cylinder/tanks at pressure of up to 600 psi or at −253°C in insulated tanks. Either method of storage will pose problems when filling the vehicle. There are options to avoid the on-board storage of hydrogen which includes the on-board produc- tion of hydrogen from methanol or petrol (Fig. 5.15). Both methanol and petrol are liquid and can easily be supplied by the present infrastructure, but petrol is non-sustainable and methanol would need to be produced in a sustainable manner.

Both systems would add weight, complication, increase fuel consumption and cost to the vehicle.

environmentally benign (Semelsberger et al., 2006). As DME is non-toxic and non- corrosive it is used mainly as a hairspray propellant, in cosmetics and in agricultural chemicals. DME has a high cetane value, no sulfur, little particulate matter (PM) emissions and can be competitive with LPG. Owing to these characteristics DME has been considered as a fuel for diesel engines, gas turbines and fuel cells. As its proper- ties are similar to those of propane and butane (Table 5.6), DME could be used to replace or supplement LPG for distributed power generation including gas turbines (Coccoet al., 2006). DME can also be reformed to produce hydrogen for fuel cells.

Dimethyl ether is produced in a two-step process where methanol is produced from syngas which is normally produced by the steam reformation of methane (natu- ral gas). The methanol is then dehydrated to form dimethyl ether. Syngas can be produced from waste and biomass so that DME could be produced from sustainable sources. To produce methanol the syngas needs a 1:1 ratio of carbon monoxide to hydrogen which can be adjusted by the water-shift reaction:

CO+ 2H₂« CH₃OH (5.12)

2CH₃OH« CH₃OCH₃+ H₂O (5.13)

DME has been shown to produce low noise, smoke-free combustion, and reduced NO_x when used in an internal combustion engine (Huang et al., 2006). Because of its high cetane number and low boiling point, DME has been used at 100% or as an oxygenated addition to diesel. However, DME requires special fuel handling and storage as its properties are similar to LPG, and the lower energy means that a larger fuel tank will be required. The engine does not require modification but as the viscosity of DME is so low it can cause leakage in the pumps and injectors.

Another consequence of the low fuel viscosity is a reduction in lubrication where lubricants need to be added to the fuel if used for long periods. The conclusions on DME were that it gave lower NO_x and SO_x, is soot-less and produces the highest well-to-wheel value compared with FT-biodiesel, biodiesel, methanol and ethanol (Semelsbergeret al., 2006).

DME has also been shown to be suitable for gas turbines where performance and carbon dioxide emissions were improved when it was used in a chemically recuperated gas turbine (CRGT) (Cocco et al., 2006). One of the options to increase the efficiency of gas turbines is to recover the exhaust heat chemically. Most CRGT systems use methane Table 5.6. Properties of propane, butane, dimethyl ether and diesel. (From Semelsberger et al., 2006; Cocco et al., 2006.)

Propane Butane Dimethyl ether

Properties (C₃H₈) (C₄H₁₀) (CH₃OCH₃) Diesel (C₁₄H₃₀) Molecular weight 44.1 58.13 46.07 586

Carbon (%) 82 96 52.2 86

Density (kg/l) 0.5 0.58 0.66 0.86

Energy (MJ/kg) 46.4 45.7 28.6 38.5–45.8

Boiling point (°C) −42 −0.5 −24.9 125–400

Cetane number 5 20 55–60 40–55

Sulfur (%) 0 0 0 0.2

steam reforming where carbon dioxide and hydrogen are formed and used as a fuel in the turbine. However, a high reforming temperature up to 600–800°C is required, which is higher than the exhaust temperature of commercial gas turbines. On the other hand methanol, DME and ethanol have lower reforming temperatures of 250–300°C, 300–

350°C and 400–500°C respectively which makes them more suitable. The overall reform- ing process is described below and a CRGT system is shown in Fig. 5.16:

CH₃OCH₃+ H₂O « 2CH₃OH (5.14)

CH₃OH« CO + 2H₂ (5.15)

CO+ H₂O« CO₂+ H₂ (5.16)

The reformation is carried out at 290°C using Cu/SiO₂ and HPA/Al₂O₃ catalysts. The CRGT system achieves an efficiency of 54%, 44% higher than a standard plant.

DME can also be used as a fuel for fuel cells as it can be reformed to produce hydrogen. The reformation is in two steps where the first step is an acid catalysis which converts dimethyl ether into methanol and the second step is the reformation of methanol over a Cu or Cu/Zn catalyst:

CH₃OCH₃+ H₂O « 2CH₃OH (5.17)

2CH₃OH+ 2H₂O« 6H₂+ 2CO₂ (5.18)

Other similar compounds have been tested in diesel engines which include dimethyl carbonate and dimethoxy methane (Huang et al., 2006).

Water

+ DME P

Reformed fuel

Combustion chamber

Compressor Turbine

Exhaust

Fig. 5.16. A chemically recuperated gas turbine (CRGT) system using reforming dimethyl ether (DME) to utilize the exhaust heat. (From Cocco et al., 2006.)

Conclusions

Gaseous biofuels are a mixture of existing technologies and the promise of technology in the future. Methane is produced in landfill and anaerobic digesters and used for heating and electricity generation. Methane as a transport fuel has been proposed and the technology for the compression and liquefaction of the gas exists but may not be implemented. Methane is similar to LPG. LPG has been around for some years but the take-up of cars using this fuel has been very slow, probably due to the required expensive modifications to the car and the uneven distribution of LPG filling stations.

Much has been written about hydrogen and the ‘hydrogen economy’ but consider- able advances in technology will be required to make hydrogen a transport fuel that is sustainable. At present all hydrogen is made from natural gas and to be sustainable it needs to be produced from renewable resources such as biomass. The problem with hydrogen as a fuel is it needs to be stored so that sufficient fuel can be carried in a vehicle. At present, hydrogen can either be compressed gas or liquefied but both require considerable amounts of energy and special tanks. The production and distri- bution of hydrogen will also be required if it is to be used as a transport fuel. This will need the installation of a completely new infrastructure at a considerable cost. Despite the problems there is probably a future for hydrogen as a fuel for fuel-cell-powered vehicles; the question is whether hydrogen will be produced on-board or stored as hydrogen.

6 Liquid Biofuels to Replace Petrol

Introduction

Oil makes up 35% of the world’s primary energy supply and the majority of this oil is used to produce the transport fuels petrol, diesel and kerosene. If biofuels are to be used to replace the liquid fuel produced from oil, the scale of the replacement needs to be appreciated. The world used in 2005 about 1900 Mtoe oil for transport, the USA 601 Mtoe, the EU 25 342 Mtoe and the UK 58 Mtoe. The fuels used for trans- port in the UK, the EU 25 and world are given in Table 6.1. At present almost all transport fuels are liquid and used in internal combustion, compression ignition and jet engines. The liquid fuels are predominantly petrol, diesel and kerosene. The pat- tern of fuel use will vary depending on the country as many use more diesel than petrol. In the EU, diesel use exceeds petrol use and the more recent figures for the UK indicate that diesel use has exceeded petrol for the first time.

The possible biofuel replacements for petrol and diesel were sketched out in Chapter 4, section ‘The Nature of Biofuels: First-, Second- and Third-generation Biofuels’, where the three generations of biofuels were explained. This chapter deals with biofuels which can supplement or replace petrol and include methanol, bioetha- nol, biobutanol and FT-petrol.

Table 6.1 gives the amount of liquid fuels used for transport in the UK in 2006 and in the EU 25 and world in 2005. In the UK, diesel use has increased rapidly and now exceeds petrol, following the trend set in the EU, whereas petrol use is greater on a global basis.