Yes, I think an eco charging mode for the 737 would be an awesome feature. A way to throttle the output.
When I go camping, I usually bring my 26800 with me for the slow charging and longevity. Plus it is a lot less expensive so if I drop it in a puddle I am not going to stress as much.
Is there a firmware update capability for this? I think not?
I also camp but I take my 20000 PD because it with its charger is smaller. Even so I use it’s usbA output as I benchmarked it a long time ago and it’s 5V is more efficient than its 9V for my phone. That may be the phone’s fault I only counted recharges not a USB meter which measures passed thru Wh.
I was also going to write more about how bad value this 140W but I looked and the current prices across the range are roughly double what I paid.
I’m no expert on usb power banks. I mainly deal with automotive programming and encoding. But if it can communicate over the the usb 2.0 pins that it does have for sure. It doesn’t need those pins to negotiate the power delivery with the receiving unit but still has them. I would assume that the microcontroller responsible for the negotiation would be able to accept coding. In the tear down video it didn’t look like there were any engineering headers on th board so I would also assume that they did the initial encoding through pins A6-A7 and B6-B7 as that would be the most cost effective way to get data into the package as it is already there. Even my 10k redux pd power bank has pins a4 through a9 and b4 through b9.
The 6 cells are connected as one large series circuit for a nominal voltage of 21.6V, unlike the previous PowerCore Elite III 26K which used 2 series circuits of 4 cells (14.8V) connected in parallel. This is the reason for the PowerCore 24K’s cuboid design. The supply unit takes up the top front portion where the ports and display are and the cells start at the rear of the supply unit, go down and around the bottom of the power bank, and then end up back at the rear of the supply unit. You can clearly see this if you observe the indents in the cells in the video. If Anker did not want to go with the cuboid design but still wanted the higher nominal voltage, the company would have needed to make it really long.
How do you know they’re in series? I couldn’t see from teardown how.
Link to where you saw that please.
If it is series, which is rare, then it only takes 1 of 6 cells to fail for unit to fail.
Shape is not remotely related to series as , you know, wires exist.
More common is 2s3p as it takes more cells to fail (but you lose capacity). E.g. you can alternate up/down and solder the ends together just as you can in parallel with the cells all pointed same direction. Think about it.
The cells are indeed connected in series. The circuit is in a “zigzag” shape, starting and ending at the rear of the top front portion responsible for supplying power. On the bottom of the power bank it says “4000mAh 21.6Vdc / 86.4Wh.” In the video, you can see the little indents on one side of each cell indicating where the positive side is. To use 3 series circuits of 2 cells would be very inefficient and produce lots of heat as the power would have to be converted from ~7.4V up to 20V, or even worse, 28V. This technique to increase the nominal voltage is how power bank companies have managed to produce units that supply the full USB PD rating of 100W and beyond.
If true then it will lower the life of the product.
The most efficient buck-boost is double the voltage so it’s more efficient to make 140W 28V from around 14V. So even 3s2p would get you to 12.6V nearer to 14V.
You do have to buck boost 21.6V to 28V and it’s not more efficient to get to 28V from 21V it’s better from 14V.
I just didn’t expect they’d worsen product reliability doing it that way.
My old PowerCore Speed 20000 PD from 5 years ago when USB PD was still in its infancy still works perfectly. Someone else in the family has a PowerCore III Elite 26K 87W and an old PowerCore 20100 that also work perfectly. Besides, isn’t it more efficient the closer the nominal voltage is to the output voltage? When AllThingsOnePlace tested this unit he got 84% discharge efficiency compared to the 82% he got from the Baseus Blade 100W (1 series circuit of 4 cells, 14.8V). According to your chart it was getting 87% discharge efficiency at 20V. It also had 76% charge efficiency compared to the Baseus’ 71%. For it to be more efficient at 15V than at 20V is really odd. Also, 2 series circuits of 3 cells would yield 11.1V.
Good unboxing video
Anker doesn’t advertise this but the PowerCore 24K has full-spectrum (3.3-21V) variable voltage (aka PPS) at 5A. This means that it conforms to the specifications of Qualcomm Quick Charge 5. In the video from ChargerLAB shown in an above post, the POWER-Z KM002C device mentions “QC5” in the “PD3.1” section.
This video from ChargerLAB features a nubia REDMAGIC 7S, a phone with a QC5 power setup, charging from various USB PD AC adapters (no portable units were tested.) The phone can be seen taking over 90W from the adapters that have up to 20-21V variable voltage at 5A. With the adapters that either do not have variable voltage or do have it but only up to 11V or 16V, the phone simply sets the adapters to 9V⎓3A.
With the adapters that have the high variable voltage, the POWER-Z device shows that the adapters are set to 19.5V⎓5A, but according to it, the phone is taking ~17V⎓5.4A. There is nothing wrong with the voltage, but that current is over USB PD’s official maximum of 5A from power sources and cables other than the ones that come with the phone. Has anyone tried plugging this or any other QC5-equipped device into the PowerCore 24K using a 5A cable? I would not want to plug one of these phones in only for it to constantly trip the overload protection, or even worse, damage the power bank and/or cable!!!
FYI these still work
Still works but even so I could see the direct of my currency and grabbed another earlier this year
It’s voltage and current is compatible with all my devices including my laptop I got this year
It’s got 12% more stored energy than this priced item
Admittedly I got lucky, my laptop will take any voltage, it works off 5V, if it didn’t I’d be forced up to items which by today’s standards are probably not worthwhile getting
Tried an ASUS ROG Strix G15. That computer wouldn’t work reliably with the PowerCore 24K. It would start taking power from it and then the power bank would reset. It would keep doing the same thing over and over until I unplugged it. Someone on r/anker has the same problem with this combination of device and power source. When they try an Anker USB PD AC adapter, it works fine. The computer seems to set the power bank to the correct setting (20V⎓5A), but I wonder if there is a bug in ASUS’ firmware that makes it start taking power in a way that trips the power bank’s overload protection. Does anyone here with an ROG Strix G15 have the same problem and is there a firmware update on ASUS’ end?
I wanted this powerbank, but now I really want one, just because of how excited you are lol. This was great 
The PowerCore 24K has an easter egg! Read one of the latest reviews on Amazon to see it.
Link? You don’t state which country. USA most likely.
Review says need special cable.
It comes with the required cable doesn’t it?
True you do need to buy a charger. Personally I’d be ok with a 100W charger to save a few $
Mine came with a cable. It says “MAX 140W” but ChargerLAB connected it to the POWER-Z device and the E-Marker chip reported 50V⎓5A, implying it is a 240W cable. Hopefully future 36V and 48V sources and devices will not fry it.
If it’s saying it can handle 50V 5A then it should. Higher voltage is much harder to fry something than rated than a higher current than rated as the pins width of the USB standard can handle 48V but the guage of the wire determines what current it handle.
I don’t see the use of USB for higher Wattage as a good trend as it’s actually increasing costs. A “dumb” 240W charger is lower cost, much simpler electronics. I do like the removal of proprietary barrel connectors but I’m perfectly happy with my current maximum device USB at 45W (my Chromebook).
Maybe E-Marker chips only come in either 50V or 20V varieties, and Anker is simply warning the consumer not to use a device that runs at more than 28V.
