essential role in energy consumption and greenhouse gas emissions. According to the International Energy Agency (IEA), it was responsible for 29% of global energy consumption in 2017 and 25% of global carbon dioxide emission in 2016 [1]. Hydrogen (H2) fuel cells provide zero pollutant discharge. The authorities in many countries have strongly supported the production of fuel cell vehicles, and this initiative will inevitably become the future developmental direction in the automotive industry. The USA was the first country that set H2 energy and fuel cells as a long-term energy strategy. There were 5899 fuel cell vehicles in the USA by the end of 2018 [2]. Concerning the promotion of H2 fuel cell vehicles, Japanese and South Korean companies were pioneers in large-scale mass production, successfully launching various mass-produced vehicles, such as Toyota Mirai, Honda Clarity, and Hyundai Nexo [3]. Since then, four automobile group alliances have gradually been formed, including Daimler, Ford, and Renault–Nissan, General Motors and Honda, Bayerische Motoren Werke (BMW) and Toyota, and Audi and Hyundai. The alliances invested joint effort in developing H2 fuel cell vehicle technologies, and accelerated their commercialization. The Shanghai Automotive Industry Corporation of China launched the fourth fuel cell vehicle using a Roewe 950 vehicle with a 400 km driving range without refueling, demonstrating its capacity for small-scale production [4].
H2 fuel cells mainly include phosphoric acid fuel cells (PAFCs), molten carbonate fuel cells (MCFCs), solid oxide fuel cells (SOFCs), alkaline fuel cells (AFCs), and proton-exchange membrane fuel cells (PEMFCs) [5]. PEMFCs are dominant since they possess a high power density, low-temperature start, and compact structure, representing an ideal power source for H2 fuel cell vehicles. On the other side, PEMFCs require high-purity H2. Otherwise, the fuel cell performance and running life may be severely affected [6]. Currently, H2 production technologies, such as coal gasification, natural gas steam reforming, methanol reforming, and water electrolysis, are very well established in China [7]. According to statistical data from the China Hydrogen Alliance and China National Petroleum and Chemical Planning Institute, the current H2 production capacity in China is approximately 41 million tons/year, with a yield of 33.42 million tons. Specifically, the yield of H2 as an independent component (synthetic gas not containing H2), which meets the quality standards of H2 for industrial use and can be directly sold as industrial gas, is about 12.7 million tons/year. Among these, the H2 yield produced from coal is the highest (21.24 million tons), accounting for 63.54%, followed by H2 produced from by-product gas (7.08 million tons), natural gas (4.6 million tons), and electrolyzed water (0.5 million tons). However, the H2 contributions from supercritical steam coal [8], photocatalytic water decomposition with solar energy [9], and biological H2 production [10] are still in the research and developmental stage (Table 1). Different raw materials yield large differences in the composition and impurity contents of H2 produced using various technologies. Thus, efficient H2 purification technologies that enable the removal of impurities from H2 and provide high-qualify H2 for fuel cell vehicles are of the utmost importance for developing the H2 fuel cell vehicle industry.
To support large-scale applications of H2 energy in the transportation field, novel and high-efficient purification technologies for the production of low-cost and high-quality H2 should be urgently developed. In this study, the characteristics of standard H2 purification technologies, such as pressure swing adsorption (PSA), membrane separation and metal hydride separation, were analyzed. Research progress was reviewed according to the characteristics of H2 for fuel cell vehicles. To further improve the separation efficiency, it is necessary to continuously conduct studies on the novel and highly selective adsorption materials, long-lasting and low-cost membrane materials, anti-poisoning metal hydride materials with a low regeneration energy consumption, as well as new separation and coupling processes based on the materials mentioned above.

2. H2 Standards for Fuel Cell Vehicles

The International Organization for Standardization (ISO) issued the ISO 14687-2:2012 standard in 2012, and the Society of Automotive Engineers (SAE) issued the SAE J2719-201511 standard in 2015, presenting the same requirements for H2 quality for PEMFCs. Until 2019, China was following the GB/T 3634.2-2011 Hydrogen Part 2: Pure Hydrogen, High-Pure Hydrogen, and Ultrapure Hydrogen standard. However, this standard was aimed at industrial H2 use, limiting the impurity content only partly, without specific regulations on other impurities that may affect H2 fuel cells’ performance. Therefore, by the end of 2018, China set the GB/T 37244-2018 Fuel Specification for Proton Exchange Membrane Fuel Cell Vehicles—Hydrogen standard, which was in line with ISO 14687-2:2012 and SAE J2719-201511 standards, regulating the concentration of fourteen impurities: water (H2O), total hydrocarbon (HC) (by methane), oxygen (O2), helium (He), nitrogen (N2), argon (Ar), carbon dioxide (CO2), carbon monoxide (CO), total sulfide (by H2S), formaldehyde (HCHO), formic acid (HCOOH), ammonia (NH3), total halide (by halide ions), and maximum particulate matter. The PEMFC technology was remarkably improved, e.g., a lower Pt usage, thinner electrolyte membrane, and higher operating electric current density and lower humidity, so it is necessary to reconsider the previously set impurity limit in H2. The ISO technical committee for H2 energy, IOS/TC 197, issued the ISO 14687:2019 standard in November 2019, combining and revising three H2 fuel cell-related standards, namely, ISO 14687-1, ISO 14687-2, and ISO 14687-3. Meanwhile, according to the ISO 14687:2019 standard, the SAE issued the SAE J2719-202003 standard in March 2020, extending the limit of CH4, N2, Ar, and HCHO impurities. Table 2 shows the requirements for the impurity content in H2 for fuel cells, including previous and new standards in China and abroad.

3. The Impact of Impurities on Fuel Cells

As shown in Table 1, compared with H2 for industrial applications, the requirements for H2 purity for fuel cells are not high. Still, the impurity content is strictly controlled, determined by fuel cells’ structure and operating characteristics. For instance, even a low CO content may cause irreversible damage to the performance and running life of fuel cells. Table 3 shows the impact of excessive impurities on fuel cells.

4. H2 Purification Technology

H2 purification technology is a crucial link from H2 production to H2 utilization. Stable, reliable, and low-cost H2 sources represent a base for large-scale applications of fuel cell vehicles. Thus, high-efficient and low-power H2 purification technologies for fuel cell vehicles play an underlying role in the development of the H2 energy industry.
A fuel cell power system can operate efficiently only if high-quality H2 is provided. H2 produced in coal gasification, natural gas reforming, by-product H2, or from water electrolysis, is collectively referred to as crude hydrogen. It cannot be directly used for fuel cell vehicles without purification according to the existing standards. The composition of different types of crude H2 is listed in Table 4. The H2 purification methods can be mainly classified as physical and chemical methods [21]. The former include adsorption methods [PSA, temperature swing adsorption (TSA), and vacuum adsorption], low-temperature separation methods (cryogenic distillation and low-temperature adsorption), and membrane separation methods (inorganic membrane and organic membrane), while the latter involve a metal hydride separation and catalysis method (Figure 1). The selection of an appropriate H2 purification method is closely related to the hydrogen supply mode and gas source. For H2 production by centralized large-scale coal gasification and natural gas reforming with an H2 supply amount ≥10,000 Nm3/h, PSA purification is primarily adopted after transformation, desulfurization, and decarbonization. The PSA technology has been around for a while, and is characterized by low operation costs and a long service life. However, the H2 for fuel cell vehicles produced via traditional PSA with a standard impurity content results in a decreased recovery rate and yield. It is also not cost-efficient due to low requirements for specific impurity removal (e.g., CO ≤ 0.2 ppm). Cryogenic distillation is also applicable to large-scale production, but standard H2 purity is 85–99%, which does not satisfy the application requirements. For H2 production by centralized by-product mode with an H2 supply of 1000–10,000 Nm3/h, versatile processes should be applied based on different impurities to improve the H2 recovery efficiency. For example, an organic membrane combined with a PSA process is used for obtaining methanol purge gas, while a two-stage or multi-stage PSA process is adopted for obtaining coke oven gas and by-product gas from the refinery. Concerning such small-scale on-site distributed H2 production scenarios, with the H2 supply ≤ 1000 Nm3/h and vehicle H2 supply, traditional PSA separation shows the disadvantages of large floor area, inflexibility, and low adaptability. Hence, low-temperature adsorption, metal hydride, and metal membrane separations are available processes according to the types and amounts of impurities. Low-temperature adsorption can effectively eliminate multiple impurities, such as sulfide, HCHO, and HCOOH. However, it requires high energy consumption, and it is a complex process suitable for special small-scale and cold source applications [22]. Metal hydride separation and palladium (Pd) membrane separation methods are reasonably effective in separating gas sources with a high content of inert components. At the same time, their inherent disadvantage is that purified materials react with impure gas during the H2 recovery, reducing the purification efficiency [23]. New membrane technologies, such as carbon molecular sieve membranes (CMSMs) [24], ionic liquid membranes [25], and electrochemical H2 pump membranes [26], are currently hot spots in scientific research. However, their industrial-scale implementation is still hard to foresee.

4.1. PSA Methods

Gas separation and purification by PSA are implemented by periodical pressure changing based on the difference in the adsorbent capacity for different gases. The PSA separation effect primarily depends on the type of adsorbent and the technical process used. H2 significantly differs from the majority of gas molecules, such as CO2, CO, and CH4, in terms of static capacity, so it is very suitable for PSA separation and purification [34]. Air Product, Air Liquid, and other renowned global gas companies, are already established and very successful examples for the industrial application of H2.
Traditional adsorbents include zeolite molecular sieves, activated carbon, activated alumina, and silica gel. Modifications and innovations of these adsorbents were reported in regard to different impurities, and most of the studies focused on CO2 removal. Lively et al. [35] used hollow fibers as an adsorbent to investigate the CO2 removal in PSA experimental devices. The purity of the obtained H2 was 99.2% pure, with a recovery rate of 88.1%, and this needs to be optimized. Shamsudin et al. [36] increased the H2 purity to about 100% and the recovery rate to 88.43% via the strong CO2 absorption of palm shell charcoal. He et al. [37] reported a structured activated carbon system applied to rapid PSA (RPSA) using a dip-coated Ni foam framework. Under the working conditions of 0.4 MPa and 200 mL/min, the adsorption rate constant K was 0.0029 s1, which was about two times higher than that of traditional adsorbents. The material exhibited a better CO2 adsorption effect in H2. Moreover, Kuroda et al. [38] applied hydroxyl aluminum silicate clay (HAS-Clay) to purify the H2 produced by biomass, and found a relatively high adsorption selectivity to CO2. This adsorbent is also applicable for the adsorption and separation of H2S. Metal-organic frameworks (MOFs) are recently developed materials with easily adjustable structures and properties, and they are ideal novel adsorption materials. Agueda et al. [39] utilized UTSA-16 as an adsorbent to remove the CO2 impurities, and simulated the PSA process of the steam methane reforming of tail gas. The results revealed a H2 purity up to 99.99–99.999%, a recovery rate of 93–96%, and a yield of 2–2.8 mol/kg/h.
Researchers are trying to develop novel adsorbents for the simultaneous removal of multiple impurities in H2. Brea et al. [40] synthesized a raw material NaX molecular sieve within CaX and MgX molecular sieves using an ion-exchange method. They conducted an adsorption simulation for the H2/CH4/CO/CO2 gas mixture and showed that these three adsorbents could yield H2 with a purity higher than 99.99%. The CaX molecular sieve application exhibited the highest recovery rate and yield of H2. Besides this, Banu et al. [41] compared the performances of four kinds of MOF adsorbents (UiO-66(Zr), UiO-66(Zr)-Br, UiO-67(Zr), and Zr-Cl2AzoBDC) and discovered that UiO-66(Zr)-Br had the best purification effect on H2 produced via methane steam reforming. Relvas et al. [42] prepared a novel Cu-AC-2 adsorbent to process the H2/CH4/CO/CO2 gas mixture. The H2 purity exceeded 99.97%, while the CO content declined to 0.17 ppm, reaching the H2 standards required for fuel cell vehicles.
The improvement and optimization of the PSA process are crucial ways to increase the H2 purification efficiency. The flow scheme of the classical PSA system is shown in Figure 2. Ahn et al. [43] used a two-bed PSA and a four-bed PSA to recover H2 from coal gas with N2 as a major impurity. The four-bed PSA process’ performance was superior to that of the two-bed PSA process, yielding a H2 purity of 96–99.5% and a recovery rate of 71–85%. Abdeljaoued et al. [44] established a four-bed PSA theoretical model and performed a twelve-step four-bed PSA experiment at room temperature. They investigated the removal of impurities from H2 produced by ethanol steam reforming for fuel cell vehicles. Further optimization was expected to increase the H2 recovery rate above 75%, providing a CO concentration lower than 20 ppm. Moon et al. [45] investigated the eight-bed PSA process. Considering that a H2 purity of 99.99%, the highest H2 recovery rate was 89.7%, which was approximately 11% higher than that of a four-bed PSA process. Moreover, Zhang et al. [46] established the five-step one-bed and six-step two-bed PSA cycle models, and compared them in terms of purity, recovery rate, and yield of H2. The recovery rate and the yield of the two-bed PSA process were 11% and 1 mol/kg/h, respectively, higher than those of the one-bed PSA process. Li et al. [47] explored the effects of adsorption pressure, adsorption time, and P/F ratio on PSA. They designed a six-step two-bed PSA process for the purification of H2 produced by methane steam reforming, and the produced H2 exhibited a purity and a rate of more than 99.95% and 80%, respectively. When the CH4 concentration in impurities was high, it was necessary to increase the adsorption pressure to ensure the purity of the H2. Yáñez et al. [32] developed a four-bed PSA device with a 5 Å molecular sieve as an adsorbent for purification of H2 from synthetic ammonia tail gas (H2:N2:CH4:Ar = 58:25:15:2). It was indicated that the H2 purity was up to 99.25–99.97%, while the recovery rate was 55.5–75.3%.
The improvement of process flow based on conventional PSA is an important research direction for increasing the H2 purity and recovery rate. Vacuum PSA (VPSA) can forcibly desorb impurities with a strong adsorption capacity from adsorbents via vacuum pumping in order to regenerate adsorbents. You et al. [48] showed that the VPSA and PSA could produce H2 with a similar purity level under the same conditions, but the recovery rate was increased by about 10% during VPSA. Besides this, Lopes et al. [49] performed an experiment on rapid VPSA (RVPSA), and the results illustrated that RVPSA was able to improve the H2 yield by nearly 410% compared with PSA. Golmakani et al. [50] conducted a comparative study on PSA, VPSA, and TSA processes, and discovered that the VPSA process could yield the H2 for fuel cell vehicles with a reasonable cost-efficiency and recovery rate, proposing it as the best option among the three investigated processes. Furthermore, Golmakani et al. [51] established a sixteen-step four-bed VPSA model. They studied the influence of N2 on the process’ performance so as to enhance the recovery rate of H2 produced by VPSA and decrease the energy consumption.
Many novel PSA devices are currently in the development or implementation phase for different impurities and H2 utilization demands. Thus, Air Products [52] has investigated and developed a novel PSA device, named Sour PSA, to capture the acidic impurities, such as CO2 and sulfides, in H2. Majlan et al. [53] designed a compact PSA (CPSA) system with a rapid circulation rate to provide H2 continuously without the need for adsorbent regeneration. Moreover, it could reduce CO concentration in the H2/CO/CO2 gas mixture from 4000 to 1.4 ppm, and the CO2 concentration from 5% to 7 ppm, yielding H2 with a purity of 99.999%. Zhu et al. [54] proposed a seven-step two-bed elevated-temperature PSA (ET-PSA) system to separate the feed gas CO/CO2/H2O/H2 under proper conditions. In this way, H2 with a purity of 99.9991% and a recovery rate of 99.6% was obtained. As such, the system was applicable to the removal of CO and CO2 from H2. A summary of the PSA technology is shown in Table 5.

4.2. Membrane Separation Methods

As an emerging gas separation technology, membrane separation has the advantages of flexible and simple operation, compact structure, low energy consumption, and environmental friendliness. In the membrane separation technology with a perm-selective membrane as a separation medium, the raw material components can selectively permeate the membrane under the action of driving forces (pressure difference, concentration difference, and potential difference), thereby achieving separation and purification [55]. The performance of membrane materials is the most critical factor determining the H2 separation and purification effects of the membrane. Commonly used membrane materials primarily include metal and polymer membranes, and novel membrane materials, such as nanomaterial membrane, CMSM, and MOF membranes, may exhibit preferable separation performance. Therefore, the performance of these membrane materials in the H2 purification is analyzed and evaluated below.

4.2.1. Metal Membranes

H2 is catalyzed to protons and electrons on the compact structure of metal membranes. The protons pass through the metal membrane and bind electrons on the other side to form H2 again. However, the metal membrane blocks CO2, N2, CH4, and O2 gas molecules, thereby achieving the selective permeation of H2. Pd membranes are currently the most commonly used metal membranes, due to their excellent H2 permeability, and their high resistance to H2 fluidity and auto-catalytic hydrogenolysis reactions [56]. However, the Pd membrane is related to high manufacturing costs, and it is prone to H2 embrittlement at a low temperature.
A Pd alloy membrane can be formed by adding other metal elements (Ag, Au, Cu, Ni, Y, etc.) into the Pd membrane to solve the H2 embrittlement problem, enlarge the Pd lattice, and increase the H2 permeation rate at the same time. Nayebossadri et al. [57] studied the performance of H2 in natural gas separated by Pd, PdCu53, and PdAg24 membrane materials at different concentrations. They found that the H2 permeability of the PdAg24 membrane is better than that of the other two membranes. Zhao et al. [58] prepared a bilayer bcc–PdCu alloy membrane by the alternative electrodeposition of Pd and Cu on a ceramic support membrane. The membrane exhibited excellent low-temperature tolerance and H2 permeability, and it is a candidate membrane material for H2 separation at ambient temperature.
Both pure Pd membranes and Pd alloy membranes are self-supporting membranes. Their thickness is limited from several tens to several hundreds of micrometers to assure sufficient mechanical strength. When the membrane thickness is too high, it increases the total cost and lowers the H2 permeation rate. As such, it is possible to deposit a Pd membrane or a Pd alloy membrane on the surface of a porous material to prepare a supported Pd composite membrane. The support increases the mechanical strength of the Pd membrane and decreases the Pd amount and membrane thickness, which is beneficial to the total cost and the H2 permeation rate, as described above. Kong et al. [59] deposited a nanoscale Pd membrane on polybenzimidazole-4,4′-(hexafluoroisopropylidene)-bis(benzoic acid) (PBI-HFA) using the vacuum electroless plating (VELP) technique. The novel Pd/PBI-HFA composite membrane completely prevented CO permeation and exhibited good H2/N2 and H2/CO2 selectivity. Kiadehi et al. [60] deposited a NaY molecular sieve and a Pd membrane on porous stainless-steel substrates. The permeation of the H2 and N2 mixture into the prepared Pd/NaY/PSS composite membrane was tested, showing that the membrane’s H2/N2 selectivity was 736 at 450 °C. Moreover, Iulianelli et al. [61] prepared a supported Pd70-Cu30/γ-Al2O3 thin membrane using the metal vapor synthesis method. The membrane showed H2/N2 and H2/CO2 selectivity of 1800 and 6500, respectively, at 400 °C and 50 kPa. Huang et al. [62] used natural mineral Nontronite-15A as a surface coating material of porous Al2O3 to prepare a Pd/Nontronite-15A/Al2O3 membrane, lowering the production cost compared to other composite membranes that provide high H2 permeability.
The permeation ability of Pd H2 is not the strongest among metals. It has been recently indicated that vanadium group metals, V, Nb, and Ta, have different bcc lattice structures, higher H2 permeability and mechanical strength, and weaker H2 dissociation and adsorption ability than Pd [63]. However, a compact oxide layer forms on the surface, preventing H2 permeation. As a result, the H2 permeation rate of the thin membrane is not very high, although vanadium group metals have a strong lattice H2 permeation ability. Besides this, these metals are more susceptive to H2 embrittlement than Pd. A useful approach toward this problem was depositing an extremely thin Pd layer plated on both sides of the vanadium group metals to form symmetric composite membranes. In that way, the H2 adsorption and dissociation ability of the Pd membrane was combined with the H2 permeation ability of the vanadium group metals, lowering the total cost. Dolan et al. [64] prepared a Pd-coated vanadium membrane with a tubular structure, and this revealed a high H2 permeability and stability, suitable for H2 separation for fuel cell vehicles. Fasolin et al. [65] applied high-power pulse magnetron sputtering technology to prepare a Pd/V93Pd7/Pd multilayer membrane with a total thickness less than 7 μm on the surface of porous alumina. Besides this, research studies have demonstrated that such V-based thin membranes have similar permeability and higher resistance to H2 embrittlement than Pd-based membranes. Alimov et al. [66] prepared a thin-walled seamless tubular membrane using V–Pd and V–Fe alloys. Furthermore, they manufactured a membrane module by welding 18 membranes, which was applied to extract ultra-pure H2. Jo et al. [67] adopted a Pd/Ta composite membrane for ammonia dehydrogenation, overcoming H2 embrittlement and producing H2 with a purity over 99.9999%, while the NH3 concentration was reduced below 1 ppm. Additionally, they applied the Pd/Ta composite membrane to purify H2 from the CO, CO2, H2O, and H2 gas mixture, yielding a H2 purity of more than 99.999% and a CO content of 10 ppm [68]. Budhi et al. [69] investigated the separation of H2 from the H2 and N2 mixture using a Pd/α-Al2O3 membrane. They achieved a higher H2 recovery rate by adjusting the feed gas flow rate to make the membrane operate under non-steady-state conditions.

4.2.2. Polymer Membranes

The working principle of polymer membrane separation is based on the different permeation rates of gases through the polymer membrane. Nowadays, polysulfone (PSF), polyimide (PI), and polyamide are commonly used as polymer membrane materials [70]. An ideal polymer membrane material should possess high selectivity, permeability, thermal stability, and good mechanical performance. However, as a rule of thumb, a highly permeable polymer membrane has low selectivity, and vice versa [71]. Since the trade-off between selectivity and permeability limits the use of polymer membranes, researchers attempted to prepare mixed matrix membranes (MMMs) by adding zeolite, silicon dioxide, CMS, and other inorganic materials into the polymer to improve the overall performance [72]. Rezakazemi et al. [73] added 4A zeolite nanoparticles into a polydimethylsiloxane (PDMS) substrate to prepare the PDMS/4A MMMs. The prepared MMMs experimentally exhibited higher H2/CH4 selectivity and H2 permeability than the pure PDMS membrane. Peydayesh et al. [74] introduced Deca-dodecasil 3R (DDR) zeolite into a Matrimid® 5218 PI substrate to prepare the Matrimid® 5218-DDR MMM, yielding H2 permeability and H2/CH4 that were increased by 100 and 189%, respectively.
In addition, polymer blending could also improve the performance of polymer membranes. Hamid et al. [75] synthesized a PSF/PI membrane that possessed higher H2 permeability and H2/CO2 selectivity (4.4) than a single PSF or PI membrane, with a H2 purification efficiency of 80%. Meanwhile, the PSF/PI membrane exhibited more stable physical and chemical properties, yielding a novel polymer membrane with excellent performance. Structurally, the mechanical performance and specific surface area of a hollow fiber membrane are superior to those of a traditional plate membrane. These findings are also used as a developmental direction of the gas separation membrane. Naderi et al. [76] developed a bilayer hollow fiber membrane with a polybenzimidazole (PBI) and sulfonated polyphenylenesulfone (sPPSU) mixture as an outer selection layer, and PSF as an inner support layer. The experimental results indicated a H2 permeability in the membrane of 16.7 GPU, and a H2/CO2 selectivity of 9.7 at 90 °C and 14 atm. Therefore, the membrane was suitable for H2 and CO2 separation at high temperatures.
All the polymer membranes mentioned above have very high H2 selectivity. Furthermore, researchers have developed separation membranes with CO2 selectivity to remove CO2 from H2 efficiently. Figure 3 schematically illustrates two selective membranes. Compared with the H2-selective membrane, the CO2-selective membrane requires a smaller area during separation and generates H2 as a product in a high-pressure state, significantly reducing the mechanical energy loss [77]. As the CO2 molecular diameter is larger than that of H2, the polymer membranes should have a particular CO2 affinity to achieve negative selectivity [55]. Abedini et al. [78] prepared a poly(4-methyl-1-pentene) (PMP)/MIL 53 (Al) MMMs membrane by adding MIL 53(Al) MOF into a poly(4-methyl-1-pentene) (PMP) substrate. It was experimentally indicated that the MMMs possessed higher CO2/H2 negative selectivity and thermal stability than pure PMP membranes. In the meantime, the negative selectivity of MMMs was enhanced with the increase in feed pressure, and it was capable of overcoming the Robeson upper limit. Cao et al. [79] introduced a covalent organic framework (COF) into polyvinyl amine to prepare the PVAM/COF MMMs, with a CO2/H2 selectivity of 15 and a CO2 permeation rate of 396 GPU. Moreover, Salim et al. [80] prepared novel oxidatively stable membranes containing quaternary ammonium hydroxide, fluoride, and tetrafluoroborate using a crosslinked polyvinyl alcohol–polysiloxane substrate, with a CO2 permeation rate of 100 GPU and CO2/H2 selectivity greater than 100, and such membranes were expected to be applied to purify H2 for fuel cell vehicles. Nigiz et al. [81] added graphene oxide (GO) into PDMS to prepare nanocomposite membranes, increasing the CO2 permeation rate and CO2/H2 selectivity. At a GO content of 0.5% and transmembrane pressure of 0.2 MPa, the CO2/H2 selectivity rose from 7.1 to 11.7, and the CO2 permeability reached 3670 Barrer. Besides this, Chen et al. [77] prepared ZIF-8-TA nanoparticles using a hydrophilic modification of ZIF-8 with tannic acid (TA). The nanoparticles were introduced into a hydrophilic polyvinyl amine substrate to obtain an MMM. Under the feed pressure of 0.12 MPa, the CO2 permeability and CO2/H2 selectivity were 987 GPU and 31, respectively, providing a preferable CO2/H2 separation performance.

4.2.3. Carbon-Based Membranes

Carbon molecular sieve (CMS) membranes (CMSMs) with an amorphous microporous structure are the most common carbon-based membranes, usually obtained by the carbonization or pyrolysis of polymer precursors in the inert gas or vacuum environment. Common polymer precursors include polyimide and its derivatives, polyfurfuryl alcohols, and phenolic resins [55]. An in-depth exploration was conducted to improve the permeability and selectivity of CMS membranes. Tanco et al. [82] prepared composite alumina–CMS membranes (Al-CMSMs) with tubular porous alumina as a carrier, achieving a H2 and CH4 separation performance considerably better than the Robeson upper limit for polymer membranes at 30 °C. The H2 extracted from an H2/CH4 gas mixture possessed a purity of 99.4%. Xu et al. [83] prepared CMSMs with ultra-high selectivity by decomposing polyetherketone–cardo polymers at a high temperature. The reported permeability of CMS membranes prepared by carbonization at 700 °C was 5260 Barrer, while the H2/CH4, H2/N2, and H2/CO selectivity was 311, 142, and 75, respectively. When the carbonization was performed at 900 °C, the H2/CH4 selectivity reached 1859.
Graphene-based membranes, as a new type of carbon-based membranes, have attracted extensive attention in the gas separation field. Graphene and GO exhibit a single-atom thickness, high mechanical strength, and good chemical stability [84]. Keeping in mind that the membrane thickness is inversely proportional to its permeability, graphene-based membranes have become ideal membranes with minimum transmission resistance and maximum permeation flux because of their ultra-low thickness. However, most graphene-based materials do not have suitable natural pores, so they cannot be directly used for gas separation. Therefore, to improve the gas separation performance of graphene-based membranes, the emphasis of the research is on imparting uniformly distributed nanopores with an appropriate size and shape and high porosity in graphene sheets [85]. By designing two dumbbell-shaped porous γ-graphene monolayers containing γ-graphyne N2 (γ-GYN) and γ-graphyne H2 (γ-GYH), respectively, Sang et al. [86] simulated the membrane performance to separate H2 from an H2, H2O, CO2, N2, CO, and CH4 gas mixture. The γ-GYN membranes exhibited better selectivity and H2 permeability, and they could be an ideal choice for H2 purification from the gas mixture. Silva et al. [87] proved that g-C3N4 graphene-like two-dimensional nanomaterials could effectively purify H2 from CO2 and CH4. Theoretical analyses suggested that H2 permeability might be improved, by enlarging the pore area by applying 2.5 and 5% biaxial strains to the membranes, without affecting the H2/CO2 and H2/CH4 selectivity. Moreover, Wei et al. [88] used density functional theory (DFT) to study the performance of 3N-PG and 6N-PG monolayers composed of porous graphene (PG) membranes and nitrogen in separating H2 from the H2, CO, N2, and CH4 gas mixture. It was also revealed that 3N-PG monolayers and 6N-PG monolayers possessed better H2 permeability than PG membranes, providing a novel membrane material for H2 purification. Sun et al. [84] studied the nano-PG (NPG) membranes and found that the H2 permeability reached 106 GPU, which was much higher than that of polymer membranes. At the same time, the H2/CH4 selectivity was 225, similar to that of polymer membranes. Meanwhile, NPG membranes are more cost-efficient than polymer membranes under the same separation conditions and purification requirements. Zeynali et al. [89] prepared GO nanocomposite membranes on modified alumina tubes, indicating their good H2 permeability, favorable H2/CO2 and H2/N2 selectivity, and stability, accompanied with lower costs than Pd membranes. In addition, Liu et al. [90] simulated the reaction path of gas molecules through nano-graphene C216 and proved that H2 could penetrate C216 membranes with a diffusion barrier of 0.65 eV. The H2 selectivity to O2, N2, NO, H2O, CO, and CO2 was up to 1033, higher than that of PG and polymer membranes.

4.2.4. MOF Membranes

MOFs generally represent a novel class of organic–inorganic hybrid porous solid materials with regular geometric and crystal structures. They are composed of metal ions or metal ion clusters connected by organic connectors. Compared with other porous materials, MOFs have the advantages of structural variability, ultra-high porosity, uniform and adjustable apertures, adjustable inner surface properties, etc. [91]. Wang et al. [92] prepared dense and defect-free Mg-MOF-74 membranes with MgO crystal seeds and modified them with ethylenediamine. The results indicated significantly improved H2/CO2 separation performance, while the H2/CO2 selectivity increased from 10.5 to 28 at room temperature. Jin et al. [93] prepared novel CAU-10-H MOF membranes and reported their good H2 permeability. The maximum separation coefficients of H2/CO2 and H2/H2O were 11.1 and 5.67, respectively. They also found that such membranes could retain their structure and H2 selectivity under long-term hydrothermal conditions, suggesting that they are suitable for H2 separation in ethanol steam reforming. Liu et al. [94] synthesized a novel heterogeneous MIL-121/118 MOF membrane. The mixed H2/CO2, H2/CH4, and H2/N2 separation coefficients were 10.7, 8.9, and 7.5, respectively, at 293K and 1 bar. The average H2 permeability was 7.83 × 10−8 mol·m−2·s−1·Pa−1. Meanwhile, MIL-121/118 exhibited high thermal stability and durability, showing a good application prospect.

4.3. Metal Hydride Separation Method

The metal hydride separation method refers to purifying H2 using H2 storage alloys to absorb and desorb H2 reversibly. H2 molecules decompose into H atoms catalyzed by H2 storage alloys by lowering the temperature and increasing the pressure. Then, metal hydrides are generated via diffusion, phase transition, combination reaction, and other processes, while impurity gases are trapped among metal particles. After the temperature is elevated and pressure is lowered, the impurity gases discharge from the metal particles, and then H2 comes out from the crystal lattice. H2 storage alloys can be divided into rare earth alloys, titanium alloys, zirconium alloys, and magnesium alloys based on the type of the main element. Furthermore, they can also be classified into AB5-type alloys, AB2-type alloys, AB-type alloys, and A2B-type alloys according to the main elements’ atomic ratio [95]. The performance of the H2 storage alloys determines the efficiency of H2 purification, so the chemical stability and tolerance of H2 storage alloys can be improved and the influences of impurity gases can be reduced by modifying H2 storage alloys. Dunikov et al. [96] used two kinds of AB5-type alloys to separate the H2/CO2 mixture. They found that for the low-pressure LaNi4.8Mn0.3Fe0.1 alloy, H2 can be purified from the mixture containing 59% H2 with a recovery rate of 94%, supporting the operation of PEMFCs. Yang et al. [97] carried out cyclic experiments on the LaNi4.3Al0.7 H2 storage alloy in the high CO concentration environment. The H2 storage capacity of this alloy slowly decreased at 363 K or higher temperatures, maintaining a relatively high kinetic rate so that it can be used for H2 separation and purification in different applications. Besides this, Hanada et al. [98] studied the effects of CO2 on the H2 absorption performance of AB2-type alloys to develop metal hydrides for H2 purification and storage. The results showed that Fe and Co addition could improve the alloys’ tolerance to CO2, while Ni addition had the opposite effect. Zhou et al. [99] found that MgH2 catalyzed by nano VTiCr easily reacted with low-pressure H2, and is recycled in mixed gas. Therefore, the material showed H2 separation and purification potential.

4.4. Cryogenic Distillation

The principle of cryogenic distillation is to separate and purify H2 by utilizing the difference in the relative volatility of different components in feed gases. Compared with CH4 and other light HCs, H2 has relatively high volatility, such that HCs, CO, N2, and other gases condense before H2 with temperature reductions [100]. This process is usually used for H2–HC separation. The low-temperature separation method assures a high H2 recovery rate, but it is challenging to adapt the method for treating different feed gases. As such, it is necessary to remove CO2, H2O, and other impurities from the feed gases before the separation so as to avoid equipment blockage at a low temperature. Besides this, high costs and energy consumption accompany the requirements for gas compressors and cooling equipment in the actual operation. Although most impurities are liquefied at a low temperature, some remain in the gas phase as saturated steam, so it is difficult to directly obtain H2 that meets the purity standards of fuel cell vehicles.

5. Conclusions and Prospects

Compared with industrial H2, the purity of H2 for fuel cell vehicles is not sufficient, although the requirements for the impurity content in H2 are stringent. According to the existing standards, an impurity level above the limit may damage the fuel cell’s performance. Thus, removing specific impurities is the focus of future research on H2 purification for fuel cell vehicles. PSA is a universal method that can be applied to remove most contaminants. H2-permeable membranes are often used to remove CO, CO2, N2, CH4, H2O, and other gas impurities, while CO2-permeable membranes enable only CO2 removal. Owing to CO, CO2, and H2O sensitivity, metal hydrides can be used to remove N2, Ar, and other inert gases. However, all the existing H2 purification methods are limited, and it is difficult to achieve the H2 impurity level standards for fuel cell vehicles by using only one separation and purification method. Since there are many different H2 sources, two or even more H2 purification technologies should be adopted.

Author Contributions

conceptualization, Z.D., C.L. and W.S.; writing—original draft preparation, C.L. and G.H.; writing—review and editing, J.Z., C.L., Y.X. and X.G.; All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the National Key Research and Development Program of China (Grant No. 2019YFB1505000) and the Technology Innovation Project of China Energy Investment (Project Number: GJNY-19-136).

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Classification of hydrogen purification technologies.
Figure 1. Classification of hydrogen purification technologies.
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Figure 2. Flow scheme of the classical pressure swing adsorption (PSA) system.
Figure 2. Flow scheme of the classical pressure swing adsorption (PSA) system.
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Figure 3. Schematic representation of (a) H2-selective and (b) CO2-selective membranes.
Figure 3. Schematic representation of (a) H2-selective and (b) CO2-selective membranes.
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Table 1. Emerging H2 production methods.
Table 1. Emerging H2 production methods.
H2 Production MethodTechnical Feature
H2 production from supercritical steam coalIn this technology, supercritical water [namely, temperature and pressure are at or above the critical values (374.3 °C and 2.1 MPa)] is used as a medium that provides a homogeneous and high-speed reaction because of its special physical and chemical properties, so that the chemical energy of coal is directly and efficiently converted into hydrogen energy [8].
H2 production from water photocatalytically decomposed by solar energyPhotocatalyst powders or electrodes can produce photo-generated carriers by absorbing solar energy, so they decompose water into H2 and O2. The photocatalytic H2 production can be subdivided mainly into heterogeneous photocatalytic (HPC) H2 production and photo-electrochemical (PEC) H2 production [9].
Biological H2 productionH2 is a product of microorganisms’ metabolism using biomass and organic wastewater as raw materials. Based on the type of microorganisms and their metabolic mechanisms, the biological H2 production technology includes water splitting H2 production, photo-fermentative H2 production, dark fermentative H2 production, and H2 production combined with photo-fermentation and dark fermentation [10].
Table 2. Requirements for the impurity content in H2 for fuel cells in previous and new standards in China and abroad.
Table 2. Requirements for the impurity content in H2 for fuel cells in previous and new standards in China and abroad.
ComponentGB/T 3634.2-2011ISO 14687-2:2012
SAE J2719-201511
GB/T 37244-2018
ISO 14687:2019
SAE J2719-202003
Pure H2High Pure H2Ultrapure H2
H2 purity (mole fraction)99.99%99.999%99.9999%99.97%99.97%
Total non-hydrogen gases-10 ppm1 ppm300 ppm300 ppm
H2O10 ppm3 ppm0.5 ppm5 ppm5 ppm
Total HC (by methane)---2 ppm-
Non-methane HC (by C1)----2 ppm
Methane10 ppm1 ppm0.2 ppm-100 ppm
O25 ppm1 ppm0.2 ppm5 ppm5 ppm
He---300 ppm300 ppm
N2 and Ar---100 ppm-
N260 ppm5 ppm0.4 ppm-300 ppm
ArAgreed by supply and demandAgreed by supply and demand0.2 ppm-300 ppm
CO25 ppm1 ppm0.1 ppm2 ppm2 ppm
CO5 ppm1 ppm0.1 ppm0.2 ppm0.2 ppm
Total sulfide (by H2S)---0.004 ppm0.004 ppm
HCHO---0.01 ppm0.2 ppm
HCOOH---0.2 ppm0.2 ppm
NH3---0.1 ppm0.1 ppm
Total halide (by halide ion)---0.05 ppm0.05 ppm
The concentration of maximum particulate matter---1 mg/kg1 mg/kg
Table 3. Impact of impurities on the performance of fuel cells.
Table 3. Impact of impurities on the performance of fuel cells.
ImpurityDamage Induced by Excessive Impurities
H2OH2O can transport water-soluble impurities, such as Na+ and K+, and reduce the membrane proton conductivity. Excessive H2O induced corrosion of metal parts [11].
HCMost HCs adsorbed onto the catalyst layer will decrease catalytic performance. Methane does not pollute fuel cells, but it dilutes H2 and hampers performance [12].
O2O2 in specific concentrations negatively affects the performance of metal hydride, a type of H2 storage material [11].
Inert gasDilution and diffusion of He, Ar, and N2 in H2 decrease the electric potential of fuel cells [13].
CO2CO2 has a dilution effect on H2. CO2 in high concentrations can be converted into CO through a reverse water gas shift reaction, thereby leading to catalyst poisoning [14].
COCO closely binds to the active site of Pt catalysts, decreasing the effective electrochemical surface area used for H2 adsorption and oxidation [15].
SulfideThe adsorption of sulfides on the active catalyst sites prevents H2 adsorption on the catalyst surface. The adsorbed sulfides react with Pt catalysts to form stable Pt sulfides, irreversibly degrading the fuel cell performance [16].
HCHO and HCOOHHCHO and HCOOH are adsorbed on catalysts to form CO, thereby leading to catalyst poisoning [17].
NH3NH4+ can reduce the proton conductivity of the ionic polymer. NH3 adsorbed on the surface of the catalyst blocks the active sites [18].
HalideHalide adsorbed on the catalyst layer decreases the superficial area of catalysts. Chloride ions are deposited in the fuel cell membrane by forming soluble chlorides, leading to the Pt catalyst’s dissolution [19].
Particulate matterParticulate matters adsorbed on the active site of catalysts of fuel cells prevent the H2 adsorption on the catalyst surface, blocking the filter and destroying the full cell components [20].
Table 4. Composition of different types of crude hydrogen.
Table 4. Composition of different types of crude hydrogen.
Component (%)H2COCO2CH4N2ArTotal SulfurH2OO2Others
Coal gasification [27]25–3535–4515–250.1–0.30.5–1-0.2–115–20--
Natural gas reforming [28]70–7510–1510–151–30.1–0.5-----
Methanol reforming [29]75–800.5–220–25-------
Coke oven gas [30]45–605–102–525–302–5-0.01–0.5-0.2–0.52–5
Methanol purge gas [31]70–804–85–102–85–150.1–2----
Synthetic ammonia tail gas [32]60–75---15–20--1–310–15-
Biomass gasification [33]25–3530–4010–1510–201-0.2–1-0.3–1-
Table 5. Summary of PSA technology.
Table 5. Summary of PSA technology.
AdsorbentProcess FlowFeed GasH2 PurityH2 Recovery RateReference
Hollow fiber sorbentRCPSACO2:H2 = 25:7599.2%88.1%[34]
Palm kernel shell activated carbonTwo-column PSACO2:H2 = 15:85About 100%88.43%[35]
UTSA-16Four-column PSASteam methane reforming off-gas99.99–99.999%93–96%[38]
CaX zeoliteFour-column PSAH2:CH4:CO:CO2 = 75.89:4.01:3.03:17.07+99.99%69.6%[39]
Cu-AC-2Four-column PSAH2:CO2:CH4:CO = 70:25:4:1+99.97%+75%[41]
Activated carbon/zeolite 5AFour-bed PSAH2:CO2:CH4:CO:N2 = 38:50:1:1:1096–99.5%71–85%[42]
Activated carbonTwelve-step four-column PSACO:CO2:CH4:H2 = 1:25:5:6999.999%+75%[43]
Activated carbon/zeolite LiXEight-layered bed PSAH2:CO2:CO:N2:Ar = 88.75:2.12:2.66:5.44:1.0399.99%89.7%[44]
Activated carbon/zeolite 5ASix-step layered two-bed PSAH2:CH4:CO:CO2 = 72.9:3.6:4.5:19+99.95%+80%[46]
5A zeoliteFour-column PSAH2:N2:CH4:Ar = 58:25:15:299.25–99.97%55.5–75.3%[32]
Activated carbonCPSAH2:CO:CO2 = 94.6:0.4:599.999%-[52]
Potassium-promoted layered doubleoxideTwo-column seven-step ET-PSACO:CO2:H2O:H2 = 1:1:10:8899.9991%99.6%[53]
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Du, Z.; Liu, C.; Zhai, J.; Guo, X.; Xiong, Y.; Su, W.; He, G. A Review of Hydrogen Purification Technologies for Fuel Cell Vehicles. Catalysts 2021, 11, 393. https://doi.org/10.3390/catal11030393

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Du Z, Liu C, Zhai J, Guo X, Xiong Y, Su W, He G. A Review of Hydrogen Purification Technologies for Fuel Cell Vehicles. Catalysts. 2021; 11(3):393. https://doi.org/10.3390/catal11030393

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Du, Zhemin, Congmin Liu, Junxiang Zhai, Xiuying Guo, Yalin Xiong, Wei Su, and Guangli He. 2021. "A Review of Hydrogen Purification Technologies for Fuel Cell Vehicles" Catalysts 11, no. 3: 393. https://doi.org/10.3390/catal11030393

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