It Pays To Complain Politely!
I like Nakd bars.
My favourite was the Cocoa Mint bar, but I was having difficulty getting them.
I complained politely and found out that they had been discontinued.
The company said they’d send a few others for me to try.
I wasn’t expecting a box of nine.
Note the box came in the padded bag on the left, so it came through my letterbox, without needing to be collected from the Post Office.
How many Christmas parcels have to be collected, because companies don’t pack them properly?
Exciting Renewable Energy Project for Spennymoor
The title of this post is the same as that of this article on the Durham University web site.
This is the first paragraph.
In January 2016, local residents Alan Gardner, Cllr Kevin Thompson and Lynn Gibson from the Durham Energy Institute at Durham University, met a team of academics to explore the advantages renewable energy and specifically the use of geothermal resources could bring to Spennymoor.
And this is the last.
Durham University is one of the world leaders in this research field. Spennymoor now has an opportunity to be at the forefront of that research. What the outcomes will eventually be is unknown at this stage but being able to explore the opportunity by the best in the business is encouraging.
Charlotte Adams mentioned in the article is the academic, who did the presentation I saw yesterday and talked about in Can Abandoned Mines Heat Our Future?.
Everybody, who lives in a mining area, should read this article and show it to everyone they know.
Funding Nemo: £600m Power Cable Connects UK And Belgium
The title of this post is the same as this article in The Guardian.
This is the first paragraph.
A £600m cable connecting the UK and Belgium’s energy systems is about to be switched on, becoming the first of a new generation of interconnectors that will deepen the UK’s ties to mainland Europe just as it prepares to leave the EU.
It runs between Richborough in Kent and Zeebrugge in Belgium and is the fifth interconnector to be connected to Great Britain.
Other interconnectors connect to Ireland, Northern Ireland, France and the Netherlands.
In Large Scale Electricity Interconnection, I discuss the rest of the interconnectors, that are being constructed or planned.
We could see up to fifteen in operation in a few years.
As to Nemo, it was originally thought that the UK would be importing energy from Belgium, but as Belgium needs to service its nuclear power stations and will be shutting them in the next few years, the power will sometimes be flowing the other way. Especially, as more large wind farms come on stream in the UK!
It is my view that Icelink could change everything and Belgium’s possible future power shortage, makes Icelink far more likely.
Wikipedia describes the interconnector between Iceland and Scotland like this.
At 1000–1200 km, the 1000 MW HVDC link would be the longest sub-sea power interconnector in the world.
As more interconnectors are built between the UK and the Continent, including a possible link between Peterhead in North-East Scotland to Stavanger in Norway, which is called NorthConnect, the UK will begin to look like a giant electricity sub-station, that connects all the zero-carbon power sources together.
- Denmark will supply wind power.
- France will supply nuclear power.
- Iceland will supply hydro-electric and geothermal power.
- Norway will supply hydro-electric power.
- The UK will supply nuclear and wind power.
Other sources like wind power from France and Ireland and tidal and wave power from the UK could be added to the mix in the next decade.
The Consequences For Gas
Our use of gas to generate electricity in Western Europe will surely decline.
If projects, like those I discussed in Can Abandoned Mines Heat Our Future?, come on stream to provide heat, the role of gas in providing heating in housing and other buildings will decline in the UK.
We also shouldn’t forget the role of hydrogen, which could also replace natural gas in many applications. It would be created by electrolysis of water or as a by-product of some industrial processes.
Hydrogen could also become a valuable way of storing excess electricity produced by tidal, wave and wind power.
It is unlikely, we will develop a totally gas-free economy, as methane is a valuable chemical feedstock to produce other chemical products we need.
Conclusion
Not many people will be sorry, except for President Putin and a few equally nasty despots in the Middle East.
Arup Called In To Help New Zealand Run Ports And Trains On Hydrogen
The title of this post is the same as that of this article on Global Construction Review.
This is the first paragraph.
UK consulting engineer Arup has been brought in to help design and deliver a hydrogen factory for New Zealand’s second largest port. Ports of Auckland said it plans to build a production facility to make the gas from tap water, which it will use to fuel ships, trucks, buses, cars and trains.
It is all part of the aim of making the port of Auckland, zero-carbon by 2040.
I think we’ll see other large self-contained sites like ports, airports, rail container terminals and large industrial complexes using hydrogen, as it may offer advantages over batteries in terms of range, lifting capacity and vehicle size and weight.
There is also no problem with the regular replacement of batteries in equipment like mobile cranes, which in New Zealand’s case will mean importing new ones.
I suspect, hydrogen may be more affordable to run than batteries for Auckland.
Can Abandoned Mines Heat Our Future?
The title of this post, is same as that of the title of a public lecture I attended at The Geological Society this afternoon.
This page on the Geological Society web site, gives a summary of the lecture and details of the speaker; Charlotte Adams of Durham University.
The Concept
The basic concept is simple.
- Abandoned coal mines had their pumps turned off when they are closed and the worked areas have flooded with water, that is now at temperatures of around 12 to 20°C.
- As fifteen billion tonnes of coal have been extracted from UK coalfields, that is a lot of space to flood. An estimate of around two billion cubic metres is given.
- This means that the water holds somewhere between 27.9 and 46.5 GWH of energy in the form of heat.
- Heat pumps would be used to upgrade the temperature of this water, to provide hot water at useful temperatures for space heating.
For those unfamiliar with the concept of a heat pump, Wikipedia gives a good explanation, of which this is the first paragraph.
A heat pump is a device that transfers heat energy from a source of heat to what is called a heat sink. Heat pumps move thermal energy in the opposite direction of spontaneous heat transfer, by absorbing heat from a cold space and releasing it to a warmer one. A heat pump uses a small amount of external power to accomplish the work of transferring energy from the heat source to the heat sink.
In connection with this project, the heat source is the warm water in the mines and the heat sink is the water that is circulated to heat the buildings.
Wikipedia goes on to say this.
In heating mode, heat pumps are three to four times more effective at heating than simple electrical resistance heaters using the same amount of electricity. However, the typical cost of installing a heat pump is also higher than that of a resistance heater.
Wikipedia also has a section, which descries the use of heat pumps in district heating.
It should also be noted, that as with lots of technology, heat pumps are much improved, from the one I installed in a swimming pool in the 1980s.
Gas Is Replaced By Renewable Energy
The electricity to drive the heat pumps could be derived from renewable sources such as hydroelectric, solar, wave or wind.
Effectively, the system is using intermittent sources of electricity to create a constant source of heat suitable for space heating.
Would The Mines Run Out Of Heat Or Water?
As I understand it, the water in the mine will continue to be heated by the heat in the mines. The father of a friend, who came with me to the lecture was a coal miner and my friend confirmed it was hot in a coal mine.
The water will of course continue to flood the mine and the water pumped to the surface will probably be returned.
So the system will continue to supply heat for space heating.
How Long Will The System Supply Heat?
The system has the following characteristics.
- It is electro-mechanical.
- It is powered by electricity.
- Water is the heat transfer medium.
- Additives like anti-freeze will probably be applied to the water used for heat transfer.
There is no reason the system can’t be designed, so that it supplies heat for many years with regular maintenance and updating.
How Does The System Compare To Bunhill 2 Energy Centre?
In Bunhill 2 Energy Centre, I described Islington’s Bunhill 2 Energy Centre which uses heat generated in the Northern Line of the London Underground to provide district heating.
I am fairly sure that a lot of similar technology will be used in both applications.
This page on Wikipedia is entitled London Underground Cooling.
There is a section, which is entitled Source Of The Heat, where this is said.
The heat in the tunnels is largely generated by the trains, with a small amount coming from station equipment and passengers. Around 79% is absorbed by the tunnels walls, 10% is removed by ventilation and the other 11% remains in the tunnels.
Temperatures on the Underground have slowly increased as the clay around the tunnels has warmed up; in the early days of the Underground it was advertised as a place to keep cool on hot days. However, over time the temperature has slowly risen as the heat sink formed by the clay has filled up. When the tunnels were built the clay temperature was around 14ºC; this has now risen to 19–26ºC and air temperatures in the tunnels now reach as high as 30ºC.
So one big difference is that the Underground is warmer than the mine and this should make it a better heat source.
I feel that engineers on both projects will benefit from the ideas and experience of the others.
Would Infrastructure Funds Back This Technology?
In the UK, there are several infrastructure funds set up by companies like Aberdeen Standard, Aviva, Gresham House and L & G.
In World’s Largest Wind Farm Attracts Huge Backing From Insurance Giant, I explained why Aviva had invested nearly a billion pounds in wind farms to support pensioners and holders of their insurance policies.
Comparing the risk of using abandoned mines to heat buildings and that of offshore wind turbines generating electricity, my engineering knowledge would assign a greater risk to the turbines, providing both were built to the highest possible standards.
It’s just the onshore and offshore locations and the vagaries of the weather!
I think it is true to say, that infrastructure funds will back anything, where there is an acceptable long-term income to be made, commensurate with the costs and risk involved.
But then Government or any public or private company or organisation should not pay over the odds for the energy delivered.
Conclusion
Charlotte Adams in her lecture, asked if abandoned mines can heat our future.
The answer could well be yes, but there are other sources of heat like the London Underground, that can also be used.
The Anonymous Widower 