Comparison Choetech BS006 vs Allpowers S2000 Pro
Add to comparison |  |  |
|---|---|---|
| Choetech BS006 | Allpowers S2000 Pro | |
from $1,179.36 | from $664.00 | |
| User reviews | ||
| TOP sellers | ||
2 USB A ports, 2 USB A QC3.0 ports, 2 USB-C ports. Car cigarette lighter, 2 DC5521 ports. LiFePo4 battery 1997 Wh. New models (from 2026) have a smartphone control feature (confirm in the store before purchase). | Case included. Socket for van 30A | |
| In box | charging station | charging station |
| Rated power | 2000 W | 2400 W |
| Peak power | 4000 W | |
| Output waveform | sinusoid (PSW) | sinusoid (PSW) |
| UPS function |  |  |
| Switchover time to battery | 10 ms | |
Outputs | ||
| Sockets (230 V) | 3 | 4 |
| USB-A | 2 pcs 5В/2.4А 12 W | |
| USB-A (quick charge) | 2x QC3.0 18 W | 4 5В/3A, 9В/2A, 12В/1.5A 18 W |
| USB-C | 2 pcs 5 A 100 W | 2 pcs 5 A 100 W |
| Car cigarette lighter | | |
Inputs (station charging) | ||
| From solar panels | | |
| Input port XT60 | | |
| Anderson port | 11.5 – 50 H / 500 W | |
| Add. ports | C13/14 (charging) | C13/14 (charging) |
Battery and charging time | ||
| Battery type | LiFePO4 | Li-Ion |
| Battery capacity | 1997 W*h | 1500 W*h |
| Charging time (socket) ≈ | 120 min | |
| Charging time (socket + solar panel) ≈ | 90 min | |
| Charging time (solar panel) ≈ | 300 min | 139 min |
| Charging power (socket) | 1100 W | |
| Charging power (solar panel) | 500 W | 650 W |
General | ||
| Smartphone synchronization | Bluetooth and WiFi | Bluetooth |
| PSU | built into the body | built into the body |
| Display | | |
| Backlight | | |
| Carrying handle | | |
| Operating temperature | -10 °C ~ +40 °C | |
| Dimensions | 386x275x306 mm | 375x245x250 mm |
| Weight | 22 kg | 14.5 kg |
| Warranty | 2 years | |
| Added to E-Catalog | january 2023 | january 2023 |
Compare Choetech BS006 and Allpowers S2000 Pro
The charging stations Choetech BS006 and Allpowers S2000 Pro each have their unique features that may influence the user’s choice. The Choetech BS006 offers a power of 2000 W and a battery capacity of 1997 Wh, making it a good option for long-term use. It also has 3 sockets and 4 USB ports, including QC3.0, which is convenient for charging multiple devices simultaneously. Charging time from the network is about 120 minutes. On the other hand, the Allpowers S2000 Pro has a higher nominal power of 2400 W and a peak power of 4000 W, making it more powerful for demanding devices. It also has 4 sockets and 4 USB ports, but the charging time from the network is only 90 minutes, which is an advantage. Users note that the Allpowers S2000 Pro is lighter (14.5 kg compared to 22 kg for the Choetech) and has a built-in power supply, which simplifies use. However, the Choetech BS006 stands out with a higher battery capacity and additional DC outputs. The choice between these models depends on your power and portability needs.
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Glossary
Rated power
Power that a device can consistently produce for an indefinitely long time without any unpleasant consequences. For normal operation of the charging station, the rated power must be at least 15 - 20% higher than the total power of all devices simultaneously connected to it.
Peak power
Some electrical appliances (in particular, units with electric motors - refrigerators, air conditioners, etc.) consume significantly more energy at startup than after reaching the operating mode. For such a load, the peak power of the charging station must be taken into account - its indicator must be higher than the starting power of the load.
UPS function
Charging stations with UPS function switch consumers to backup power from their own battery, acting as an uninterruptible power supply. In comparison with full-fledged UPSs, switching does not occur instantly, but with a certain delay (about 10-30 ms). To use this function correctly, you must first study the instructions for the charging station, which often describes the correct procedure for connecting the intended consumer devices.
Switchover time to battery
The delay (usually in milliseconds) between the power going out from the outlet and the moment when the station starts feeding connected devices from its battery, maintaining "pass-through" power. The shorter this time, the higher the chance that devices won't notice the drop at all: for routers, cameras, NAS, and PCs, this is critical because a long pause can cause a reboot, loss of connection, or even filesystem errors. Essentially, this is the same parameter as in a classic UPS, but for charging stations, it greatly depends on implementation: models with a more "UPS-like" switching scheme switch considerably faster, while some stations formally have a UPS mode but actually create a noticeable break or activate the output only after "realizing" the network's loss. In practice, this point helps distinguish a charging station that is truly suitable as a UPS for sensitive electronics from an option "for lights and charging": for example, for home internet and video surveillance, minimal switching time is important, while for lamps, charging phones, or a heater, a brief pause is typically not critical.
Sockets (230 V)
Total number of outlets with output voltage. This is, in fact, the number of devices that can be simultaneously connected to the charging station without the use of splitters, extension cords and carriers. Accordingly, weaker charging stations have one or two sockets in their submission. Powerful charging stations already have three or more sockets “on board”.
USB-A
Full-size USB-A connectors are popular in computer technology, commonly used in charging adapters for 230 V household networks and 12 V car sockets. These outputs have become widespread in charging stations for charging gadgets.
— The total number of such ports can be quite varied (1 USB, 2 connectors, 3 ports, and even 4), as they allow for charging and, in some cases, powering various low-power devices — smartphones, tablets, power banks, lamps, and more.
— Current Strength. The maximum current delivered through the USB-A connector to the charging device. Note that different ports of the charging station may output different currents (for example, 1.5 A and 2.1 A). In such cases, the highest current strength is usually specified.
— Power. The maximum output power in watts (W) that the charging station is capable of delivering through the USB-A connector to a single charging gadget.
— The total number of such ports can be quite varied (1 USB, 2 connectors, 3 ports, and even 4), as they allow for charging and, in some cases, powering various low-power devices — smartphones, tablets, power banks, lamps, and more.
— Current Strength. The maximum current delivered through the USB-A connector to the charging device. Note that different ports of the charging station may output different currents (for example, 1.5 A and 2.1 A). In such cases, the highest current strength is usually specified.
— Power. The maximum output power in watts (W) that the charging station is capable of delivering through the USB-A connector to a single charging gadget.
USB-A (quick charge)
Full-sized USB-A ports with fast charging support. This feature allows you to charge your smartphone, tablet, or other connected devices much more quickly. The charging process occurs at increased power, with current and voltage regulated at each stage to stay within optimal values. However, keep in mind that there are many fast-charging technologies today, and not all of them are compatible with each other.
— Current strength. The current parameters delivered through USB-A fast charging ports. Note that different ports of the charging station may output different voltage and current parameters. This section specifies the current strength values at a certain voltage (for example, 5V / 3A, 9V / 2A, 12V / 1.5A).
— Power. The maximum power in watts (W) that the charging station can deliver through the USB-A fast charging port to a single charging gadget. High output power allows for faster charging. However, the charging device must support the corresponding power; otherwise, the speed will be limited by the gadget's characteristics.
— Current strength. The current parameters delivered through USB-A fast charging ports. Note that different ports of the charging station may output different voltage and current parameters. This section specifies the current strength values at a certain voltage (for example, 5V / 3A, 9V / 2A, 12V / 1.5A).
— Power. The maximum power in watts (W) that the charging station can deliver through the USB-A fast charging port to a single charging gadget. High output power allows for faster charging. However, the charging device must support the corresponding power; otherwise, the speed will be limited by the gadget's characteristics.
Anderson port
A large two-pole connector for connecting batteries, chargers and all kinds of equipment where reliable contact is required for the sake of ensuring stable operation of the equipment. Anderson Port is resistant to moisture changes, can be used both for indoor and outdoor mechanisms. Thanks to identical mating parts, a pair is formed by two identical connectors, which are rotated 180 ° relative to each other. Most often, Anderson port is used in mobile homes on wheels.
Battery type
— Li-Ion. The key advantage of lithium-ion batteries is their high capacity with small dimensions and weight. Also, Li-Ion batteries are not subject to memory effect and can charge quite quickly. Of course, this option is not without its drawbacks - first of all, it is sensitivity to low or elevated temperatures, and if overloaded, the lithium-ion battery can catch fire or even explode. However, thanks to the use of built-in controllers, the likelihood of such “accidents” is extremely low and, in general, the advantages of this technology significantly outweigh the disadvantages.
— Li-Pol. An improved version of lithium-ion technology (see the corresponding paragraph): the liquid electrolyte in Li-Pol batteries is replaced with a solid polymer. At the same high capacity, the batteries have become more compact, there is practically no “memory effect” in them, and the likelihood of fires and explosions in the event of critical violations of operating conditions is minimized. The downside of these improvements was increased cost and increased sensitivity to frost. However, most often these shortcomings are not significant.
— LiFePO4. Lithium iron phosphate batteries are a modification of lithium ion batteries (see corresponding paragraph) designed to eliminate some of the shortcomings of the original technology. LiFePO4 batteries are characterized by a...large number of charge/discharge cycles, chemical and thermal stability, low temperature tolerance, short charging time (including high currents) and safety in operation. The likelihood of an “explosion” of a LiFePO4 battery when overloaded is reduced to almost zero, and in general, such batteries cope with high peak loads without problems and maintain the operating voltage almost until discharge.
— Li-Ion NMC. A type of lithium rechargeable battery using a complex alloy in the manufacture of the cathode. It contains nickel, manganese and cadmium. This “recipe” allows you to increase the power of a power source based on Li-Ion NMC elements. Batteries of this type have a high specific capacity and a stable discharge voltage, provide a long operating time of the charging station with high performance, are characterized by a complete absence of “memory effect”, maintain functionality over a wide temperature range and are fireproof.
— VRLA. Acid batteries with a regulating safety valve to release excess gas. The abbreviation VRLA stands for Valve Regulated Lead Acid. Batteries of this type have a sealed, non-separable design and come in two types: AGM VRLA (the battery plates are equipped with a layer of fiberglass absorbent) and GEL VRLA (with a gel electrolyte in a jelly-like state). Batteries with a control valve are resistant to deep discharges, do not require topping up with distillate throughout their entire service life, and do not emit hydrogen or oxygen.
- Semi-solid State. An advanced type of lithium-ion battery (see above), which combines some of the characteristics of liquid and solid batteries. It uses an electrolyte that is in a semi-soft or gel-like state, making the batteries more resistant to leakage than traditional wet batteries. Semi-solid state technology allows for a significant increase in the energy density of cells. As a result, it is possible to make compact batteries with high energy intensity.
— Li-Pol. An improved version of lithium-ion technology (see the corresponding paragraph): the liquid electrolyte in Li-Pol batteries is replaced with a solid polymer. At the same high capacity, the batteries have become more compact, there is practically no “memory effect” in them, and the likelihood of fires and explosions in the event of critical violations of operating conditions is minimized. The downside of these improvements was increased cost and increased sensitivity to frost. However, most often these shortcomings are not significant.
— LiFePO4. Lithium iron phosphate batteries are a modification of lithium ion batteries (see corresponding paragraph) designed to eliminate some of the shortcomings of the original technology. LiFePO4 batteries are characterized by a...large number of charge/discharge cycles, chemical and thermal stability, low temperature tolerance, short charging time (including high currents) and safety in operation. The likelihood of an “explosion” of a LiFePO4 battery when overloaded is reduced to almost zero, and in general, such batteries cope with high peak loads without problems and maintain the operating voltage almost until discharge.
— Li-Ion NMC. A type of lithium rechargeable battery using a complex alloy in the manufacture of the cathode. It contains nickel, manganese and cadmium. This “recipe” allows you to increase the power of a power source based on Li-Ion NMC elements. Batteries of this type have a high specific capacity and a stable discharge voltage, provide a long operating time of the charging station with high performance, are characterized by a complete absence of “memory effect”, maintain functionality over a wide temperature range and are fireproof.
— VRLA. Acid batteries with a regulating safety valve to release excess gas. The abbreviation VRLA stands for Valve Regulated Lead Acid. Batteries of this type have a sealed, non-separable design and come in two types: AGM VRLA (the battery plates are equipped with a layer of fiberglass absorbent) and GEL VRLA (with a gel electrolyte in a jelly-like state). Batteries with a control valve are resistant to deep discharges, do not require topping up with distillate throughout their entire service life, and do not emit hydrogen or oxygen.
- Semi-solid State. An advanced type of lithium-ion battery (see above), which combines some of the characteristics of liquid and solid batteries. It uses an electrolyte that is in a semi-soft or gel-like state, making the batteries more resistant to leakage than traditional wet batteries. Semi-solid state technology allows for a significant increase in the energy density of cells. As a result, it is possible to make compact batteries with high energy intensity.