[sdfjkl]

This has never bothered me until moving on a boat, where top-loading fridges (often ice boxes with a compressor kit retrofitted) are the norm. Because energy supply is very limited. They are integrated into the kitchen work surface and double as a temporary workspace when closed.

So it's possible to save space _and_ energy.

Now the standup kitchen fridges in houses really bother me. Every time I see someone open one, I imagine seeing all that cold air being sucked out by the opening door and falling on the ground.

[avian]

> I imagine seeing all that cold air being sucked out by the opening door and falling on the ground.

Air has negligible thermal mass compared to everything else solid or liquid in the fridge. As long as you don't leave the door open long enough that fridge contents themselves start warming up, the energy losses are minimal.

Quick back-of-the-envelope calculation:

My fridge is around 1.0 x 0.5 x 0.5 m, giving a volume of 0.25 m3.

Outside temp is around 25 C, inside the fridge is around 5 C.

Air specific heat capacity is around 1000 J/m3/K.

If the fridge only contains air (it does not), and all air gets cycled out when I open the door (it does not), the fridge needs to pump out 5 kJ of heat after each door opening.

I don't know what's the typical efficiency, but let's say the fridge pumps out as much heat as you put electrical work into it (COP=2).

That's around 0.0014 kWh wasted per door opening.

It's nothing compared to just steady state consumption of a closed fridge.

[londons_explore]

The calculation isn't as simple as it seems...

Typically your house air will have a dew point above 5C. That means, when it enters your fridge, dew will condense on the inside. The latent heat of condensation is really high. Just 10 grams of water could be 22 kilojoules of energy released.

That water will eventually end up as ice on the evaporator (since the evaporator coil in a fridge-freezer typically has to run sub-freezing because it is shared with the freezer). Thats more energy loss (3 kJ for our 10 grams).

Then the defrost mechanism will kick in to melt it into the drain - which is a resistive heater normally. So 3kJ again. The resistive heater typically heats far more than it needs though - a bunch of heat will be wasted into the metal of the coil and air in the fridge - which in turn will need more refrigeration to correct.

So all in all, the energy loss of opening the door of the fridge is dominated by the water you're letting into the fridge, not the energy loss of the cold air.

This analysis is tricky enough and with enough variables (house humidity, design of fridge, amount of other 'wet' food in the fridge, etc.) that I haven't seen anyone attempt to come up with a cost number, either numerically or experimentally.

[avian]

I agree with the humidity argument, although even if you 10x the energy loss opening the fridge is still relatively small contribution to total energy use unless you open your fridge tens of times per day. It's nowhere close to what the article claims.

The defrost thing I guess depends on the fridge. Mine has two coils and the one in the 5 C non-freezer section generally stays above the freezing point when the compressor is not running. It does does not have a resistive heater.

[s1artibartfast]

10g is a pretty extreme number if you aren't living in the tropics, maybe even then.

Also, if your ambient relative humidity is less than 100, not all or none of the water will condense.

[marcosdumay]

10g of water condensation isn't extreme. It's about typical for moderate temperatures, like the 25°C of the OP's example. On the tropics you will have much more than that.

But 10g of water freezing is extreme. There are mechanisms on the fridge to avoid the water freezing.

[s1artibartfast]

100% relative humidity is ~23 grams/m^3 at 25C

That is <6 grams if you sucked every molecule out of 0.25 m^3.

Air at 0 C still has about 5 grams/m^3, so the number would actually be lower.

50% RH at 25C to 100% RH at 0 would condense ~1.6 grams of water from the air .

To hit 10g you need 45+ grams per m^3, which would be 100% humidity at >37C (eg, the tropics)

[londons_explore]

Think of an ice cold beer sitting out. Quite quickly it gets covered in dew.

But the inside of your fridge and all the goods inside has the surface area of hundreds of ice cold beers.

It isn't just a matter of how much room air you trapped in the fridge, but how much passes the beers in the fridge while you have the door open - perhaps 10x as much.

[s1artibartfast]

I have always wondered how big a factor the warming of items via passive convection was. I suspect this could be the biggest energy cost

[robbiep]

That’s really interesting, thanks

[bmacho]

I also made the same quick calculation, opening the door ~20-30 times is equivalent to placing a bottle of milk in it, in terms of joules. (Milk has ~4x the mass, and ~6x the heat capacity in terms of mass.) Is that negligible? Well, depends on the usage, i guess, but the 10x efficiency from the article certainly can't come from it.

Maybe if you open the door, the moving air heats the things inside much faster?

edit: in a sister thread they state that the humidity of air plays a more significant role.

[andai]

Article claims the chest fridge is 10-20x more efficient, how does that work?

[mcv]

I've only ever had standup fridges, but long ago I had a free-standing one, whereas the past decades it's been integrated fridges, and I notice those integrated fridges are just terrible; way more ice accumulation in the freezer section, and the fridge running more and more loudly. And this is a top brand, A+ energy rated fridge. I suspect that because of the way they're integrated into the kitchen, they have a much harder time getting rid of their heat. And maybe the door doesn't close quite as reliably?

I suspect the big problem with chest freezers/fridges for most homes is their shape. People want a flat counter on everything that they can leave stuff on, while still being able to access the fridge, so a fridge opening from the top isn't going to fit anywhere. But I've been thinking: how about a chest fridge that slides out? That way it can disappear underneath cupboards or counters, while you can still access them without having to clean up your counter top.

[bluebill]

I have a chest freezer converted to a fridge. If I had the skills (I don't), I would make the lid so that it can rise vertically at the push of a button. That is, hydraulics, at the push of a button the door would lift vertically and all the shelves (I would have built if skilled and the shelves would be grates so as not to trap cold air and bring it up out of the box) would rise with it. The top of the lid could be a work surface when closed.

There is the issue of cleanup and condensation. That is something would would need to be solved or at least be made easy to clean.

[mihaaly]

What irritates me (also friends) is relatives opening it and standing their thinking about the food, keeping it open for a minute or more without actual activity.

I wonder if transparent door would be a gain here, with worse thermal insulation but allowing to locate things and contemplate before opening the door and allowing the cold to escape to the floor.

[blensor]

Does it make much of a difference if you keep it open for 20 seconds or 2 minutes?

I imagine that as soon as most of the cool air has flowed out of it (which should happen quite quickly), the additional energy loss is minimal

There are compromise versions where there is a small door at half height in the big door, through which you can get the bottles/milk crates out of the side of the door.

What I am wondering is if there is a way to solve this with at technical solution that keeps the current standup design but makes it energy efficient.

For example: An opening at the bottom of the door that sucks cold air in when the door opens and transports it to the top back of the compartment. While open, most of the cold air would be saved and it's only a ventilator that's running for a few seconds

[almostarockstar]

Perhaps a transparent door, inside the main insulating door. So people could open the fridge and stare slack jawed without letting all the cold out. Condensation blocking the view would be an issue I suppose.

[londons_explore]

Many fridges start beeping after 30 seconds of the door being open.

People quickly learn to ignore the beep while they "quickly make breakfast" and then put the sausages and eggs back in the fridge and close the door after eating breakfast. #billpayerfrustratedwithhisfamily

[qikInNdOutReply]

You can feel it on summer days, if you dont have AC and get something from the fridge on your bare feet.