SILVERSTONE DA1000 Gold Decathlon Series Cybenetics Gold 230V 1000W Semi-Modular Instruction Manual

Decathlon Series
DA1000 Gold
Cybenetics Gold 230V 1000W semi-modular ATX PSU
Instruction Manual

DA1000 Gold Decathlon Series Cybenetics Gold 230V 1000W Semi-Modular

• High efficiency with Cybenetics Gold 230V / Silver 115V certification
• Japanese primary capacitor
• Class-leading single +12V rail
• Silent running 140mm fan with 18 dBA
• Semi-modular cables facilitate cable management
• Dual EPS 8-Pin with multiple PCIe 8 / 6-Pin connectors support
• 24/7 continuous power output with 40°C operating temperature

SPECIFICATION

SilverStone Decathlon Series
DA1000 Gold
SST-DA1000-GH
ATX12V Switching Power Supply With Active PFC PS/2

Scope

This document defines the Desktop Power Supply quality, ATX12V size, 5 output 1000W power supplies for the application of Desktop systems.

Electrical

The electrical specifications that follow is going to meet over the environmental ranges specified in Section 3 unless otherwise noted.
2.1.AC Input
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.

Table 1. AC input

• The inrush current is less than 150A 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.

2.2.DC Output
2.2.1. DC Output Voltage Regulations
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.

| +12V| +5V| +3.3V| -12V| +5V5b| Unit
---|---|---|---|---|---|---
Total DC Output Regulation| ±5%| ±5%| ±5%| ±8%| ±5%| Volt
AC Line and DC Load Regulation| ±1%| ±1%| ±1%| ±2.5%| ±2.5%| Volt

Table 2. DC Output Voltage Regulations

• The remote sense is provided to +12V, +5V, and +3.3V outputs to compensate for excessive cable drops.

2.2.2. DC Output Load Distributions
The Table 3. defines the power supply typical output load distribution.

Table 3. DC Output Load Distribution (850W / 1000W)

2.2.3. DC Output Efficiency & Erp* requirements
The power supply efficiency could be suppot
115V in cybenetics silver(Overall Efficiency: ≥85% to <87%) and 230V in cybenetics Gold(Overall Efficiency: ≥89% to <91%)

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).

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

Table 4. The power supply typical output load distribution

2.2.4. DC Output Ripple & Noise
The output ripple & noise specifications listed in Table 6. 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.

| +12V| +5V| +3.3V| -12V| +5Vsb| Unit
---|---|---|---|---|---|---
Max Ripple & Noise| 70| 50| 50| 80| 50| my P-P

Table 6. DC Output Ripple & Noise

2.2.5. DC Output Transient Response
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 0.5A/us. The maximum step load size, and output capacitive loading are specified as followings in Table 7.

| +12V| +5V| +3.3V| -12V| +5Vsb
---|---|---|---|---|---
Voltage limits.| ±5%| ±5%| ±5%| ±10%| ±5%
Load Change Low Load| 0.00%~70%| 0.0%~400/0| 0.0%~40%| OA ~0.1A| OA ~ 0.5A
Load Change High Load| 30%~100%| 60W%~400%| 60%~400%| 0.2A ~ 0.3A| 2.0A ~2.5A
Capacitive Load| 10000uF| 10000uF| 10000uF| 470uF| 10000uF

Table 7. DC Output Transient Response

2.2.6. DC Output Voltage Hold-up Time
The power supply will maintain outputs in regulation per section 2.2.1 despite a loss of input power at the nominal range of AC input and at 80% of maximum continuous output load as applicable for a minimum of 16 msec.
2.3. Timing / Housekeeping / control

Figure 1. Power Supply Timing
Notes: T1 is defined is section 2.3.4
T2 is defined in section 2.3.5
T3, T4, T5 and T6 are defined in Table 6

WR_OK (Power Good Signal)
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 10. and in figure 1.

Table 10. PWR_OK Signal Characteristics

2.3.2. PS_ON (DC Soft Start)
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 low-level (1.5V max.), the power supply will turn on the main DC output rails: +12V, +5V, +3.3V, and –12V. When PS_ON is pulled to high-level (2.4V min.), the DC output rails will not deliver current and will be held at zero potential with respect to ground. PS_ON has no effect to the +5Vsb output, which is always enabled whenever the AC power is present. Table 7 lists PS_ON signal characteristics.

| Min|  Max
---|---|---
VIL, Input Low Voltage| 0.0V| 0.8V
IIL, Input Low Current (Vin = 0.4V)| | -1.6mA
VIH, Input high Voltage (lin = -200uA)| 2.0V|
VIH, open circuit, lin =0| | 5.25V

Table 9. PS_ON Signal Characteristics

2.3.3. +5Vsb (Standby Voltage Output)
+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.
2.3.4. Power-on Time
The power-on time is defined as the time from when PS_ON is pulled low to when the12V, +5V, and +3.3V output are within the regulation ranges specified in Section 2.2.1. The power-on time will be less than 500ms (T1 <500 ms). +5Vsb has a power on time of one 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
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.
2.4. Output Protection
2.4.1. Over Voltage Protection
The power supply can provide latch-mode over voltage protection as defined in Table 10.

Table 10. Over Voltage Protection

2.4.2. Under Voltage Protection
The power supply can provide latch-mode over voltage protection as defined in Table 10.

Table 10. Under Voltage Protection

2.4.3. Over Current Protection
~180% max. for +3.3V and +5V outputs
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%~150% over peak load
2.4.6. OVER TEMPERATURE PROTECTION
Protection temperature is 45 ℃ to 65 ℃ 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

Environmental

The following subsections define recommended environmental specifications and test parameters. Based on the typical conditions to which an ATX12V power supply
may be subjected during operation or shipment.

3.1. Temperature

3.2. Humidity

3.3. Altitude

Electromagnetic Compatibility

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 61000-3-3: 2013
EN 55035: 2017, including| Voltage Fluctuation and Flick Measurement
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

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

Mechanical

Dimension W x L x H = 150x86x160mm

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.

This device complies with Part 15 of the FCC Rules.
Operation is subject to the following two conditions:
(1) this device may not cause harmful interference, and
(2) this device must accept any interference received, including interference that may cause undesired operation.

Model (safety certification):SST-AX1000HCBR-A
The equipment a Class | Switching Power Supply intended to use for information technology equipment or Audio and Video equipment.
Please refer to SilverStone website for latest specifications updates.

SilverStone Technology Co., Ltd.
www.silverstonetek.com
support@silverstonetek.com
NO.G11246340

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