SimonD

Clearly, I've never measured them properly to begin with 🙄 My assumption was that as with timber products which is what I'm more used to working with, or pipes, you get what's specified. And maybe it explains why I had to get rid of the plasterer I was using? I was just told that gaps above 3mm must be prefilled, nothing about leaving a gap when boarding but he and another did most of the boarding so far. Oh dear!

I've just plaster boarded up a ceiling and while doing so realised that plasterboard sheets seem to have shrunk? First I thought it was either me or my tape measure and then I twigged the sheets are all actual 2395mm and not 2400 long - my mistake was not taking this missing 5mm into account when I cut short ends of the plasterboard. So rather than waste a load of sheets, I now have some very annoying gaps in my ceiling. Main question is: what should I fill these gaps with? Drywall join filler or some expanding foam? My sense is drywall filler is more sensible. The other thing I also realised is that all my sheets are 3mm less than 1200mm some along both the walls and ceilings the screws get closer and close the batten/stud edge. Is this sheet dimension new or have I just been blind to it before?

Windows or Linux machine? I'll test on my windows 11 machine to see if I can replicate. And put it in the bug list for further investigation.

32.6/66.2 (although you can just use room internal measurements) = 0.492

Hmm interesting. The card you should be seeing looks like this: I wonder whether you have the older version of the app from before I sorted the radiator saving issue locally. Can you close your browser and/or do a hard refresh? On both my browsers - Chromium and Firefox, decimal entry in the form I have is fine from keyboard. and I have the add & select button rather than add to database. Would be interesting to see what you get following full refresh. Ah, no sorry! You're in the Radiator Library editor on the multi project beta! So the card is correct. Inputs on both my browsers work fine for decimals on water content. What browser are you using?

Yes, of course, share the numbers.

Best thing to do with odd shaped rooms, it just calculate the P/A ratio yourself and enter it into the calculator. In the Floor Dimensions and Exposure Card, select Manual P/A, then measure the length of the exposed perimeter of the room and divide by the total floor area - then you can just add the p/a ratio into the Enter P/A Ratio Directly - this is specifically designed for complex shapes. You can the ignore all the other dimension inputs in that card. Hope that makes sense?

Because this is an implementation of the CIBSE reduced method, these are really the only choices for this particular version. However, when I get the full BS EN 12831:2017 method tested and run, there will be full freedom for proper and complete fabric inputs for the calcs. The CIBSE method covers pretty much 90% of projects we see, which is why I went for the quicker win to begin with. The tool will still give you a pretty good result right now as fundamentally this gives you a conservative result as that's what all the methods tend to do. However, to get around this now, you can select the tab to the right of SAP Estimate and select the Measured/Tested air permeability and then add your SAP design figures, that completely gets around the problem and is the better approach right now.

It is, and applied well and in the right place, it produces an extremely good finish. I've been in many houses where it looks stunning. A lot of the other paints like the trade ones are developed I think to go on easily and hide a multitude of sins.

Absolutely, they are all about the surface area, which does dictate output. The app just uses the shortcut of the Delta T 50 and then applies a correction factor for the system design temps, so we don't need to worry about the surface area being involved in the app. We could, but it was enough to resolve the UFH output calcs as they are calculated based on the variables input for each room and those took some effort to resolve and get right - or at least in the ballpark. If there is enough call for it, I may add a calculator based on surface area for rads as I know the question comes up a lot with older existing panel rads with no fins. It's in my backlog. Yes, that's what I should have said ...

Thanks for letting me know. That's my fault. I was playing around with users and authorisation earlier to create the new beta engineer test and in doing so seemed to break how radiators are saved to specific users - it was saving fine for anonymous but not any registered users! Anyway, it should be fixed now 😊 Yeah, the width is actually termed length in catalogues so you always have dimensions = height by length e.g. 600x1200 or 1800x445 Glad to hear you're getting on with it okay!

Any radiators you add go into your own 'company' radiator database linked to you as a user, so if you had several projects, you'd build up your own database of radiators. Nobody else has access to those or can edit/change them, they're yours. In the wider version for managing several projects, there's even a project settings page where you can add edit and delete you own database. If you want access to this wider version with multi-project capability, ping me your registered email address and I'll change your settings to 'beta' test engineer in the system. I'll add flat tube radiators to the type as a system addition, but for now, two column would work fine - the type doesn't really matter that much, it's more for your own reference. The important bits are output at DT50 and water volume really. And then size if you're putting a new one into a space... Not at all, I've done that to check volume on existing rads myself, but luckily most rad manufacturers now provide l/m figures in the tech spec. Stelrad actually even provide Kv. To get the l/m min take your total measure volume and divide by length in meters - so in your case the 0.578m Best thing to do in the workflow is add all your standard elements into the U-value tab and create your U-value library. Do this especially for all your floor U-values by using the Floor U-value calculator as floor U-values vary according to the Perimeter/Area ratio. Once that's in you'll get an automatic drop down when you add an element in the rooms tab. These will then auto-populate and add the thermal bridging addition. I've been back and forth on the editing of value directly in the room as if you skip creating the U-value library and you're working on a large project, inputing into individual room elements gets very tedious, which is partyl why I locked it to force users back to the U-value library. I ought to put a user hint in there about this. The other bit to bear in mind here is that if you add a door or window to the room, you'll get another automatic drop-down where you can select which element area this door or window needs to be subtracted from. So if you have an external wall added, this will be listed in the dropdown and you just apply it. The reason to do this is because this will apply the correct calculation for fabric loss, but at the same time used the full external element area for the ventilation & infiltration calculation. To make things easier to follow, I tend to add the wall element, then add any corresponding window or door to that element and subtract it. Then move onto the next element. Then in the elements also remember to change any internal element's Design Delta T (e.g.partition wall) to the difference between the two adjacent internal spaces and not leave it at default. Elements roof, ground floor suspended, external wall are all automatically added to exposed envelope so if you have a ceiling that is the external envelope, then you need to add this to exposed area by selecting Exp. I have on my to do list a load of videos to walk new users through the tool. If you spend a lot of time inputing this stuff, it follows pretty much a normal design workflow but it's not obvious at all for someone not in the industry.

Ah okay. The finished Readme is now up on Github so should contain all you need to know for Linux install: https://github.com/OpenHeatLoss/OpenHeatLoss You'll notice in the Readme that while the UI is completely functional there is room for improvement especially for mobile and accessibility. With the amount of input for a design, I'd hesitate to use it on a phone unless I was just accessing it for reference and using the survey checklist. But obviously it's all ready to go with the hosted service

Is this for installing locally from Git or using the hosted version? If installing locally, it's currently designed to work as a web stack using React/Express/Postgresql, so you'll need to install those and access it through your browser. Initial development was on windows, so it can be installed on a windows machine, but the majority of the development has been on Linux as that's what all the hosts use. The hosted version is best through PC & browser, but it will work on both tablet and phone through browser. I'm currently completing the Readme for Git which will guide you through the setup for self-hosting.

yes and with some controls they're intelligent enough to balance load between 2 units to keep them both in more efficient operating conditions, or separate dhw from ch.