Production of Solar Hybrid Fuels of DME, Methanol and H2 in Australia and Shipping to Japan

Solar Energy ◽  
2005 ◽  
Author(s):  
Yutaka Tamaura ◽  
Hiroshi Kaneko ◽  
Akinori Fuse ◽  
Hideyuki Ishihara
Keyword(s):  
Natural Gas ◽  
Solar Energy ◽  
Thermal Energy ◽  
Solar Thermal ◽  
Solar Thermal Energy ◽  
Mixed Gas ◽  
Combined Process ◽  
Emission Process ◽  
Zero Emission ◽  
The One

Solar hybrid fuel production from natural gas using concentrated solar thermal energy in Australia was studied, assuming that 54.6MW/(one unit of solar farm) of the concentrated solar thermal energy is used for the endothermic process of stream reforming (solar steam reforming; SSR) with total solar energy conversion efficiency of 45.5% (120MW of heliostat field; one unit of solar farm). With 23 units of the solar farm, natural gas of 2516t/d can be reformed by the SSR. To ship the product fuel to Japan by existing tankers, the syngas (CO + 3H2) produced by the SSR is separated into one mole of H2 (375t/d) and the mixed gas of one mole of CO and two moles of H2 which is converted to one mole of methanol (6000t/d) to be shipped by existing tankers. The one mole of H2 will be used in Australia as the H2 fuel with 25% solar share (CO2 reduction). To improve cost barrier between oil and the methanol produced by SSR, the CO2 zero emission process of the combined process of SSR and AT (auto-thermal process) is proposed as the one whose methanol cost can be competitive with oil, when carbon tax is introduced. By shipping the methanol produced by the CO2 zero emission process of the combined process of SSR-AT (economically feasible), we can reduce CO2 emission by co-firing coal and methanol at coal-firing power stations in Japan. In this system, an excess H2 fuel with solar energy is produced, and can be used in Australia.

scholarly journals Solar Integrated Anaerobic Digester: Energy Savings and Economics

Energies ◽  
2020 ◽  
Vol 13 (17) ◽  
pp. 4292
Author(s):  
Lidia Lombardi ◽  
Barbara Mendecka ◽  
Simone Fabrizi
Keyword(s):  
Anaerobic Digestion ◽  
Natural Gas ◽  
Economic Analysis ◽  
Thermal Energy ◽  
Economic Feasibility ◽  
Solar Thermal ◽  
Base Case ◽  
Economic Sustainability ◽  
Solar Thermal Energy ◽  
Solar Integration

Industrial anaerobic digestion requires low temperature thermal energy to heat the feedstock and maintain temperature conditions inside the reactor. In some cases, the thermal requirements are satisfied by burning part of the produced biogas in devoted boilers. However, part of the biogas can be saved by integrating thermal solar energy into the anaerobic digestion plant. We study the possibility of integrating solar thermal energy in biowaste mesophilic/thermophilic anaerobic digestion, with the aim of reducing the amount of biogas burnt for internal heating and increasing the amount of biogas, further upgraded to biomethane and injected into the natural gas grid. With respect to previously available studies that evaluated the possibility of integrating solar thermal energy in anaerobic digestion, we introduce the topic of economic sustainability by performing a preliminary and simplified economic analysis of the solar system, based only on the additional costs/revenues. The case of Italian economic incentives for biomethane injection into the natural gas grid—that are particularly favourable—is considered as reference case. The amount of saved biogas/biomethane, on an annual basis, is about 4–55% of the heat required by the gas boiler in the base case, without solar integration, depending on the different considered variables (mesophilic/thermophilic, solar field area, storage time, latitude, type of collector). Results of the economic analysis show that the economic sustainability can be reached only for some of the analysed conditions, using the less expensive collector, even if its efficiency allows lower biomethane savings. Future reduction of solar collector costs might improve the economic feasibility. However, when the payback time is calculated, excluding the Italian incentives and considering selling the biomethane at the natural gas price, its value is always higher than 10 years. Therefore, incentives mechanism is of great importance to support the economic sustainability of solar integration in biowaste anaerobic digestion producing biomethane.

System and component modelling of a low temperature solar thermal energy conversion cycle

2013 ◽  
Vol 24 (4) ◽  
pp. 51-62
Author(s):  
Shadreck M. Situmbeko ◽  
Freddie L. Inambao
Keyword(s):  
Low Temperature ◽  
Solar Energy ◽  
Thermal Energy ◽  
Electrical Power ◽  
Solar Thermal ◽  
Working Fluid ◽  
Small Scale ◽  
Solar Thermal Energy ◽  
Solar Field ◽  
Conversion Technology

Solar thermal energy (STE) technology refers to the conversion of solar energy to readily usable energy forms. The most important component of a STE technology is the collectors; these absorb the shorter wavelength solar energy (400-700nm) and convert it into usable, longer wavelength (about 10 times as long) heat energy. Depending on the quality (temperature and intensity) of the resulting thermal energy, further conversions to other energy forms such as electrical power may follow. Currently some high temperature STE technologies for electricity production have attained technical maturity; technologies such as parabolic dish (commercially available), parabolic trough and power tower are only hindered by unfavourable market factors including high maintenance and operating costs. Low temperature STEs have so far been restricted to water and space heating; however, owing to their lower running costs and almost maintenance free operation, although operating at lower efficiencies, may hold a key to future wider usage of solar energy. Low temperature STE conversion technology typically uses flat plate and low concentrating collectors such as parabolic troughs to harness solar energy for conversion to mechanical and/or electrical energy. These collector systems are relatively cheaper, simpler in construction and easier to operate due to the absence of complex solar tracking equipment. Low temperature STEs operate within temperatures ranges below 300oC. This research work is geared towards developing feasible low temperature STE conversion technology for electrical power generation. Preliminary small-scale concept plants have been designed at 500Wp and 10KWp. Mathematical models of the plant systems have been developed and simulated on the EES (Engineering Equation Solver) platform. Fourteen candidate working fluids and three cycle configurations have been analysed with the models. The analyses included a logic model selector through which an optimal conversion cycle configuration and working fluid mix was established. This was followed by detailed plant component modelling; the detailed component model for the solar field was completed and was based on 2-dimensional segmented thermal network, heat transfer and thermo fluid dynamics analyses. Input data such as solar insolation, ambient temperature and wind speed were obtained from the national meteorology databases. Detailed models of the other cycle components are to follow in next stage of the research. This paper presents findings of the system and solar field component.

Pengujian Alat Pengering Surya Sederhana dan Modifikasi Menjadi Alat Pengering Hybrid

2018 ◽  
Vol 3 (3) ◽  
Author(s):  
Muhammad Irvan ◽  
Dewi Sri Jayanti ◽  
Raida Agustina
Keyword(s):  
Solar Energy ◽  
Thermal Energy ◽  
Biomass Energy ◽  
Solar Thermal ◽  
Solar Irradiation ◽  
Biomass Combustion ◽  
Energy Sources ◽  
Solar Thermal Energy ◽  
Green Beans ◽  
Average Temperature

Abstrak.  Pengering hybrid merupakan pengering yang menggunakan dua atau lebih sumber energi untuk proses penguapan air. Tujuan dari penelitian ini adalah memodifikasi alat pengering surya sederhana menjadi alat pengering hybrid dengan tambahan energi panas dari pembakaran tempurung kelapa untuk melakukan uji pengeringan pada kacang hijau. Distribusi suhu rata-rata pada alat pengering hybrid pengeringan kacang hijau menggunakan energi panas matahari, kombinasi dan biomassa masing-masing adalah 49oC,50oC dan 35oC dengan iradiasi matahari masing-masing menggunakan energi panas matahari dan kombinasi adalah 360,47W/m2 dan 362,79W/m2. Kelembaban relatif pada alat pengering hybrid saat pengeringan kacang hijau menggunakan energi panas matahari, kombinasi dan biomassa masing-masing adalah 44,69%, 45,69% dan 57,75%. Kecepatan udara pada alat pengering hybrid saat pengeringan kacang hijau menggunakan energi panas matahari, kombinasi dan biomassa masing-masing adalah 0,11 m/s , 0,1 m/s dan 0,08 m/s. Pengeringan kacang hijau menggunakan sumber panas dari energi matahari, sumber panas kombinasi energi matahari dengan pembakaran biomassa dan menggunakan energi pembakaran biomassa menghasilkan kadar air akhir biji kacang hijau masing-masing sebesar 8,42%, 8,27% dan 10,75%. Besarnya energi biomassa yang dihasilkan saat pengering selama 10 jam adalah 272,142 MJ. Besarnya energi matahari saat pengeringan kacang hijau menggunakan sumber energi matahari dan sumber panas kombinasi energi matahari dengan pembakaran biomassa adalah 3,22 MJ dan 3,14 MJ.Testing of Simple and Modified Solar Dryers Become a Hybrid Dryer ToolAbstract. A hybrid dryer is a dryer that uses two or more sources of energy for the evaporation process of water. The purpose of this study is to modify the simple solar drying tool into a hybrid drying tool with additional heat energy from coconut shell combustion to test drying on green beans. The average temperature distribution of green peanut drying dryers using solar thermal energy, combination and biomass are respectively 49oC, 50oC and 35oC with solar irradiation each using solar thermal energy and the combination is 360,47W/m2 and                362, 79   W/m2. The relative humidity in the hybrid drier when drying green beans using solar thermal energy, combination and biomass are 44.69%, 45.69% and 57.75%, respectively. The air velocity in the hybrid drier when drying green beans using solar thermal energy, combination and biomass are 0.11 m/s, 0.1 m/s and       0.08 m/s respectively. Drying of green beans using a source of heat from solar energy, a combination of solar energy sources with biomass combustion and using biomass combustion energy to produce the final content of green beans seeds by 8.42%, 8.27% and 10.75% respectively. The amount of biomass energy produced during drying for 10 hours is 272,142 MJ. The amount of solar energy during drying of green beans using solar energy sources and the combined heat source of solar energy with biomass burning is 3.22 MJ and 3.14 MJ.

scholarly journals Application of Solar Thermal Energy for Medium Temperature Heating in Automobile Industry

2017 ◽  
Vol 7 (2 (S)) ◽  
pp. 19
Author(s):  
Anagha Pathak ◽  
Kiran Deshpande ◽  
Sandesh Jadkar
Keyword(s):  
Solar Energy ◽  
Thermal Energy ◽  
Automobile Industry ◽  
Storage Tank ◽  
Fossil Fuel ◽  
Heating System ◽  
Hot Water ◽  
Solar Thermal ◽  
Solar Thermal Energy ◽  
Medium Temperature

There is a huge potential to deploy solar thermal energy in process heat applications in industrial sectors. Around 50 % of industrial heat demand is less than 250 °C which can be addressed through solar energy. The heat energy requirement of industries like automobile, auto ancillary, metal processing, food and beverages, textile, chemical, pharmaceuticals, paper and pulp, hospitality, and educational institutes etc. can be partially met with solar hybridization based solutions. The automobile industry is one of the large consumers of fossil fuel energy in the world. The automobile industry is major economic growth driver of India and has its 60 % fuel dependence on electricity and remaining on oil based products. With abundant area available on roof top, and need for medium temperature operation makes this sector most suitable for substitution of fossil fuel with renewable solar energy. Auto sector has requirement of heat in the temperature range of 80-140 oC or steam up to 2 bar pressure for various processes like component washing, degreasing, drying, boiler feed water preheating, LPG vaporization and cooling. This paper discusses use of solar energy through seamless integration with existing heat source for a few processes involved in automobile industries. Integration of the concentrated solar thermal technology (CST) with the existing heating system is discussed with a case study for commonly used processes in auto industry such as component washing, degreasing and phosphating. The present study is undertaken in a leading automobile plant in India. Component cleaning, degreasing and phosphating are important processes which are carried out in multiple water tanks of varying temperatures. Temperatures of tanks are maintained by electrical heaters which consumes substantial amount of electricity. Non-imaging solar collectors, also known as compound parabolic concentrators (CPC) are used for generation of hot water at required process temperature. The CPC are non-tracking collectors which concentrate diffuse and beam radiation to generate hot water at required temperature. The solar heat generation plant consists of CPC collectors, circulation pump and water storage tank with controls. The heat gained by solar collectors is transferred through the storage tank to the process. An electric heater is switched on automatically when the desired temperature cannot be reached during lower radiation level or during non-sunny hours/days. This solar heating system is designed with CPC collectors that generate process heating water as high as 90OC. It also seamlessly integrates with the existing system without compromising on its reliability, while reducing electricity consumption drastically. The system is commissioned in April, 2013 and since then it has saved ~ 1,75,000 units of electricity/year and in turn 164 MT of emission of CO2 annually.

scholarly journals Tuning the photochemical properties of the fulvalene-tetracarbonyl-diruthenium system

2016 ◽  
Vol 45 (21) ◽  
pp. 8740-8744 ◽  
Author(s):  
Anders Lennartson ◽  
Angelica Lundin ◽  
Karl Börjesson ◽  
Victor Gray ◽  
Kasper Moth-Poulsen
Keyword(s):  
Energy Storage ◽  
Solar Energy ◽  
Thermal Energy ◽  
Thermal Energy Storage ◽  
Chemical Energy ◽  
Solar Thermal ◽  
Solar Thermal Energy ◽  
System P ◽  
Photochemical Properties

In a Molecular Solar–Thermal Energy Storage (MOST) system, solar energy is converted to chemical energy using a compound that undergoes reversible endothermic photoisomerization.

Preheating Metal Scrap in Foundries Using Solar Thermal Energy

2015 ◽  
Vol 813-814 ◽  
pp. 760-767 ◽  
Author(s):  
J. Selvaraj ◽  
Chandra C. Jawahar ◽  
Khushal A. Bhatija ◽  
Saalai Thenagan
Keyword(s):  
Solar Energy ◽  
Energy Conservation ◽  
Greenhouse Gases ◽  
Environmental Protection ◽  
Thermal Energy ◽  
Solar Thermal ◽  
Solar Thermal Energy ◽  
Metal Scrap ◽  
Parabolic Trough ◽  
Preheating Temperature

The present scenario of energy conservation has witnessed many innovative and eco-friendly techniques and one such area where there is a necessity to conserve energy is foundries. Foundries also pollute the atmosphere with greenhouse gases contributing to 296143037.6 metric tons annually. The proposed technique in this paper aims at reducing the energy utilized in melting the scrap material at foundries by solar thermal energy. In the methodology proposed, solar energy is concentrated onto the scrap placed on a receiving platform using a parabolic trough and heats it up so that the heated scrap takes lesser energy to melt. The experiments resulted in preheating temperature of 100 °C when placed on a receiving platform and 110°C when copper shots are used to conduct heat from receiver to the scrap. This translates to energy conservation of 6%. This eco-friendly technique when adopted can result in substantial savings in consumption and environmental protection.

scholarly journals Solar Hybrid Hatching Machine Applying a Thermal Accumulator with a Reflective Array Method

2021 ◽  
Vol 77 (3) ◽  
pp. 23-31
Author(s):  
Budhy Setiawan ◽  
Riska Nur Wakidah
Keyword(s):  
Solar Energy ◽  
Thermal Energy ◽  
Electrical Energy ◽  
Solar Thermal ◽  
Electric Heater ◽  
Solar Thermal Energy ◽  
Data Logger ◽  
One Year ◽  
Switching Method ◽  
Electronic Controller

In this research, a hybrid egg hatcher machine applied two types of energy for heating, namely solar thermal energy and an electric (fossil) heater. Solar energy was the main energy, and the electric heater was the secondary energy. This hybrid system was related to Indonesian geography, with high solar energy of an average of 5 kWh/m2/day in one year. Therefore, solar thermal energy storage will be effectively used in Indonesia to reduce fossil energy exploitation. The solar thermal energy was stored in an accumulator with a 4 m2 collector.  The solar thermal accumulator was an insulated vessel with high reflectivity and insulation.  The heat energy was stored and kept in some water bars. In maximizing absorption capability, the collector used a reflective array method that was operated by opening or closing the arrays. The arrays were controlled by an electronic controller, which compared the thermal energy inside with the energy of sunlight. The array’s movement to charge the accumulator was done automatically by using the hysteresis switching method. The electric heater will be used only if the accumulator temperature is less than 40 °C. The capacity of the egg hatcher machine accumulator was 300 eggs. Raw data were collected using a data logger of DAQ (Data Acquisition Interface) DT9813 to determine and analyze the performance of system parameters.  From the data collected, the solar thermal accumulator showed its capability for storing thermal energy up to 7.07 kWh. However, its average absorption efficiencies were 54–58 % by direct solar and 60–70 % by diffuse solar. Experiments verified the effectiveness of the designed accumulator. The experimental results showed that the electrical energy consumption was reduced up to 64 %.

scholarly journals High-efficiency solar thermoelectric conversion enabled by movable charging of molten salts

2020 ◽  
Vol 10 (1) ◽  
Author(s):  
Chao Chang ◽  
Zongyu Wang ◽  
Benwei Fu ◽  
Yulong Ji
Keyword(s):  
Solar Energy ◽  
Thermal Energy ◽  
Molten Salts ◽  
High Efficiency ◽  
Thermal Storage ◽  
Solar Thermal ◽  
Stable Operation ◽  
Solar Thermal Energy ◽  
Thermoelectric Converter ◽  
Thermoelectric Conversion

AbstractSolar energy as an abundant renewable resource has been investigated for many years. Solar thermoelectric conversion technology, which converts solar energy into thermal energy and then into electricity, has been developed and implemented in many important fields. The operation of solar–thermal–electric conversion systems, however, is strongly affected by the intermittency of solar radiation, which requires installation of thermal storage subsystems. In this work, we demonstrated a new solar–thermal–electric conversion system that consists of a thermoelectric converter and a rapidly charging thermal storage subsystem. A magnetic-responsive solar–thermal mesh was used as the movable charging source to convert incident concentrated sunlight into high-temperature heat, which can induce solid-to-liquid phase transition of molten salts. Driven by the external magnetic field, the solar–thermal mesh can move together with the receding solid–liquid interface thus rapidly storing the harvested solar–thermal energy within the molten salts. By connecting with a thermoelectric generator, the harvested solar–thermal energy can be further converted into electricity with a solar–thermal–electric energy conversion efficiency up to 2.56%, and the converted electrical energy can simultaneously light up more than 40 orange-colored LEDs. In addition to stable operation under sunlight, the charged thermal storage subsystem can release the stored heat and thus enables the solar–thermal–electric system to continuously generate electricity after removal of solar illumination.

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