SilverStone SST-ZU1650R-TM ZEUS 1650R Titanium 80 PLUS User Manual

ZEUS 1350R Titanium

ZEUS 1650R Titanium

ZEUS Series

80 PLUS Titanium 1350W /1650W ATX 3.1 & PCIe 5

Fully Modular ATX Power Supply

Compliant with ATX 3.1 and PCIe Gen 5 standards, supporting 12V-2x6 PCIe connectors

Latest PCIe Gen 5 standard to support up to 2x power excursion

High efficiency with 80 PLUS Titanium certification

24/7 continuous power output with 50ƫ operating temperature

SPECIFICATION

SilverStone ZEUS Series

ZEUS 1350R Titanium / SST-ZU1350R-TM

ZEUS 1650R Titanium / SST-ZU1650R-TM

ATX Switching Power Supply

80 PLUS Titanium efficiency certified.

1350W / 1650W

This document defines the Desktop Power Supply quality, 5 output ,power supplies

for the application of Desktop systems.

This power supplies meet the buss structures of Intel platform, and the following

key features:

1)Input: Full Range (90-264Vrms) with Active Power Factor Correction.

2)Output: Product is provided with a total of 8 output to meet the requirement

of ATX12V/EPS12V platform.

3)Cooling: A 135mm high reliable DC fan is used for cooling the power supply.

The electrical specifications that follow is going to meet over the environmental

ranges specified in Section 3 unless otherwise noted.

Table 1 lists AC input voltage and frequency range for continuous operation.

The power supply is capable of supplying full-rated output power over the input

voltage ranges as specified.

1.Scope

2.Electrical

2.1.AC Input

Parameter Min Nominal Input Max Unit

Voltage

90 100-240 264 Vrms

Frequency

47 50/60 63 Hz

Current 1350W/1650W

18.0 A

Power Factor(PF)

> 0.95

at 230Vac input and full

Table 1. AC input

●When AC Input voltage is lower than 115Vac, 1650W / 1350W total output power

must be reduced to 1250W

●The inrush current is less than 100A under the conditions of 230Vrms input and 25°C

ambient cold start. The inrush current is limited to the extent that no damage will be

done to the power supply under any specified line, load, and temperature conditions.

The inrush current will not cause external protection devices (fuses) to trip.

●The leakage current of the power supply module is less than 3.5mA measured at

230Vac input.

●The repetitive ON/OFF cycling of AC input voltage will not damage the power supply.

●The primary fuse is installed for input over-current protection, and meet product safety

requirement.

The DC output voltages remain within the regulation ranges shown in Table 2.

when measured the at load end of the output connectors under all AC line, O/P loads,

and environmental conditions. The voltage regulation will be maintained under

continuous operation for a period of time equal to the MTBF specified in section

5.2 at any steady

state temperature and operating conditions specified in section 3.

2.2.DC Output

2.2.1. DC Output Voltage Regulations

The power supply efficiency is 90% minimum measured at 10%, efficiency is 92%

minimum & PFC 0.95

measured at 20%, efficiency is 94% (-0.2% Regulation) minimum measured at 50%, ,

efficiency is 90% minimum measured at 100% which is 115Vrms conditions.

The efficiency is measured in accordance with the definition released by the 80 Plus

Organization (Plug Load Solutions).

2.2.2. DC Output Efficiency & Eup* requirements

Outpu

Output

Volta

Minimu

1350W

Max.

(

)

1650W

Max.

(

)

V1 +12V 0.0

112.5 137.5

+5V 0.0

22.0 22.0

V3 +3.3V 0.0

22.0 22.0

V4 -12V 0.0

0.3 0.3

V5 +5Vsb 0.0

3.0 3.0

Total Continuous Power

1350W 1650W

Max. combined O/P of V1

1350W 1650W

Max. combined O/P of V2 & V3

120W 120W

Max. combined O/P of V4

6.0W 6.0W

Max. combined O/P of V5

15W 15W

The Table 3.1 defines the power supply output load

Table 3.1 Power supply output load

In order to meet the 2010 and 2013 ErP Lot 6 requirements, AMS&2014

ErP Lot 3 requirements, and if any Computers use an Alternative Sleep

Mode (ASM) then the 5V standby efficiency should be met as shown in

Table 4 which is measured with the main outputs off (PS_ON# high state).

Table 4. The power supply typical output load distribution

1350W

LOAD +12V +5V +3.3V -12V +5VSB EFF

10% 10.191A 1.31A 1.31A 0.03A 0.296A 90%

20% 20.382A 2.619A 2.619A 0.059A 0.592A 92%

50% 50.956A 6.549A 6.549A 0.148A 1.48A 94%

100% 101.912A 12.973A 12.973A 0.492A 2.950A 90%

1650W

10% 12.657A 1.331A 1.331A 0.049A 0.296A 90%

20% 25.313A 2.662A 2.662A 0.099A 0.592A 92%

50% 63.283A 6.654A 6.654A 0.247A 1.481A 94%

100% 126.527A 13.308A 13.308A 0.494A 2.962A 90%

5VSB Load Target 5VSB Actual Load

Efficiency Target

(both 115V and 230V input)

Remark

45mA ≥45%

ErP* Lot 6 2013

90mA ≥55%

ErP* Lot 6 2010

0.55A ≥75%

ASM and ErP* Lot 3 2014

1.00A ≥75% Recommend

1.50A ≥75%

ASM and ErP* Lot 3 2014

Max / Label 3.0A /Label ≥75% Recommend

The output ripple & noise specifications listed in Table 5. will meet throughout

the load ranges as specified in section 2.2.2 and the nominal line input voltage

conditions as specified in section 2.1. Ripple & noise is defined as periodic of

random signals over a frequency band of 10Hz to 20MHz. Measurements

should be made with an oscilloscope with 20MHz bandwidth. adding a 10uF

electrolytic capacitor and a 0.1uF ceramic capacitor across output terminal during

ripple & noise measurement.

2.2.3. DC Output Ripple & Noise

+12V +5V +3.3V -12V +5Vsb Unit

Max Ripple & Noise 50 50 50 80 50 mV P-P

Table 5. DC Output Ripple & Noise

The output voltages will remain within the regulation limits specified in Table 2.

The load-changing repetition rate is 50Hz to 10KHz, and the transient load slew

rate 1.0A/us. The maximum step load size, and output capacitive loading are

specified as followings in Table 6.

PCI Express* CEM Add-in Card Power Excursion Limits Chart , shown in Figure.1

Figure 1. PCIE* AIC and PSU Power Budget used for Peak Power Excursion

2.2.4. DC Output Transient Response

2.2.5. DC Output Voltage Hold-up Time

2.2.6 PCI-E 5_Power Excursion

+12V +5V +3.3V -12V +5Vsb

Voltage limits.

±3% ±3% ±3% ±8% ±3%

Load Change

Low Load

Min~70%Max Min~30%Max Min~30%Max 0A ~ 0.1A 0A ~ 0.5A

Load Change

High Load

(Max-70%)~Max (Max-30%)~Max (Max-30%)~Max 0.2A ~ 0.3A 2.0A ~ 2.5A

Capacitive Load 6600uF 3300uF 3300uF 330uF 3300uF

Table 6. DC Output Transient Response

The DC output voltages are required to remain within the regulation ranges shown

in Figure.2

●5V and 3.3V voltage rails (ATX Multi-Rail power supplies only) start at 80% of

full load criteria

●DC output voltage will stay within regulation of +5/- 7% during the step load

changes(+12V Capacitive Load 6600uF)

●The 12VHPWR power connector delivers up to 55 A of continuous current to

provide a maximum of 600 W of power to the Add-in Card on a 12 V Aux rail,

are given in figure 3.

Figure 3. PCI Express* CEM Add-in Card Power Excursion Limits Chart

+5Vsb shall have a power on time of 2 Seconds maximum after application of

a valid AC line voltage.

2.3. Timing / Housekeeping / control

Parameter Description Value

Required Recommended for

Non-Alternative Sleep Mode1

Recommended for

Alternative Sleep Mode

T0 AC power on time <2s

T1 Power-on time < 150ms

T2 Rise time 0.2 – 20 ms

T3 PWR_OK delay 100 – 150 ms

T4 PWR_OK rise time < 10 ms

T5 AC loss to PWR_OK

hold-up time

> 16 ms

T6 PWR_OK inactive to

DC loss delay

> 1 ms

2.3.1. PWR_OK (Power Good Signal)

2.3.2. PS_ON (DC Soft Start)

2.3.3. +5Vsb (Standby Voltage Output)

PS_ON# is an active-low, TTL-compatible signal that allows a motherboard to

remotely control the power supply in conjunction with features such as soft on/off,

Wake on LAN*, or wake-on-modem. When PS_ON# is pulled to TTL low,

the power supply should turn on the four main DC output rails: +12 VDC, +5 VDC,

+3.3 VDC, and -12 VDC. When PS_ON# is pulled to TTL high or open-circuited,

the DC output rails should not deliver current and should be held at zero potential

with respect to ground. PS_ON# has no effect on the +5VSB output, which is

always enabled whenever the AC power is present. Table 8 lists PS_ON signal

characteristics.

+5Vsb is a standby voltage output that is active whenever the AC power is present.

It provides a power source for circuits that must remain operational when the four

main DC output rails are in a disabled state. Example uses include soft power

control, Wake on LAN, wake on modem, intrusion detection, or suspend state

activities. There is over current protection on the +5Vsb output to ensure the

power supply will not be damaged if external circuits draw more current than the

supply can provide.

PWR_OK is a “power good” signal. It will be asserted high by the power supply to

indicate that the +5V output is above the under voltage threshold listed in Table 2.

of Section 2.2. PWR_OK will be de-asserted to a low state when +5V output

voltage falls below under voltage threshold, or when AC power has been removed

for a time sufficiently such that power supply operation cannot work normally.

The electrical and timing characteristics of the PWR_OK signal are given in Table 7.

and in figure 1.

Signal type +5V TTL compatible

Logic level low

< 0.4 V while sinking 4 mA

Logic level high

Between 2.4 V and 5 V output while sourcing 200 μA

High-state output impedance

1 kΩ from output to common

Max Ripple/Noise 400 mV p-p

Table 7. PWR_OK Signal Characteristics

Min Max

, Input Low Voltage 0.0V 0.8V

, Input Low Current (Vin = 0.4V) -1.6mA

, Input high Voltage (lin = -200uA) 2.0V

, open circuit, lin =0 -5.25V

Ripple/Noise 400 mV p-p

Table 8. PS_ON Signal Characteristics

2.3.4. Power-on Time

The power-on time is defined as the time from when PS_ON is pulled low to when

the12V1, +5V, and +3.3V output are within the regulation ranges specified in

Section 2.2.1. The power-on time will be less than 150ms (T1 <150 ms). +5Vsb

has a power on time of two second max. after the valid AC Voltages applied.

2.3.5. Rise Time

The output voltage rise from ≤ 10% of nominal to within the regulation ranges

specified in section 2.2.1 within 0.2 ms to 20 ms (0.2 ms ≤ T2 ≤ 20 ms)

2.3.6. Power Sequencing

The +12V1 and +5V output levels are equal to or greater than the +3.3V output at

all times during power-up and normal operation. The time between the +12V1 or

+5V output reaching its minimum in-regulation level and +3.3V reaching its

minimum in-regulation level is ≤ 20 msec.

2.3.7. Overshoot at Turn-on / Turn-off

The output voltage overshoot upon the application or removal of the input voltage,

or the assertion / de-assertion of PS_ON will be less than 10% above the nominal

voltage.

2.3.8. Reset after Shutdown

If the power supply latches into a shutdown state because of a fault condition on

its outputs, the power supply can return to normal operation only after the fault

condition has been removed and the PS_ON has been cycled OFF/ON with a

minimum OFF time of 1 second.

2.3.9. +5Vsb at AC Power-down

2.4. Output Protection

2.4.1. Over Voltage Protection

After AC power is removed, the +5Vsb standby voltage output will remain at its

steady state value for the minimum hold-up time specified in Section 2.2.6 until the

output begins to decrease in voltage. The decrease can be monotonic in nature,

dropping to 0.0V. There are no other perturbations of this voltage at or following

removal of AC power.

The power supply can provide latch-mode over voltage protection as defined in

Table 9.

Output Min. Nom. Max. Unit

+12VDC 13.6 14.6 15.6 Volts

+5VDC 5.5 6.25 7.0 Volts

+3.3VDC 3.7 4.1 4.5 Volts

Table 9. Over Voltage Protection

2.4.2. Under Voltage Protection

The power supply can provide latch-mode Under voltage protection as defined in

Table 10.

2.4.3. Over Current Protection

The power supply can provide Over Current Protection as defined in Table 11.

2.4.4. Short-circuit Protection

The power supply will shut down and latch off for shorting the +12V, +5V, +3.3V,

and -12V rails to return or any other rails. Shorts between main output rails and

+5Vsb will not cause any damage to power supply. +5Vsb can be capable of being

shorted indefinitely, but when the short is removed, the power supply will recover

automatically or by cycling PS_ON. The power supply can be capable of

withstanding a continuous short circuit to the output without damage or overstress

to the unit under the input conditions specified in section 2.1.

2.4.5. Over Power Protection

Fold back at 120%~145% over peak load

2.4.6. OVER TEMPERATURE PROTECTION

Protection temperature is 60℃ to 80℃ at 115V and full load

2.4.7. No-load Operation

No damage or hazardous condition will occur with all the DC output connectors

disconnected from the load. The power supply may latch into the shutdown state.

2.4.8. Isolation (High Voltage Withstand)

1800Vac for 1 minute

Output Min. Nom. Max. Unit

+12VDC 8.80 9.30 9.80 Volts

+5VDC 4.10 4.30 4.47 Volts

+3.3VDC 2.55 2.69 2.83 Volts

Table 10. Under Voltage Protection

Output Min. Max.

+12VDC 120% 145%

+5VDC 120% 150%

+3.3VDC 120% 150%

Table 11. Over Current Protection

3. Environmental

4. Electromagnetic Compatibility

The following subsections define recommended environmental specifications and

test parameters. Based on the typical conditions to which an ATX 12V power

supply may be subjected during operation or shipment.

The following subsections outline applicable product regulatory specifications for

this power supply.

4.1. Emissions (Meet)

The power supply can comply with FCC Part 15 and EN55032: 2015 meeting

Class B for both conducted and radiated emissions with a 3 dB margin.

4.2. Immunity (Meet)

The power supply can comply with EN 55035: 2017.

4.3. CE Testing (Meet)

The following standards are applied during the CE testing

EN 55032: 2015 Class B with 3dB margin minimum

EN 61000-3-2: 2014 Harmonic Current Measurement

EN 61000-3-3: 2013 Voltage Fluctuation and Flick Measurement

EN 55035: 2017, including

IEC 61000-4-2: 2009 ESD – air discharge 8kV / ESD contact discharge 4kV

IEC 61000-4-3: 2010 Radiated, Radio Frequency Electromagnetic Field Immunity Test

IEC 61000-4-4: 2012 Electrical Fast Transient/Burst Immunity Test

IEC 61000-4-5: 2014 Surge Immunity Test – 2kV L/N to PE and 1kV L to N

IEC 61000-4-6: 2014 Immunity to Conducted Disturbances Induced by RF Fields

IEC 61000-4-8: 2010 Power Frequency Magnetic Field Immunity Test

IEC 61000-4-11: 2004 Voltage Dips and Short Interruptions Immunity Test

3.1. Temperature

Operating 0℃ to +50℃

Non-operating -20℃ to +70℃

3.2. Humidity

Operating 20% to 90% relative humidity (non-condensing)

Non-operating 5% to 95% relative humidity (non-condensing)

3.3. Altitude

Operating 0 to 0 to 16,404 ft (5000 meter)

Storage 0 to 50,000 feet

5. Reliability

5.1. Component De-rating

The derating process promotes quality and high reliability. All electronic components are designed with

conservative derating for use in commercial and industrial environments.

5.2. Mean Time between Failures (MTBF)

100K hours minimum at full load 25°C

6.1. Safety

6. Safety (Meet)

cTUVus UL62368-1

TUV EN 62368-1

CB IEC 62368-1

6.2. RoHS & REACH Compliance

7. Mechanical

8. Fan Mode

I: Low Speed mode

II: Semi fanless mode

III: Full Speed High Speed

The power supply meets the requirements of RoHS & REACH Compliance specified as followings:

●European Directive for Waste of electrical and electronic equipment (WEEE) 2012/19/EU

●European Directive for Restriction of the use of certain hazardous substances in electrical and

electronic equipment (RoHS) 2011/65/EU

●ACPEIP, Administration on the Control of Pollution caused by Electronic Information Products (China

RoHS), e.g. SJ/T 11363-2006 Requirements for Concentration Limits for Certain Hazardous Substanc-

es in EIP, SJ/T 11364-2006 Marking for Control of Pollution Caused by EIP

●Plastic and rubber parts are within the limits for 16 PAH and Benzopyrene polycyclic aromatic

hydrocarbons

- PAH (Polycyclic Aromatic Hydrocarbons):

- 200mg/kg for components touched less than 30 seconds

- 10mg/kg for components touched longer than 30 seconds

- Benzopyrene are within the limits of:

- 20mg/kg for components touched less than 30 seconds

- 1mg/kg for components touched longer than 30 seconds

●Phthalate concentration is below 1000mg/kg for:

- Diisononyl phthalate - Diisodecyl phthalate

- Bis(2-ethylhexyl)phthalate - Butyl benzyl phthalate

- Di-n-octyl phthalate - Bis(n-butyl)phthalate

●Polychlorinated biphenyl (PCB) concentration limits are less than two (2) parts per million (ppm).

Regulation (EC) No 1907/2006 ... concerning the Registration, Evaluation, Authorization and Restric-

tion of Chemicals (REACH): No substance of Very High Concern of the “Candidate List” exceeds more

than 0,1 % of the global weight of the delivered item (without packaging of the item)

Dimension W x L x H = 150 x 180 x 86mm.

9.POWER SUPPLY CONNECTOR OVERUSE DEFINITION

Power supply connector overuse definition

A single PCIe 8pin cable and connector’s maximum current rating is

12.5A, which is 150W (+12V x 12.5A). So SilverStone’s warranty will not

cover damages or malfunction resulting from the use of a graphics card

or expansion card with a single PCIe 8pin connector that exceeds

standard 225W total power draw (150W from PCIe 8pin connector +

75W from PCIe motherboard slot). Similarly, a graphics card or

expansion card with dual PCIe 8pin connectors that exceed 375W total

power draw (300W from two PCIe 8pin connectors + 75W from PCIe

motherboard slot) will also not be covered under warranty.

Peripheral (molex) or SATA connector’s maximum current rating is 5A,

which is 60W (+12V x 5A) or 25W (+5V x 5A). Please ensure connected

devices are operating under these limits. SilverStone’s warranty will not

cover damages or malfunction resulting from usages exceeding these

connectors and their associated cables.

24pin motherboard connector’s maximum current rating for its dual

+12V metal pins are 5A each, which totals 120W (+12V x 5A x 2).

Please ensure +12V drawing devices connected to the motherboard are

operating under these limits. SilverStone’s warranty will not cover

damages or malfunction resulting from usages exceeding these

connectors and their associated cables.

Definition einer Überlastung des

Netzanschlusses

Die maximale Stromstärke eines einzelnen 8-poligen PCIe-Kabels und

Anschlusses beträgt 12,5 A, was 150 W (+12 V x 12,5 A) entspricht.

Daher deckt die SilverStone-Garantie keine Schäden oder

Fehlfunktionen durch den Einsatz einer Grafikkarte oder Erweiterung-

skarte mit einem einzigen 8-poligen PCIe-Anschluss ab, die die

Standardleistungsaufnahme von insgesamt 225 W übersteigt (150 W

vom 8-poligen PCIe-Anschluss + 75 W vom PCIe-Motherboard-Steck-

platz). Ebenso wird die Verwendung einer Grafikkarte oder

Erweiterungskarte mit zwei 8-poligen PCIe-Anschlüssen, die eine

Leistungsaufnahme von insgesamt 375 übersteigen (300 W von den

beiden 8-poligen PCIe-Anschlüssen + 75 W vom PCIe-Mother-

board-Steckplatz) nicht durch die Garantie abgedeckt.

Der maximale Nennstrom von Peripherie- (Molex) oder SATA-An-

schluss beträgt 5 A, was 60 W (+12 V x 5 A) oder 25 W (+5 V x 5 A)

entspricht. Bitte achten Sie darauf, dass verbundene Geräte unter

diesen Grenzwerten arbeiten. Die Garantie von SilverStone deckt keine

Schäden oder Fehlfunktionen aufgrund einer Nutzung ab, die diese

Anschlüsse und ihre zugehörigen Kabel übersteigt.

Der maximale Nennstrom des 24-poligen Motherboard-Anschlusses für

seine dualen +12-V-Metallkontakte beträgt jeweils 5 A, was insgesamt

120 W (+12 V x 5 A x 2) ergibt. Bitte stellen Sie sicher, dass mit dem

Motherboard verbundene +12-V-Geräte unter diesen Grenzwerten

arbeiten. SilverStones Garantie deckt keine Schäden oder

Fehlfunktionen aufgrund einer Nutzung jenseits der Angaben dieser

Anschlüsse und ihrer zugehörigen Kabel ab.

Définition de l'utilisation excessive du

connecteur d'alimentation électrique

Le courant nominal maximum d'un périphérique (Molex) ou d'un

connecteur SATA est de 5 A, ce qui correspond à 60 W (+12 V x 5 A)

ou 25 W (+5 V x 5 A). Veuillez vous assurer que les appareils

connectés fonctionnent dans ces limites. La garantie de SilverStone

ne couvre pas les dommages ou les dysfonctionnements résultant

d'utilisations dépassant ces connecteurs et leurs câbles associés.

Le courant nominal maximal des connecteurs 24 broches de la carte

mère pour ses doubles broches métalliques +12 V est de 5 A chacun,

ce qui représente au total 120 W (+12 V x 5 A x 2). Veuillez vous

assurer que les dispositifs de tension +12 V connectés à la carte mère

fonctionnent dans ces limites. La garantie de SilverStone ne couvre

pas les dommages ou les dysfonctionnements résultant d'utilisations

dépassant la capacité de ces connecteurs et de leurs câbles

associés.

Le courant nominal maximum d'un câble et d'un connecteur PCIe 8

broches unique est de 12,5 A, ce qui correspond à 150 W (+12 V x

12,5 A). La garantie de SilverStone ne couvre donc pas les dommages

ou les dysfonctionnements résultant de l'utilisation d'une carte

graphique ou d'une carte d'extension avec un connecteur PCIe 8

broches unique qui dépasse une consommation énergétique totale de

225 W standard (150 W provenant du connecteur PCIe 8 broches + 75

W provenant de l'emplacement de la carte mère PCIe). De même, une

carte graphique ou une carte d'extension avec deux connecteurs PCIe

8 broches qui dépasse une consommation énergétique totale de 375 W

(300 W provenant des deux connecteurs PCIe 8 broches + 75 W

provenant de l'emplacement de la carte mère PCIe) ne sera également

pas couverte dans le cadre de la garantie.

La corrente massima di un singolo cavo PCIe a 8 pin e del connettore

è 12,5 A, corrispondente a 150 W (+12 V x 12,5 A). Pertanto, la

garanzia di SilverStone non copre danni o malfunzionamenti derivanti

dall'utilizzo di una scheda grafica o una scheda di espansione con un

singolo connettore PCIe a 8 pin che supera l'assorbimento totale di

225 W (150 W da connettore PCIe a 8 pin + 75 W da slot PCIe).

Analogamente, la garanzia non copre anche una scheda grafica o

una scheda di espansione con doppi connettori PCIe a 8 pin che

superano l'assorbimento totale di 375 W (300 W da doppi connettori

PCIe a 8 pin + 75 W dalla scheda madre PCIe).

La corrente massima del connettore periferico (molex) o SATA è 5 A,

corrispondente a 60 W (+12 V x 5 A) o 25 W (+5 V x 5 A). Assicurarsi

che i dispositivi collegati funzionino entro questi limiti. La garanzia di

SilverStone non copre danni o malfunzionamenti derivanti da uso

eccessivo di questi connettori e dei relativi cavi.

La corrente massima del connettore a 24 pin per scheda madre per i

suoi due pin di metallo a +12 V è di 5 A ciascuno, per un totale di 120

W (+12 V x 5 A x 2). Assicurarsi che i dispositivi a +12 V collegati alla

scheda madre funzionino con questi limiti. La garanzia di SilverStone

non copre danni o malfunzionamenti derivanti da uso eccessivo di

questi connettori e dei relativi cavi.

Definizione di uso eccessivo del connettore

di alimentazione

La corriente máxima de un solo cable PCIe de 8 pines es 12,5A, lo

que son 150W (+12V x 12,5A). Por tanto, la garantía de SilverStone

no cubrirá daños o fallos provocados por el uso de una tarjeta gráfica

o de expansión con un único conector PCIe de 8 pines que exceda el

total estándar de 225W (150W del conector PCIe de 8 pines + 75W

del zócalo PCIe de la placa base). De igual modo, una tarjeta gráfica

o de expansión con conectores duales PCIe de 8 pines que superen

375W de potencia (300W de los dos conectores PCIe de 8 pines +

75W del zócalo de la placa base) tampoco será cubierta por la

garantía.

La corriente máxima del conector de periféricos (molex) o SATA es

5A, que son 60W (+12V x 5A) o 25W (+5V x 5A). Por favor,

asegúrese de que los dispositivos conectados funcionan dentro de

estos límites. La garantía de SilverStone no cubrirá daños o fallos a

resultas de un uso excesivo de estos conectores y sus cables

asociados.

La corriente máxima del conector de 24 pines de la placa base para

sus pines de metal duales de +12V es de 5A cada uno, para un total

de 120W (+12V x 5A x 2). Por favor, asegúrese de que los

dispositivos de +12V conectados a la placa base funcionan dentro de

estos límites. La garantía de SilverStone no cubrirá daños o averías a

resultas de un uso excesivo para estos conectores y sus cables

asociados.

Definición de uso excesivo del conector de

la Fuente de alimentación

Определение чрезмерной нагрузки на

коннектор блока питания

Один кабель и коннектор PCIe 8pin поддерживает ток 12.5A, что

равно 150Вт (+12В x 12.5A). Таким образом, гарантийные

обязательства SilverStone не будут действовать если вы

используете видеокарту или другую карту расширения с одним

коннектором PCIe 8pin, которые превышает стандартную общую

потребляемую мощность 225Вт (150Вт через коннектор PCIe 8pin +

75Вт через слот PCIe материнской платы). Аналогично, видеокарта

или другая карта расширения с

двумя коннекторами PCIe 8pin,

которые превышают общую потребляемую мощность 375Вт (300Вт

через коннектор PCIe 8pin + 75Вт через слот PCIe материнской

платы), также не будут покрываться гарантией.

Максимальный номинальный ток периферийного (molex) или SATA

разъёма составляет 5A, что равно 60Вт (+12В x 5A) или 25Вт (+5В x

5A). Пожалуйста, убедитесь, что подключенные устройства

работают в этих пределах. Гарантия SilverStone не будет

распространяться на неисправности,

возникающие в результате

использования этих коннекторов или подключаемых к ним кабелей.

Максимальный номинальный ток 24pin коннектора материнской

платы для его двойных металлических контактов +12В составляет

5A на каждый, что равно 120Вт (+12В x 5A x 2). Пожалуйста,

убедитесь, что устройства, подключенные к линии +12В, работают

в этих пределах. Гарантия SilverStone не будет распространяться

на неисправности, возникающие в

результате использования этих

коннекторов или подключаемых к ним кабелей.

전원 공급 커넥터 과용 정의

埮沂穢΁ʹͺΖ穆理決挚愕珪嘫瘶汞牢堆洊幞洛冯汆Ͳ嵢昢

洊崫求嵢筞斶穞彺Έ·ΩͲ沋城埪΄ΚΝΧΖΣ΄ΥΠΟΖ汞

懺溣櫖昢垚祢渆Έ汞爣暒捊洊崫΁ʹͺΖ穆珪嘫瘶汞Έ歆

΁ʹͺΖ彚汾懺姢枲嵵汞Έ汞穯汊爎刂穞垚埮沂΁ʹͺΖ穆珪嘫瘶

痗沲勾岞穃獺姢喞筛沫獺姢庂斲殯穞櫲愢旣穞垚暖旇嬖垚

欪沗壟汊懺旇穞滆橐枻城埪決歆廎焲儆滆嵢Έ汞爣暒捊

洊崫΁ʹͺΖ穆珪嘫瘶儢汞Έ歆΁ʹͺΖ彚汾懺姢枲嵵汞Έ汞

穯汊爎刂穞垚姆櫂΁ʹͺΖ穆珪嘫瘶痗沲勾岞穃獺姢喞筛沫獺姢庂

斲殯空壊懺溣櫖昢懺旇空渂滆橐枻城埪

渂懆沫獞ΞΠΝΖΩ嬖垚΄Ͳ΅Ͳ珪嘫瘶汞牢堆洊幞洛冯汆Ͳ嵢昢

洊崫求嵢筞斶穞彺Έ·ΩͲ嬖垚Έ·ΩͲ沋城埪

櫶冶夢沫獞姪汆決峲穢洢穢穞櫖昢廒沗壟柢琢檂穯城埪΄ΚΝΧΖΣ΄ΥΠΟΖ

汞懺溣櫖昢垚決峲穢珪嘫瘶愕決歆櫶冶夞垚理決挚汞洛冯汊

爎刂穞櫲斲殯穮求嵢桮愢旣穞垚暖旇決喞欪沗壟汊懺旇穞滆

橐枻城埪

姆櫂·匎暓穆櫖斲殯夞垚穆彚汾懺姢珪嘫瘶汞洛冯洊幞垚

Ͳ決彶儇儇穯凊儆Έ·ΩͲΩ沋城埪彚汾懺姢櫖

櫶冶夢·沫獞儆空埿穢凊惾廒求嵢沗壟夞壊嵣穞柳柢欪

΄ΚΝΧΖΣ΄ΥΠΟΖ汆決珪嘫瘶喞分崮理決挚汞穢凊庂爎刂空昢

斲殯穮求嵢桮愢旣穞垚暖旇決喞処沫櫖堆空昢懺沫穞滆橐枻城埪