Comparison be quiet! System Power 11 BP011 vs be quiet! Pure Power 13 M BP025
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|---|---|---|
| be quiet! System Power 11 BP011 | be quiet! Pure Power 13 M BP025 | |
| Compare prices 1 | from $266.00 | |
| User reviews | ||
| TOP sellers | ||
| Power | 650 W | 650 W |
| Form factor | ATX | ATX |
Specs | ||
| PFC | active | active |
| Efficiency | 89 % | 94 % |
| Cooling system | active | semi-passive |
| Fan size | 120 mm | 120 mm |
| Fan bearing | sliding | sliding |
| Certification | 80+ Bronze | 80+ Gold |
| Cybenetics Efficiency | Gold | |
| ATX12V version | 3.1 | 3.1 |
| EPS12V version | 2.92 | 2.92 |
Power connectors | ||
| MB/CPU power supply | 24+8+4 pin | 24+8+4 pin |
| SATA | 5 | 5 |
| MOLEX | 1 | 2 |
| PCIe 8pin (6+2) | 2 | 2 |
| PCIe 16pin | 1 pcs | 1 pcs |
| Cable system | non-modular | modular |
Cable length | ||
| MB | 550 mm | 550 mm |
| CPU | 600 mm | 650 mm |
| SATA | 450 mm | 500 mm |
| MOLEX | 790 mm | 800 mm |
| PCIe | 500 mm | 500 mm |
Max. power | ||
| +3.3V | 20 А | 20 А |
| +5V | 20 А | 20 А |
| +12V1 | 54.17 А | 54.1 А |
| -12V | 0.3 А | 0.3 А |
| +5Vsb | 3 А | 3 А |
| +12V | 650 W | 650 W |
| +3.3V +5V | 120 W | 120 W |
| -12V | 3.6 W | 3.6 W |
| +5Vsb | 15 W | 15 W |
General | ||
| Over voltage protection (OVP) | ||
| Over power protection (OPP) | ||
| Short circuit protection (SCP) | ||
| Protection | OTP, OCP, UVP, SIP | OTP, OCP, UVP, SIP |
| Noise level | 12 dB | 8 dB |
| Manufacturer's warranty | 5 years | 10 years |
| Dimensions (HxWxD) | 86x150x140 mm | 86x150x160 mm |
| Weight | 1.97 kg | 2.32 kg |
| Added to E-Catalog | june 2025 | june 2025 |
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Glossary
Efficiency
Efficiency, in this case — the ratio of the power of the power supply (see "Power") to its power consumption. The higher the efficiency, the more efficient the power supply, the less energy it consumes from the network at the same output power, and the cheaper it is to operate. Efficiency may differ depending on the load; the characteristics can indicate both the minimum efficiency and its value at an average load (50%).
It should be noted that compliance with one or another level of 80PLUS efficiency directly depends on this indicator (for more details, see "Certificate").
It should be noted that compliance with one or another level of 80PLUS efficiency directly depends on this indicator (for more details, see "Certificate").
Cooling system
— Active cooling system. Uses a fan that constantly operates to remove heat from internal components. Unlike passive cooling, the active system provides better heat dissipation and stability under high loads, preventing overheating. However, it creates noise. To eliminate this, fans in such power supplies can have dynamic speed control (AFC – Automatic Fan Control), reducing speed at low power consumption.
— Semi-passive. Active cooling systems with automatic fan shutdown in situations where the load on the power supply is low and heat generation is reduced. Let us remind you that systems of this type are more efficient than passive ones, but they consume additional energy and create noise during operation. Accordingly, at low loads, when intensive cooling is not required, it is wiser to turn off the fans — this saves energy and reduces the noise level.
— Passive(radiators). Compared to fans, radiators have a number of advantages: for example, they do not create any noise and do not require their own power supply (thus reducing overall energy consumption). On the other hand, they are significantly less efficient, as a result — the power of power supplies with passive cooling does not exceed 600 W. In addition, such power supplies are quite expensive.
— Semi-passive. Active cooling systems with automatic fan shutdown in situations where the load on the power supply is low and heat generation is reduced. Let us remind you that systems of this type are more efficient than passive ones, but they consume additional energy and create noise during operation. Accordingly, at low loads, when intensive cooling is not required, it is wiser to turn off the fans — this saves energy and reduces the noise level.
— Passive(radiators). Compared to fans, radiators have a number of advantages: for example, they do not create any noise and do not require their own power supply (thus reducing overall energy consumption). On the other hand, they are significantly less efficient, as a result — the power of power supplies with passive cooling does not exceed 600 W. In addition, such power supplies are quite expensive.
Certification
The presence or absence of an 80+ certificate for the power supply. This certificate indicates high energy efficiency: to obtain it, the efficiency (see above) must be at least 80%, and in different modes (20%, 50% and 100% of the maximum load). There are several degrees of 80+:
— 80+. The original version of the certificate, assuming an efficiency of at least 82% (at least 85% for 50% load).
— 80+ White. The second name of the original 80+ certificate (see above).
— 80+ Bronze — efficiency not less than 85% (for half load — 88%).
— 80+ Silver — respectively 87% (90% for half load).
— 80+ Gold — 89% (92% for half load)
— 80+ Platinum — 90% (94% for half load).
— 80+ Titanium — 94% (96% for half load).
The power factor (see "PFC Type") must be at least 0.9 for the lower levels and at least 0.95 for the Platinum level. Also note that for redundant power used in server systems, the efficiency requirements are somewhat lower.
— 80+. The original version of the certificate, assuming an efficiency of at least 82% (at least 85% for 50% load).
— 80+ White. The second name of the original 80+ certificate (see above).
— 80+ Bronze — efficiency not less than 85% (for half load — 88%).
— 80+ Silver — respectively 87% (90% for half load).
— 80+ Gold — 89% (92% for half load)
— 80+ Platinum — 90% (94% for half load).
— 80+ Titanium — 94% (96% for half load).
The power factor (see "PFC Type") must be at least 0.9 for the lower levels and at least 0.95 for the Platinum level. Also note that for redundant power used in server systems, the efficiency requirements are somewhat lower.
Cybenetics Efficiency
Cybenetics Efficiency is a power supply unit (PSU) energy efficiency certification system that serves as an alternative to the 80 PLUS standard. It is more accurate as it considers efficiency at various load levels (10%, 20%, 50%, 100%) and at different input voltages (115V, 230V). The labeling of this system is identical to 80 PLUS:
Bronze — overall efficiency from 82% to 85% at 115V input voltage and from 84% to 87% at 230V;
Silver — 85 – 87% and 87 – 89% respectively;
Gold — from 87% to 89% (115V) and from 89% to 91% (230V);
Platinum — 89 – 91% at 115V and 91 – 93% at 230V;
Titanium — 91 – 93% (115V) and 93 – 95% (230V);
Diamond — ≥ 93/95%.
Bronze — overall efficiency from 82% to 85% at 115V input voltage and from 84% to 87% at 230V;
Silver — 85 – 87% and 87 – 89% respectively;
Gold — from 87% to 89% (115V) and from 89% to 91% (230V);
Platinum — 89 – 91% at 115V and 91 – 93% at 230V;
Titanium — 91 – 93% (115V) and 93 – 95% (230V);
Diamond — ≥ 93/95%.
MOLEX
The number of Molex (IDE) connectors provided in the design of the power supply.
Initially, such a connector was intended to power peripherals for the IDE interface, primarily hard drives. And although the IDE itself is completely obsolete today and is not used in new components, however, the Molex power connector continues to be installed in power supplies, and almost without fail. Almost any modern PSU has at least 1 – 2 of these connectors, and in high-end models this number can be 7 or more. This situation is due to the fact that Molex IDE is a fairly universal standard, and with the help of the simplest adapters, components with a different power interface can be powered from it. For example, there are Molex - SATA adapters for drives, Molex - 6 pin for video cards, etc.
Initially, such a connector was intended to power peripherals for the IDE interface, primarily hard drives. And although the IDE itself is completely obsolete today and is not used in new components, however, the Molex power connector continues to be installed in power supplies, and almost without fail. Almost any modern PSU has at least 1 – 2 of these connectors, and in high-end models this number can be 7 or more. This situation is due to the fact that Molex IDE is a fairly universal standard, and with the help of the simplest adapters, components with a different power interface can be powered from it. For example, there are Molex - SATA adapters for drives, Molex - 6 pin for video cards, etc.
Cable system
The cable system used in the power supply. According to this parameter, modular, semi- modular and non-modular devices are distinguished, here are their features:
— Not modular. The classic version of the design, used in computer power supplies from the very beginning and not losing popularity to this day. The wires in such systems have a non-detachable design, and additional cables are not provided for connection. As a result, the user has to deal with only those cables that the manufacturer provided, without the ability to remove or replace them (the only modifications available are the installation of additional accessories such as an extension cord or splitter). Because of this, such PSUs are less convenient than modular and semi-modular ones: their wires are often excessively long, and some of them are not used at all, while such an “economy” further clutters up the case, worsening air circulation and cooling efficiency. On the other hand, these shortcomings can be reduced to almost zero with careful selection of the PSU and careful wiring; and non-modular systems themselves are distinguished by reliability and at the same time low cost. It is because of these features that they are most common nowadays.
— Modular. Systems in which each cable is made detachable; special sockets are used for fastening wires. Thanks to this design, you can optimally organize the space inside the PC —...for example, remove unnecessary wires so that they do not interfere with air circulation in the system unit; replace a cable that is too long with a shorter wire (or vice versa); swap cables, etc. At the same time, modular systems are noticeably more expensive than non-modular ones, while they are considered somewhat less reliable due to the presence of "weak points" in the form of removable cable mounts.
— Semi-modular. A kind of compromise between the options described above: some of the wires in such power supplies are made non-removable, some are equipped with modular mounts. This makes it possible to partially combine the advantages and compensate for the disadvantages of the two systems: semi-modular PSUs are less expensive and more reliable than modular ones, and at the same time more convenient than non-modular ones. Usually, in systems of this type, the most important wires have a non-removable design, which are almost guaranteed to be used when assembling a PC, and secondary cables are equipped with removable mounts and can be removed if not needed. However, the specific features of a semi-modular PSU should be specified separately.
— Not modular. The classic version of the design, used in computer power supplies from the very beginning and not losing popularity to this day. The wires in such systems have a non-detachable design, and additional cables are not provided for connection. As a result, the user has to deal with only those cables that the manufacturer provided, without the ability to remove or replace them (the only modifications available are the installation of additional accessories such as an extension cord or splitter). Because of this, such PSUs are less convenient than modular and semi-modular ones: their wires are often excessively long, and some of them are not used at all, while such an “economy” further clutters up the case, worsening air circulation and cooling efficiency. On the other hand, these shortcomings can be reduced to almost zero with careful selection of the PSU and careful wiring; and non-modular systems themselves are distinguished by reliability and at the same time low cost. It is because of these features that they are most common nowadays.
— Modular. Systems in which each cable is made detachable; special sockets are used for fastening wires. Thanks to this design, you can optimally organize the space inside the PC —...for example, remove unnecessary wires so that they do not interfere with air circulation in the system unit; replace a cable that is too long with a shorter wire (or vice versa); swap cables, etc. At the same time, modular systems are noticeably more expensive than non-modular ones, while they are considered somewhat less reliable due to the presence of "weak points" in the form of removable cable mounts.
— Semi-modular. A kind of compromise between the options described above: some of the wires in such power supplies are made non-removable, some are equipped with modular mounts. This makes it possible to partially combine the advantages and compensate for the disadvantages of the two systems: semi-modular PSUs are less expensive and more reliable than modular ones, and at the same time more convenient than non-modular ones. Usually, in systems of this type, the most important wires have a non-removable design, which are almost guaranteed to be used when assembling a PC, and secondary cables are equipped with removable mounts and can be removed if not needed. However, the specific features of a semi-modular PSU should be specified separately.
+12V1
The maximum current the PSU can deliver on the first +12V power line.
For more information on power lines in general, see the "+3.3V" section. Here, it is worth mentioning that 12V is the most popular voltage among computer power connectors. It is used in almost all such connectors (with few exceptions), and some plugs (for example, additional PCI-E power with 6 or 8 connectors) use only 12-volt lines — specifically in the +12V format. The division of +12V power into several separate lines is done for safety reasons — to reduce the current going through each individual wire and thus prevent excessive load and overheating of the wiring. However, some manufacturers do not specify the maximum current for individual +12V lines and provide only the overall value in the specifications; in such cases, this number is indicated in this section.
For more information on power lines in general, see the "+3.3V" section. Here, it is worth mentioning that 12V is the most popular voltage among computer power connectors. It is used in almost all such connectors (with few exceptions), and some plugs (for example, additional PCI-E power with 6 or 8 connectors) use only 12-volt lines — specifically in the +12V format. The division of +12V power into several separate lines is done for safety reasons — to reduce the current going through each individual wire and thus prevent excessive load and overheating of the wiring. However, some manufacturers do not specify the maximum current for individual +12V lines and provide only the overall value in the specifications; in such cases, this number is indicated in this section.
Noise level
The noise level produced by the power supply.
Usually, the characteristics indicate the average value of the noise level during normal operation. The lower this value, the quieter the power supply and the more comfortable it is to use. However, it is worth noting that modern computer PSUs produce very little noise. So, in the quietest models, this figure does not exceed 20 dB — this is no louder than the rustling of leaves in a light breeze, such a sound is almost inaudible and is quite acceptable even in a residential area at night. Also acceptable for this application are noise sources of 21 – 25 dB(corresponding to a whisper at a distance of about 1 m) and 26 – 30 dB(wall clock ticking). Noise of more than 30 dB is already considered quite significant for computer PSUs; according to sanitary standards, such equipment in residential premises can only be used during the day.
When choosing a power supply for this indicator, it is worth considering a few points. First, noise reduction comes at a cost: it can affect the cooling performance and/or cost of the device. Secondly, the noise from the power supply is often lost against the background of louder PC components — for example, powerful cooling systems for the CPU or graphics card. Thirdly, the very environment where the PC is installed can be noisy — an example is a...n office or coworking. Thus, specifically looking for a low-noise model makes sense mainly in cases where maximum silence is crucial for you.
Usually, the characteristics indicate the average value of the noise level during normal operation. The lower this value, the quieter the power supply and the more comfortable it is to use. However, it is worth noting that modern computer PSUs produce very little noise. So, in the quietest models, this figure does not exceed 20 dB — this is no louder than the rustling of leaves in a light breeze, such a sound is almost inaudible and is quite acceptable even in a residential area at night. Also acceptable for this application are noise sources of 21 – 25 dB(corresponding to a whisper at a distance of about 1 m) and 26 – 30 dB(wall clock ticking). Noise of more than 30 dB is already considered quite significant for computer PSUs; according to sanitary standards, such equipment in residential premises can only be used during the day.
When choosing a power supply for this indicator, it is worth considering a few points. First, noise reduction comes at a cost: it can affect the cooling performance and/or cost of the device. Secondly, the noise from the power supply is often lost against the background of louder PC components — for example, powerful cooling systems for the CPU or graphics card. Thirdly, the very environment where the PC is installed can be noisy — an example is a...n office or coworking. Thus, specifically looking for a low-noise model makes sense mainly in cases where maximum silence is crucial for you.
Manufacturer's warranty
Manufacturer's warranty provided for this model.
In fact, this is the minimum service life promised by the manufacturer, subject to the rules of operation. There are both models with a small warranty up to 3 years, and more advanced power supplies, in which the warranty can reach 7, 10 years and even 12 years. In general , a 5-year warranty(for example) does not mean that the device will fail after the specified time. Most often, the actual service life of the device is much longer than the guaranteed one.
Specific warranty periods may vary even for similar drives from the same manufacturer. So not
In fact, this is the minimum service life promised by the manufacturer, subject to the rules of operation. There are both models with a small warranty up to 3 years, and more advanced power supplies, in which the warranty can reach 7, 10 years and even 12 years. In general , a 5-year warranty(for example) does not mean that the device will fail after the specified time. Most often, the actual service life of the device is much longer than the guaranteed one.
Specific warranty periods may vary even for similar drives from the same manufacturer. So not








