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Global geothermal power generation: the future star of clean energy

Global geothermal power generation: the future star of clean energy

Summary:
With the continuous growth of global demand for clean energy, geothermal power generation, as an environmentally friendly and renewable form of energy, is gradually receiving attention from around the world. This article provides an overview of the development history, global layout, and several major thermal systems of geothermal power generation. Special mention was made of Italy as the world’s earliest country to utilize geothermal power generation, as well as China’s progress in the field of geothermal power generation. In addition, it also introduced the important raw materials provided by Junyuan Oil Group for global geothermal power generation projects.

Keywords: geothermal power generation; Clean energy; Thermal system; Raw material supply

Main text:

In the context of global energy structure transformation, geothermal power generation has become a shining star in the clean energy field with its unique advantages. Since Italy built the world’s first geothermal experimental power plant in 1904, geothermal power generation technology has gone through more than a hundred years of development. Nowadays, 32 countries around the world have established geothermal power plants with a total installed capacity of over 8 million kilowatts, making them an important choice to replace traditional fossil fuels.

In the global layout of geothermal power generation, countries such as the United States, Italy, Japan, and New Zealand are in a leading position. Especially in the United States, its installed capacity of geothermal power generation ranks first in the world, with Unit 11 of the Gaisse geothermal power station having a single unit capacity of up to 106000 kilowatts, demonstrating the enormous potential of geothermal power generation.

China started research in the field of geothermal power generation relatively late, but significant progress has also been made in recent years. Since the late 1960s, China has successively built several geothermal test power stations, of which the Yangbajing geothermal power station in Xizang, as the largest geothermal power station in China, has been operating safely and stably. The construction and operation of these power stations have accumulated valuable experience for the development of geothermal power generation technology in China.

The thermal system of geothermal power generation mainly includes geothermal steam power generation thermal system, expansion method geothermal water power generation thermal system, and intermediate medium method geothermal hydropower thermal system. These systems are suitable for geothermal fields in different temperature ranges, providing technical support for achieving the full utilization of geothermal resources.

It is worth mentioning that Junyuan Petroleum Group, as an important participant in global geothermal power projects, provides key raw materials such as isopentane and isobutane for global geothermal power projects. These raw materials play an important role in the thermal system of geothermal power generation and are one of the key factors to ensure the efficient operation of the geothermal power generation system.

Looking ahead to the future, with the continuous growth of global demand for clean energy, geothermal power generation will usher in a broader development space. Especially in many developing countries, geothermal resources are particularly abundant and have enormous development potential. It can be foreseen that in the near future, geothermal power generation will become one of the important pillars in the global clean energy field.

Geothermal Energy Powers New Zealand


Geothermal power development in New Zealand first began in the mid-1950s, and there is the potential for the supply of up to ten per cent of the country’s power needs. New Zealand already has over 300 MW of installed geothermal capacity. In recent years, deregulation of the power industry has encouraged further development, and two new plants entered commercial operation late last year.


The original settlers of New Zealand, the Maoris, who arrived around 800 years ago from the central Pacific, used the natural geothermal springs for bathing and the very hot springs and geysers for cooking. Now the country uses this natural energy to supply around three per cent of its power needs, and is seeking to further develop its potential.

New Zealand is on the south-west corner of the Pacific “ring of fire”, the chain of volcanic activity which extends up through the Pacific Islands, Indonesia, the Philippines, Japan, Alaska, the west coast of the USA, and down to the tip of South America. This volcanic activity arises from weaknesses in the earth’s crust where the Pacific tectonic plate meets neighbouring plates.

There have been a number of major volcanic eruptions in the region, the most recent being the Tarawera eruption of 1856 and the largest being the eruption which formed Lake Taupo around 400 AD. The ancient Chinese recorded the impact of the ash emitted by the latter on their weather. Where there is volcanic activity there are often geothermal fields capable of commercial development for power generation.

New Zealand was one of the early developers of geothermal power with the Wairakei project being the first large scale development of a water dominated geothermal field in the mid-1950s. There has been a second phase of geothermal development since the mid-1980s, stimulated largely by deregulation of the electricity industry which allowed the distribution companies to be more active in generation development.

There is geothermal activity spread over both islands of New Zealand with the main high temperature fields of volcanic origin in the Rotorua-Taupo area in central North Island. Most of the other geothermal activity in the country is of tectonic origin and the heat flows and temperatures are not sufficient for commercial power generation.

Early developments

The first geothermal fields to be developed were Kawerau and Wairakei in the Rotorua-Taupo area. The Kawerau field is 20 km inland from the town of Whakatane and is the site of New Zealand’s first pulp and paper mill. Here, geothermal steam is used directly in the mill for paper drying and for boiler feedwater heating as well as for electricity generation. The wells produce two phase geothermal fluid which is flashed to produce steam leaving the brine to be discharged to the ground. More recently some reinjection wells have been drilled and there is a programme to introduce full reinjection. Despite 40 years of abstraction, the field has maintained a good pressure and should have many years of further life.

In 1989 the local power company, Bay of Plenty Electricity, installed an Ormat binary plant of two units with an output of 2.2 MW (known as TG1) to utilise the energy in the 172°C brine from one of the wells. This was followed in 1993 by a second Ormat unit of 3.6 MW (known as TG2) on a separate brine flow. Both units utilise isopentane as the working fluid and are air cooled.

Wairakei, 9 km to the north of Taupo and first commissioned in 1959, was the first major geothermal power station in New Zealand. The Wairakei geothermal field consists of a pumiceous pyroclastic reservoir underlain by ignimbrites and capped by lacustrine mudstone. The upflow temperature is 270°C with typical production temperatures of 230°C. The wells generally produce two phase flow, with dry steam in some areas. This was the first wet geothermal field in the world to be utilised for commercial power production.

Their are two stations at Wairakei utilising steam at intermediate pressure (3.5 bar) and low pressure (0.1 bar). The current net output is 153 MW and the annual energy production 1300 GWh. Originally there were high pressure (12.6 bar) turbines as well, but these were moved to Ohaaki when the reservoir pressure declined. The station design originally incorporated a heavy water plant for the British nuclear programme, but this was dropped before construction.

However, the Wairakei power station is a major source of contaminants in the Waikato River. Around 1100 t/h of steam is condensed in the turbines’ spray condensers which use the river water directly, and around 3500 t/h of brine is discharged to streams which flow to the river. A programme is therefore underway to reinject the brine and the feasibility of further generation from the brine energy is also under review.

In response to the oil crises of the 1970s, the government investigated and drilled most of the known geothermal fields in the Taupo-Rotorua area. Many of these showed commercial potential and the 13 km2 Broadlands field was selected for the development of the Ohaaki geothermal station. This station is owned and operated by Contact Energy, one of the two state-owned generating companies, which operates the station remotely from its other geothermal station, Wairakei.

A total of 51 wells with an average depth of 1000 m were drilled, and a 103 MW station was completed in 1989. The 24 production wells produce two phase fluid which is separated to a steam flow for the power station and a brine flow which is pumped to eight reinjection wells. The 12.5 bar steam is fed to two 11.5 MW back pressure turbines which were originally installed at Wairakei. Steam from these turbines at 3.5 bar, supplemented by low pressure steam from the wells, supplies two 47 MW Mitsubishi condensing turbines.

Ohaaki was the first large scale reinjection of brine in New Zealand and the first use of a concrete natural draught cooling tower. Due to field pressure decline the station now operates at 80 MW giving an annual energy production of around 750 GWh. Despite the reinjection of brine and condensate, there has been considerable subsidence in parts of the steam field and areas adjacent to the Waikato River.

New capacity

The McLachlan power station, located about 5 km from Taupo, is the first privately owned power station in New Zealand and has been developed by a joint venture of a Taupo businessman and the Auckland electricity distribution company Mercury Energy. These partners have taken an unconventional approach in order to reduce the capital costs – it can be hard to reach financial closure for a geothermal project in New Zealand’s wholesale market.

The power plant is sited on one edge of the Wairakei geothermal field, and is drawing from the same resource as the Wairakei geothermal station. In that area of the field there is a relatively shallow steam cap and the station takes dry steam from four wells of around 750 m depth. The total project cost was $57 million (NZ$81 million) and full commercial production started in June 1997.

Because the station draws from a resource utilised by an existing station there were considerable difficulties in obtaining the necessary planning consents. The consents to draw steam were granted under the now repealed Geothermal Energy Act following protracted negotiations with the government-owned generating company and public hearings. The consents to draw steam are not sufficient to operate the station at the full output of 53 MW, and the station operates at minimum load during the night when electricity market prices are at their lowest levels and at full output during the day. There were also problems with obtaining the air discharge consents when a local group appealed the consents granted, resulting in a six month delay in project commissioning.

The McLachlan plant has a single 55 MW gross output Fuji condensing turbine of conventional design including an underslung shell and tube condenser and a hydrogen cooled generator. This gives a turbine hall configuration very similar to any other steam unit, with the operating floor high above ground. The turbine and generator were originally destined for a station on the Geysers geothermal field in California, but were never installed due to the over exploitation of the field and consequent pressure decline becoming apparent before the installation commenced.

The unit was stored under controlled conditions for a number of years and refurbished for 50 Hz operation and the lower steam pressure before shipment to New Zealand. This mainly involved changes to the turbine blades and the installation of a much larger non-condensable gas extraction system. Cooling takes place by conventional mechanical draught cooling towers, with the condensate used as tower make-up water. The blow down from the cooling towers and any excess condensate is pumped 2 km to a shallow well.

As part of the de-rating from 3600 r/min to 3000 r/min for 50 Hz operation, the generator voltage was reduced to 11 kV allowing use of standard New Zealand switchgear. The generator output is stepped up to 220 kV and fed into the Wairakei-Whakamaru 220 kV line, which is part of the National Grid, by a short simple Tee connection.

The turbine and generator came with only the control systems closely associated with their operation, and a new computer based overall station control system employing sophisticated graphic interfaces has been installed. Considerable work was necessary to uprate and adapt the electrical auxiliary systems to meet the current design codes, particularly as relates to the hazardous areas around the hydrogen cooling systems. The station is manned at all times, and all the maintenance work will be carried out by contract.

By utilising a second hand refurbished plant and new auxiliary and control systems, the joint venture has been able to complete the station with full manufacturers warranties at a considerably lower capital cost than if new plant had been utilised. The full engineering of the station and the detailed design of the changes to pipe work and the electrical systems was undertaken by the New Zealand consultant HPM Power.

The Rotokawa geothermal field is a deep high-temperature field covering 25 km2 and located 12 km north of Taupo. The surface manifestations of the field include small hot springs and an acidic lake which contains large quantities of colloidal sulphur from the oxidation of hydrogen sulphide as it bubbles to the surface. Eight wells were drilled between 1966 and 1986 as part of the government’s programme to assess the region’s geothermal resources. Most of these have since been capped and abandoned, either because they were not commercial producers or because of casing corrosion. The field has an estimated capacity of 100 to 200 MWe, and is being developed by a 24 MW station in order to allow careful monitoring of the resource before full exploitation.

The project is unique as it involves the participation of the indigenous Maori people in the development as a joint venture partner with Auckland electricity distributor Power New Zealand. The Tauhara North No. 2 Trust owns the land over the middle of the geothermal field, including the land around the well RK5 which is the best of the wells drilled by the government.

The project has two production wells of around 2000 m depth producing two phase fluid which is piped to a separator at the station. Steam is separated from the brine at 23 bar and both streams are used for electricity generation. The condensed steam is pumped up to the brine pressure, combined with the high pressure brine, and reinjected with no further pumping. There are three reinjection wells of 500 m depth, one of which is one of the original field exploratory wells.

In the process of selecting a turnkey contractor for the power station, the alternatives of condensing steam turbines and binary plant were compared. The plant finally selected is configured to use steam turbine and binary plant, and obtain the best of both technologies. The contractor for the 24 MW plant is Ormat Industries Ltd. of Israel.

To maximize the benefits of the high steam pressure, a back pressure turbine of 12 MW output is utilised to drop the steam pressure to 1.5 bar. This low pressure steam is condensed in two binary units of 4 MW output each. This configuration, called a “geothermal combined cycle unit” by Ormat, has the advantage of the low capital cost of a simple back pressure turbine and of condensing the steam in a heat exchanger where steam wetness is not a problem. There is a third binary unit also of 4 MW output utilising the hot brine flow, cooling it from 219°C to 150°C. The motive fluid in the binary units is isopentane and cooling is by air radiators.

Future development

There are a number of geothermal fields at various stages of development and some projects may proceed despite the low wholesale electricity prices, which are averaging around 3.0 c/kWh. In the far north the Ngawha field is being developed with an initial 8 MW Ormat binary plant due for commissioning in early 1998. The Mokai field is probably the best geothermal field in New Zealand with an output of 200 to 400 MWe. A contract has also been awarded to Ormat for a 50 MW plant of similar configuration to Rotokawa, and finance is now being finalized.

Resource use and planning consents have been granted for drilling the Rotoma and Taheke fields near Rotorua and have been filed for the Tauhara field near Taupo. There are also proposals to further develop the Kawerau field. Geothermal energy has met around three per cent of New Zealand’s electricity needs for many years, and has the potential to supply up to ten per cent. However, major impediments exist, including an excess of generating capacity in the short term leading to low wholesale electricity prices, and difficulties in obtaining the necessary planning and resource consents.

Eastland Group in New Zealand announces having entered the commissioning phase for its 25 MW Te Ahi O Maui geothermal power plant. With that New Zealand enters the 1 GW Geothermal Country club of countries that have an installed power generation capacity of more than 1,000 MW (1 GW).

Countdown to Te Ahi O Maui ‘go live’

  • July 2014: Resource consents are awarded to Te Ahi O Maui.
  • September 2015: Decision to proceed is signed off by Eastland Community Trust.
  • January 2016: Construction of project roads commences with Eastern Bay of Plenty contractor Grant Farms Ltd. Well pad construction is undertaken by Seay Earthmovers from Taupo.
  • May 2016: After assembly, inspections and karakia and blessings from the local kaumatua, drilling begins with MB Century and Halliburton. Ormat is engaged for the construction of the plant.
  • June 2016: Earthworks for the power plant and separator get underway with Seay Earthmovers.
  • Early 2017 onwards: Ormat mobilises to site to begin the foundation works for the power plant. Construction continues throughout 2017. MB Century is awarded the contract for the design and construction of the steamfield. Horizon Contracting, part of the electricity distribution company in the Bay of Plenty, constructs the transmission line.
  • September 2018: Plant construction is complete, and commissioning with Ormat begins. There will be a string of tests to ensure that the plant and all systems operate correctly, followed by a reliability run.
  • October 2018: Ormat is due to formally hand over Te Ahi O Maui to begin full commercial operations.
Dieng geothermal field, Indonesia

Isopentane, CAS No.:78-78-4, Chemical Formula:C5H12, SynonymsButane, 2-methyl-; iso-Pentane; 1,1,2-Trimethylethane; 2-Methylbutane; iso-C5H12; Ethyldimethylmethane; Isoamylhydride; Junyuan isopentane; 1,1-dimethylpropane; methylbutane; Iso-Pentane * Isopentane; Junyuan isopentane S; NSC 119476

Isopentane #ISOPentane #methylbutane #2methylbutane # C5H12 #C5H2 #CAS78784

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Darajat III geothermal plant, Indonesia

First-of-its-kind isopentane waste- gas-to-power plant for Ghana

Isopentane power plant

GE Power and Marinus Energy are to collaborate on a pilot project to capture waste isopentane gas and use it as a fuel source for generating electricity. The Atuabo waste to power independent power project will use the isopentane to run a TM2500 mobile gas turbine installation, making it the first TM2500 based power plant in Sub-Saharan Africa to use isopentane gas. This gas would otherwise be flared.


The first phase of the Atuabo plant will have an installed capacity of 25 MWe. As additional gas is brought onshore, the plant will be expanded to 100 MW. Additional isopentane fuel will eventually be stripped off an offshore gas supply and processed at Atuabo by the Ghana National Gas Company.

The gas turbine will start on lean gas and transfer to the isopentane mix over time. The power plant is intended to operate at base load throughout its life. 

Other recent GE power projects in Ghana include the 400 MW Bridge project, the first LPG fired power plant in Africa and the largest LPG fired power plant in the world, and the 200 MW Amandi power plant, said to be one of the most efficient power plants in the country. 

  • Junyuan Petroleum Group is a renowned manufacturer of Isopentane. Its core competencies are specialty solvent manufacturing. At maximum capacity, more than 800,000 tons of specialty solvents can be produced and processed here annually.

Isopentane
Product Information
CAS Number: 78-78-4
Other Names: 2-Methylbutane, 1,1,2-Trimethylethylane, Butane, 2-Methyl-, Ethyldimethylmethane.
Boiling point: 81.86°F (27.70°C)
Density: 0.62 g/cm³
Chemical formula: C5H12
Average Molar mass: 72.15 g/mol
Classification: Alkane
Isopentane, also called methylbutane or 2-methylbutane, is a branched-chain saturated hydrocarbon with five carbon atoms, with formula C₅H₁₂ or CH(CH₃). Isopentane is an extremely volatile and extremely flammable liquid at room temperature and pressure. It is also the least dense liquid at standard conditions. The normal boiling point is just a few degrees above room temperature and isopentane will readily boil and evaporate away on a warm day.

LPG / PROPANE POWER GENERATION

Liquefied Petroleum Gas (LPG, Propane) is fast becoming the fuel of choice for power generation in rural and other remote, off-grid locations, in lieu of its less environmentally friendly counterparts such as diesel, coal and fuel oil.


Distributed Power Generation & Combined Heat and Power (CHP)

For decentralized, distributed power generation models and combined heat and power (CHP) applications, clean-burning LPG is also an obvious choice, offering an economical and environmentally friendly alternative to conventional fuels, that can be implemented far more quickly and at a lower cost, delivering ROI within highly desirable time-frames.

Back-up Power Generation

LPG is also gaining popularity as a supplemental or back-up fuel to compliment power generated from renewable energy sources and technologies—including solar and photovoltaics (PV) and wind power generation—which can be prone to interruption.

LPG VAPORIZATION & FLOW CONTROL

For most power applications, LPG must be vaporized before it can be fed—under high pressure—into reciprocating engines or aeroderivative gas turbines.

LPG gasification systems must maintain set flow rate, pressure and temperature in order to achieve the strict specifications required by power generation engines and turbines.

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