Which way would be your preferred way to use the amazing AeroPress coffee maker?

AeroPress coffee maker Series 5

The AeroPress is a brilliant coffee maker which can produce consistently good results, with a couple of different options for how you use it.

The classic method is the quickest which is simply..

coffee – water – stir – press.

The AeroPress packaging still says stir for 10 seconds and push for 20 seconds – it really can be that easy to make great coffee. You can watch a video of Artistry’s Sarah demonstrating this method.

Then there’s the inverted method which is a little slower and more intricate, but the favoured method of baristas worldwide.

This involves pouring the ground coffee and the water into an inverted AeroPress, stirring and then letting the coffee brew for a few minutes.

Then adding the filter and mesh cap and quickly turning over to press the coffee through into a mug below.

This allows for lots of experimentation with different grinds on the coffee and different brew timings.

So you can decide if you want a quick well-made coffee that beats instant coffee hands down – or to take more time over the coffee and the experimentation to perfect your own brew technique!

There’s now a Series 5 version of the AeroPress, which has shiny gold lettering and a cloudy brown look to it.

Colours and materials used have changed over the years as the design has been adjusted from the original clear with blue guide marks.

Water Temperature Experiments for Coffee (6): …

Recording Temperature of Poured Water

This series of posts started from a fairly simple question in my head – what is the rate of cooling of water from boiling – to have some sense of what temperature coffee making is conducted at when there are no thermometers to hand! It has turned into a rather more complex investigation than first thought – but has been at least a little fun along the way. Here, were close to the end of my write-ups!

We’ve already covered that when transferring water after boiling from an electric kettle into another vessel such as a Buono kettle (in order to achieve greater accuracy for pour over coffee making) there seems to be about a 3 or 4 degree Celcius loss of temperature straight away.

So this post is about the expectation that as the water is then poured from the Buono onto the coffee grounds themselves there is likely to be another (notable?)drop in temperature.

That was the expectation and indeed has been exactly what I observed in my experiments.

In order to attempt to measure this effect, I rigged up a set-up (imperfect, but trying to get close to something realistic) where I could pour water from the Buono spout directly onto the bulb of the thermometer. That’s the closest I’ve been able to construct to something reasonably meaningful.

I conducted most of my previous efforts over a 10 minute observation window – however the idea of pouring water from a Buono kettle for 10 minutes was never going to be achievable – I did try and control it well, and managed around 5 minutes each time, which I think was a good achievement (also meant my rate of pour should have been similar on each attempt).

Chart of Observed Temperatures (time from Boiling Point)
Top Line (darker) : Observed Temperatures in Electric Kettle
Next Line (mid-tone): After being poured into Buono Kettle
Bottom Line (lightest): Temperatures of the Pour

The temperature within 30 seconds had dropped to 90 degrees Celcius, but took till almost 6 minutes to drop the next 5 degrees – by which point it was almost equal to the observations of the temperatures achieved in the Buono kettle itself(with no pouring).

That line on the chart that resulted did puzzle me at first – although the greater initial drop in temperature made sense, the slower rate of decline in the following minutes than observed in the kettles did seem odd ( I haven’t worked all the way through this yet, but I think one of Newton’s Laws does help – I need to look into that a bit more, and will try and write something in a few days).
What also seemed odd is that the water poured from the Bouno (having been poured in the Bouno from the electric kettle) was at a lower temperature in the earlier moments of observations than the water in the open-top vessels.

Observed Temperatures from Boiling Point
Top Line (darker): Temperatures in Electric Kettle
Next Line (mid-tone): After being poured into Buono Kettle
Bottom Line (lightest): Temperatures of the Pour
Yellow Line: Temperature in open-top container

OK – only for 30 seconds, but that it crossed the line, then crossed back again made me think that this science lark was just far too complicated!

But here could perhaps be the most important thing to understand from these experiments – that the pour itself is where the temperature changes the most (pouring from the kettle used for boiling, into another vessel in the first place, and from the pouring vessel onto the coffee).

And therefore different styles of pour, durations of pour, or methods of dealing with the water will mean that the temperature, in effect, on the coffee is different.

This is where the water is coming into most contact with the air (or perhaps more importantly (scientifically) the much lower ambient temperature) and so is losing the most heat.

So I guess one of my biggest conclusions is that when we’re talking temperature we may or may not be talking the same thing – the temperature of the water can change greatly quite quickly depending on how it is transferred from the boiling vessel to the coffee.

Water that is the same temperature for 2 different coffee making techniques at the starting point could actually be at very different temperatures when hitting the coffee grounds seconds later.

This coffee making really is both an art and a science!!

please note: boiling and hot water can be dangerous if not handled with care!
(despite the haphazardness of some of my approaches above, I did take some care and would suggest anyone else does the same: and children should be accompanied by an adult)

Water Temperature Experiments for Coffee (5): ….

Hot Water onto Coffee Grounds

Interim Conclusions …?

Instead of being one simple set of experiments to while away an afternoon and get the brain cells working – this little exploration has actually turned into a set of experiments and blog notes and pseudo scientific activity that has occupied rather more than the initial expectation!

Where we’ve travelled so far, I think, is that the temperature of the hot water as it hits the coffee could vary perhaps rather a lot – affected by all that can happen between the boiling of the water and the drips hitting the coffee.

What I seem to be able to conclude so far is that if the water remains in the kettle it retains its temperature much better than if poured into another vessel. If this other vessel is closed top (e.g. Buono kettle) the temperature will perhaps drop 3 to 4 degrees on the initial pour from the kettle, then hold at a slower rate of decline than if poured into an open-top vessel (where over a few minutes the temperature difference may easily be 10 to 15 degrees Celcius).

All of that fairly logical (and some would say obvious or a matter of common sense perhaps), but I’ve found it rather interesting to be able to place some (amateur) quantification on what’s going on, and helpful to think through what may be affecting the readings.

But the key issue is perhaps what temperature the water is as it hits the coffee. And for my own normal coffee making at home, this involves first pouring the boiling water from the electric kettle into the Buono, and then pouring from the Buono onto the coffee grounds themselves.

So the idea that there might be a second heat loss as poured from the Buono kettle seems to be a logical expectation, and that’s exactly what we get – but the results did puzzle me at first.

(I’ll write that up next post…..)

please note: boiling and hot water can be dangerous if not handled with care!
(despite the haphazardness of some of my approaches above, I did take some care and would suggest anyone else does the same: and children should be accompanied by an adult)

Water Temperature Experiments for Coffee (3):…

Kettle

From my initial inquisitiveness about what temperature is reached when you leave boiled water standing, a whole lot of other questions gathered. The reason for the initial inquisitiveness was about making good coffee and having some idea of what temperature the water might be at when there is no thermometer to hand: because the taste and characteristics of the coffee are affected by the temperature of the water.

From in initial set of observations and thoughts, I had a need to try some different scenarios to explore whether all the things that I thought might affect the rate of cooling had any meaningful effect.

Actually on my first modifications, I didn’t really get any very different results from pouring the water into a ceramic mug to cool rather than the plastic jug. I guess if my observations were more precise there might have been a small discernible difference, but obviously not big enough to show up for me.

However, measuring the temperature of the water in the vessel where it was boiled (electric kettle in my kitchen experiments) made a big difference – seemingly in the rate of cooling and in the temperatures reached in my 10 minutes of recording temperatures each time.

Not really surprising, but I’m attributing this (perhaps rather rashly, but it seems logical) to the cooling on the water from the pour from the kettle to the jug (or mug), as well as to the fact that the tapered shape of the (at least my) kettle exposes less water directly to the air.

TemperatureAtTimeSinceBoilingPoint_ElectricKettle

Lilac line represents observed temperatures of water in kettle at time (mins:secs) since water boiled.

Rather than getting to c 95 degrees Celcius within the first 15 seconds, that temperature wasn’t reached until 2 and a half minutes. And the 90 degrees wasn’t breached until after 5 minutes of cooling, rather than approximately 60 seconds in the open-top experiments as I’ll now call the first set!

It took over three times as long for the water to cool to c85 degrees Celcius: 7 and a half minutes rather than approx 2minutes 30 in the open-top ones. The rate of cooling also seemed fairly steady in these Kettle experiments rather than changing (slowing down) in the open-top experiments.

TemperatureAtTimeSinceBoilingPoint_OpenContainerVsKettle

Lilac line represents observed temperatures of water in kettle, yellow line for water in open-top container.

This means that if using a rule of thumb as to what temperature the water is at some time after boiling, there could be some great differences depending on where your water is (in relation to where it boiled).

More to come – as we still haven’t got to an answer that is practical ……

please note: boiling and hot water can be dangerous if not handled with care!
(despite the haphazardness of some of my approaches above, I did take some care and would suggest anyone else does the same: and children should be accompanied by an adult)

Water Temperature Experiments for Coffee (2):

Jam Thermometer

So thinking of my first experiments – consistent as they were (within their own world of haphazardness) – I wasn’t really satisfied that I’d ended up with a measurement of the right thing. It was informative and revealing, but what about:

  • – The fact that I had done my observations at room temperature (the rate of cooling would have been different if the temperature were much lower or much higher).
  • – The fact that the vessel was made of plastic (of course the ability of the vessel to conduct heat will have an impact)
  • – The vessel was unheated on the first observation, but would have warmed up a little on later experiments (so slowing the rate of cooling?)
  • – The size of the vessel – surface area – probably has an impact on the speed of cooling, and especially, I’m guessing, the surface area of the top of the water.
  • – The fact that I had poured water into an open topped vessel of itself was likely to be important – what of the water that had remained in the kettle,
  • – What if I had poured the water into another contained and covered vessel? (such as a Bouno pouring kettle)
  • – And after all of that, it’s the temperature at which the water actually hits the coffee grounds that matters – so how to measure that?? And could this be particularly important if the rate of cooling on the pour is actually faster than the rate of cooling when water is standing.

I decided to repeat my experiments with some variations –to take account of what I thought would be the most important aspects:

  1. Pour water into a ceramic mug – different material, smaller surface area, especially smaller top of the water.
  2. Measure the temperature in the water boiler (kettle used to boil the water). Without lid (practicality rather than best experiment).
  3. Measure the temperature in a Buono kettle (having been poured from another kettle which boiled the water). With lid replaced between readings.
  4. Measure the temperature of a Buono kettle with lid being slowly poured directly onto the bulb of the thermometer – the closest I can easily get to measuring the water as it hits the coffee.

Inadequacies in all of the above in the way that they are conducted, what they are demonstrating, and whether they are measuring anything near reality – but interesting and a bit of fun. And some conclusions possible, I think!

More to come in future days -including the realisation that Newton had a law for ( some of) this……


please note: boiling and hot water can be dangerous if not handled with care!
(despite the haphazardness of some of my approaches above, I did take some care and would suggest anyone else does the same: and children should be accompanied by an adult)

Water Temperature Experiments for Coffee (1):

Water Temperature Experiments

Water cools from boiling, we all know this – but just how quickly?

It’s a question that puzzled me, and I could find no quick answer on my google searches that met my needs – so what better than to go back into a science lab and do some real-life experiments!
Well, a kitchen. And a set of semi-controlled slightly made up conditions as I went along and made my observations. I’m sure a real scientist would be able to tear my kitchen table methods to shreds. But I thought doing these would at least point me in the right direction.

One of the first things I learned about coffee was “don’t pour boiling water onto the coffee” and as I have come to learn more I’ve repeatedly heard temperature being held up as one of the great variables affecting the coffee.

In geeky mode then, thermometer at the ready every time you make coffee and all is well I suppose?? But what if a coffee needs to be made quickly, or you just don’t have a thermometer to hand?? – is there a rule of thumb for how long you let the water rest after the kettle has boiled?

So my experiments began.

I might add that the first thing I found on the internet after I completed my experiments was a paper on how quickly water cools after boiling – but as I’d gone to the effort, I will document my findings here anyway!

I started by getting a jam thermometer (borrowed from my mother-in-law) as – fairly obvious I know – a regular one would not cope with the high temperatures I needed to record. And as with most things, although the idea of such an experiment had been rumbling around my brain for some time, the decision to actually progress with this had a fairly random timing. So rather than not do it, best get hold of what would be available.

The first set of observations I made was also using what else was easily available, a plastic jug. Probably not the material I would have chosen if I had actually thought properly about it!
I took observations every 15 or 30 seconds – in part depending what else was going on in the kitchen (but never leaving a gap of more than 30 seconds on these).

During the first time I decided that 10 minutes was about the right duration to keep going (a mix of what temperature had been reached and how long it would take to do all this: I realised early on that I would have to repeat the experiment so that I knew whether it was just a fluke).

My random nature in proceeding with these experiments meant that I hadn’t created a lovely observations table to record my readings – but was just scribbling the findings on some cut-offs of paper.

I also realised that the nature of the thermometer that I was using meant that depending on the angle of my head to the instrument I could come up with 1 of 3 readings whether my head was above, straight-on, or below the mercury (actually a coloured liquid: don’t know what they actually put in thermometers!). I think that’s most of my confessions out of the way on this exercise!

So a little haphazard, but off I ventured with this activity – trying to ensure I was learning quickly so as not to invalidate my experiments too much!!

At first I was a little puzzled that I couldn’t get a reading of 100 degrees Celsius from the water in the jug, no matter how quickly I poured and measured. I attributed this initially to the fact that the mercury (not really mercury, but we don’t know what it is) took time to get to the temperature – but later realised that the act of pouring the water would be cooling it down too. Another realisation (again obvious, but best to think about it at some point: was that the ambient temperature could affect the rate of cooling – I was doing my experiments in a room temperature environment (somewhere close to 20 degrees Celsius).

I did organise myself a little better as I went along. and transferred my readings to an excel spreadsheet before I had taken too many. So as not to get confused, to have a proper saved record, and to be able to perform some calculations on them and chart them.

So by the end of the experiments some sense of order had been enforced.

Headlines were: that the water was at c 95 degrees Celcius within the first 15 seconds, that it had dropped to under 90 degrees by around a minute, and 85 degrees by between 2 minutes 15 to 2minutes 30. And that the rate of cooling was quickest at first, and then slowed.

The average of 4 observations is charted in the attached diagram (observed temperature – in degrees Celsius – on the vertical, and time since boiling – in mins:secs – on the horizontal).

I repeated the observations about 3 times- and was surprised at how consistent my results were (to say it wasn’t exactly lab conditions, that my eye level could have thrown it, and that the starting temperature of the vessel would have been different between the first time and subsequent times – when it would have been warmer)

Thinking about what might have affected things did lead me to conduct some slightly modified versions to explore different situations too. But I was pleased with my initial findings – charted below.

Temperature vs Time
The Time Taken for boiling water poured into a jug to cool.

More to come……

please note: boiling and hot water can be dangerous if not handled with care!
(despite the haphazardness of some of my approaches above, I did take some care and would suggest anyone else does the same: and children should be accompanied by an adult)