Difference between revisions of "Morden Hall"
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=== Site Visit 07/10/2022 === | === Site Visit 07/10/2022 === | ||
The purpose of the visit was to install the control panel, cabling, and get at least one sensor online. | |||
Time taken: 45 minutes. | |||
A follow up visit will be required to add additional sensors and wire in the pulsed output from the meter. | |||
<gallery widths="250" heights="300"> | <gallery widths="250" heights="300"> | ||
File:Mhtmeter.jpg|Meter terminals | File:Mhtmeter.jpg|Meter terminals | ||
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</gallery> | </gallery> | ||
Following | |||
Following the visit, the data can be seen on the client dashboard. | |||
The graph below shows the outside air temperature (in blue) and the generator casing temperature (in yellow). After startup the generator temperature can be seen to climb as electricity is generated. | The graph below shows the outside air temperature (in blue) and the generator casing temperature (in yellow). After startup the generator temperature can be seen to climb as electricity is generated. | ||
Revision as of 16:24, 7 October 2022
https://www.nationaltrust.org.uk/morden-hall-park
The ‘Livinggreen Project’ was an HLF and EU funded initiative to show how heritage assets can be updated to be highly sustainable. It was implemented in five European cities. Morden Hall Park in South London, with over 750,000 visitors a year, was chosen as the sole UK project.
The site achieved a BREEAM ‘Excellent’ award, however the true potential of the installation has never been fully realised and is in need of some TLC.
At Thermal Integration we were responsible for the original hydraulic design of the system, based on the use of thermal stores and unvented storage to pull all heat sources and loads together as efficiently as possible.
Following ten years of declining performance, the National Trust has agreed to allow us to revisit the installation with a view to realising its original potential, to understand where things went wrong, and to learn from their experiences so that future renewables projects are guaranteed to work as intended.
The mix of renewable technologies on the site makes it unique, and a perfect case study for demonstrating how open source control and monitoring can make all the difference in outcomes. The site is also open to the public as a demonstration of renewables, so ensuring the system works properly is paramount to establishing confidence in the various technologies.
The Design
Case_Study_Morden_Hall
Schematic_and_Wiring
291162-M-103_Htg_&_Plant_Schematic_(A1)
The Plan
- Install an open control system to provide remote access and allow monitoring to proceed
Completed 28/09/2022 - Install temperature sensors to see how heat generators are acting
Completed 28/09/2022 - Install store sensors to view general operation
- Install heat meters to better understand how heat generators are performing
- Review the plumbing and recorded operational data to work out a full list of problems
- Fix the problems
- Monitor performance
- Create a simplified client interface allowing them to more easily control the system and see problems as they occur
- Setup alarm routing so that any future problems are trapped and reported
- Generate operational data that shows how the various renewables operate under different weather and load conditions
Executing the Plan
Site Works 28/09/2022
Parts List
| Description | Quantity | Cost | Notes |
|---|---|---|---|
| Open Source Control Panel | 1 | ||
| NTC Pipe Temperature Sensors | 4 | ||
| 2 Core 0.75mm Silicone Cable | 15m |
Report
Colin, Frederick, Following on from this weeks site visit, I have some feedback. I will put these notes on the wiki for reference. The installation went to plan, and the new panel is online and reporting data. I have had a much closer look at things and together with the data we have a plan. The new dashboard I have setup is at https://hwwiki.ddns.net/dashboard/ I know you have been having trouble accessing this so I have taken a snapshot at... https://snapshots.raintank.io/dashboard/snapshot/lgD7AU8x5uYc1jMomnG4gkPcDiaS10nr I will be changing the server address to something more firewall friendly, or you should be able to add an exception into your firewall for now, or use a non work computer. I have updated the wiki site with details on the site visit, including wiring diagrams, photos, and some findings. https://hwwiki.ddns.net/index.php/Morden_Hall Now we have 2 days data from the solar thermal and the heat pump, we can see that the solar is kaput, while the heat pump is looking healthy, firing roughly 4 times per day, and is on most of the time delivering 63C heat (perfect peak temperature). It does look like the heat pump circulating pump keeps going when the heat pump is off, causing the pipework around the plantroom to act as a radiator all the time. This can be easily confirmed and fixed. Their looks like room to save carbon as follows: * Control the heat pump circulating pump. * Weather compensate the heat pump to reduce temperatures and achieve a more steady state operation to match actual loads. * Get the solar thermal going. This is the only totally zero-carbon heat source and given the panel area should contribute a significant amount. * Better room temperature control. I intend to fully examine the underfloor heating on next visit. * Arguably, the biomass is also a further carbon saving - while marginal grid electricity generation is non-renewable - so bringing it back online would be of net planetary benefit. It is a make that is smokeless zone approved, however I have not looked at it yet so will follow up, possibly with a pressure test to determine if/where there is a leak. The system controls are all mechanical and we may find room for further savings once we examine the hot water loops and the operation of the thermal store pumps. Any upgrades can be made using the new controller we fitted this week. We will also be: * Bringing the TV display back online. It would appear the original kit above the TV is dead so we can easily replace with a small controller and display the online dashboards. It has a slideshow feature so we can tailor screens to the display size and rotate them every minute or so. * Adding a pressure sensor the the thermal stores. This will help determine the nature of the pressure loss you are experiencing. We can also add a simple email alarm to this. As per request we are very happy to pull in operational data from the hydro-electric screw turbine. This will require another similar small panel in the shed, and will provide: * Temperature readings from generator casing * Meter readings of energy generated * We can pull in a webcam feed of the turbine (if only for project demonstration) We will add these to the dashboard. I just need to confirm if the meter has either pulsed output, M-Bus or Modbus. My photo came out blurry. Could yo send me another photo of the meter labelling, thanks. Kind regards, Richard.
Monitoring Hydro-Electric Archimedes Turbine
The Archimedes Turbine generates electricity from a relatively low water head of a few metres, making them ideal for smaller sites between 5kW and 500kW.
They are safer to the passage of fish than traditional hydroelectric, and resilient to the passage of large debris.
The turbine at Morden Hall is an 8.5kW system, capable of providing electricity for roughly 18 medium sized properties. At current electricity prices (2022) it has a roughly 10 year pay-back, if continuously operational.
One of the clients requests is to add some visibility to the hydro-electric system. This is to include temperature monitoring of the turbine casing, and monitoring the electricity generated.
Electricity meter
The generator
Turbine Shed
Site Visit 07/10/2022
The purpose of the visit was to install the control panel, cabling, and get at least one sensor online.
Time taken: 45 minutes.
A follow up visit will be required to add additional sensors and wire in the pulsed output from the meter.
Meter terminals
Heatweb Controller
Sensor cabling
Sensor 1
Following the visit, the data can be seen on the client dashboard.
The graph below shows the outside air temperature (in blue) and the generator casing temperature (in yellow). After startup the generator temperature can be seen to climb as electricity is generated.
