SILVERSTONE Gemini Series 1300C Platinum Module

Specifications

• Product Name: Gemini Series Gemini 1300C Platinum Module
• Model: SST-GM1300C-PFU
• Power Output: 12.2V main output, 12.2V standby output
• Maximum Output Power: 1300W
• Efficiency Certification: Cybenetics Platinum
• Features: Hot-swappable design, Active PFC, Smart Ride Through (SmaRT), Closed Loop System Protection (CLST)

Product Usage Instructions

General Description
The Gemini 1300C Platinum Module is a CRPS form factor power supply with high efficiency and various protection functions.

Function briefly
GM1300C-PFU an AC/DC power supply with an input voltage range of 90~264Vac, 2 output voltages, main output 12.2V, standby output 12.2V, maximum output power 1300W. The power supply has input over-under voltage, output over-current, output over-voltage, short circuit, over-temperature and other protection functions. At the same time, the power module can control and monitor various functions through the I2C interface.

Model	Output(V)	Input(A)
SST-GM1300C-PFU	12.2V	2-105.3A
	12.2V	0.5-3A

Input requirements

AC input requirements

• Input Voltage Range: 90-264Vac
• Input Surge Current: Up to 310A
• Power Factor: 0.9-0.99

item	measure	Minimum	Nominal	Maximum	note
Input Voltage	Vac	90	115/230	264
Nom Input Voltage	Vac	100	115/230	240
Vin Frequency	Hz	47	50/60	63
Nom Vin Frequency	Vdc	180		310
Nominal DC input voltage range	Vdc		240
Maximum input current	A	/	/	14	@90Vac 100% load
Input surge current	A	/	/	50	230Vac/50Hz input， full load， cold start，25℃
Power factor		0.9			10% load，230Vac,50Hz& 115Vac,60Hz
		0.96			20% load，230Vac,50Hz& 115Vac,60Hz
		0.98			50% load，230Vac,50Hz& 115Vac,60Hz
		0.99			100% load，230Vac,50Hz& 115Vac,60Hz
iTHD	%			20	＞10%&＜20% load，230Vac,50Hz
	%			15	≥20% load，230Vac,50Hz
	%			10	≥40% load，230Vac,50Hz
	%			8	≥50% load，230Vac,50Hz

Input protection function

• Input Overcurrent Protection: Fuse blows when overcurrent occurs

Item	measure	Minimum	Nominal	Maximum	note
Input Over current protection	A	/	/	/	Yes, the input fuse will blow when over current occurs.
Input under voltage protection	Protect point	/	/	82Vac	Full load test, hysteresis more than 5V.
	Recover point	/	/	88Vac
Input over voltage protection	Protect point	290Vac	/	/	Full load test, hysteresis more than 5V.
	Recover point	280Vac	/	/

Output requirements

AC output requirements

• Main Output Voltage: 11.6V – 12.8V
• Standby Output Voltage: 11.6V – 12.8V
• Main Output Current: 2A – 105.3A
• Standby Output Current: 0.5A – 3A

Output power characteristics

Output	Input voltage（Vac）	Mi n(A)	Max(Long-term load)	Peak load capacity（20s）(A)	Peak load capacity（10ms）(A)	Peak load capacity（100us）(A)
Main output	180-264	2	105.3	105.3+10	105.3+72	105.3+105
Main output	90-140	2	80.5	80.5+10	80.5+72	80.5+105
Standby output	90-264	0.5	3	>4

Output protection function

Item		Unit	MIN	Nominal	MAX	Note
Main output Over Current Protection		A	110		145	180-264Vac, hiccup, self-recovery
		A	90		100	90-140Vac, hiccup, self-recovery
Standby		A	4		9	hiccup, self-recovery
Main output short circuit protection		/	/	/	/	Standby output, the main circuit can recover automatically after the short circuit is removed.
Standby output short circuit protection		/				The main circuit has no output, and the Standby can recover automatically after the short circuit is removed.
Over voltage protection	Main	V	13.5		15.5	The output is locked and the Standby output is not turned off.
	Second	V	13.5		15.5	Standby locks, turning off the main output
Over       temperature protection		℃	60			Turn off the main circuit, it can self- recovery, the hysteresis is not less than 5℃, do not turn off the 3.3V Standby.

Indicator

Condition	Light condition	note
The power supply is working normally (both 12V& 12VSB are normal)	GREEN	/
Power supply without AC input (including parallel redundant power supplies)	OFF	/
AC input is normal, 12VSB is normal, and 12Vhas no output.	1Hz Blink GREEN	Standby condition
No AC input, but the AC input of the parallel redundant power supply is normal.	RED	/
Power supply warning, such as over temperature, over power, over current, fan failure, etc.	1Hz Blink RED	Output normally
Power supply protection, such as over -current protection, over -voltage protection, over – temperature protection, fan failure, input over  -and under-voltage protection, etc.	RED	Fail or output protect
Power supply enters cold redundancy state	0.33Hz Blink GREEN	1s OFF；2s GREEN

Note: The light is a two-color LED light

Timing

Item	Description	MI N	MA X	UNITS
T_vout_rise	Output voltage rise time for +12V and +12VSBfrom 10% to within regulation limits.		70	ms
T_vstby_on_delay	Delay from AC being applied to +12VSB being within regulation.		1500	ms
T_vin_on_delay	Delay from AC being applied to all output voltages being within regulation.		2500	ms
T_vout_holdup	Time AC. +12V output voltage stay within regulation after loss of	12		ms
T_psok_holdup	Delay from loss of AC to de-assertion of PSOK.	10		ms
T_ps_on#_off_delay	Delay from PS_ON# de-asserted to power supply turning off.		10	ms
T_ps_on#_on_delay	Delay from PS_ON# active to output voltages within regulation limits.	5	400	ms
T_ps_on#_psok	Delay from PS_ON# deactivate to PSOK being de-asserted.		5	ms
T_psok_on	Delay from output voltages within regulation limits to PSOK asserted at turn on.	100	500	ms
T_psok_off	Delay from PSOK de-asserted to output voltages dropping out of regulation limits.	1		ms
T_psok_low	Duration of PSOK being in the de-asserted state during an off/on cycle using AC or the PS_ON# signal.	100		ms
T_vstby_vout	Delay from +12VSB being in regulation to O/Ps being in regulation at AC turn on.	50	1000	ms
T_vstby_holdup	Time the +12VSB output voltage stays within regulation after loss of AC.	70		ms
Tvingood_de-asserted	Delay from the Vin drop being 0V to VIN_GOODde-assertion. (and SMBAlert# low)		3	ms

Load sharing performance requirements

The redundant backup power supplies actively share current with each other through the current sharing bus, and the current sharing strategy is average current sharing. If one of the redundant backup power supplies fails, the operation and output of other power supplies can’t be affected. Even if the current sharing bus of a single power supply is short-circuit to ground, the power supply output should still meet the specification requirements. When the main circuit load of the power supply is greater than or equal to 50% of the rated power, the current average index should meet 6.5% (max). When the main circuit load of the power supply is 20% and 30% of the rated load, the current sharing unbalance is tested at two points, and it meets the requirement of not exceeding 10%;

Module test

1. Add 120% of the maximum design voltage of the bus to the current-sharing bus and measure the output voltage variation. It is required that this value does not exceed the output voltage regulation accuracy range of the rectifier module.
2. The current sharing requirements are as follows, 12Vsb is no-load during testing.

Turn on test

1. Under all input voltage and output current combinations, the output ripple must not have low-frequency oscillation;
2. Under various cross loads and input voltages, when plugging or unplugging any power supply, the overshoot (including undershoot) on the output DC bus must meet the specification requirements;
3. Dynamically respond to the output voltage under various extreme conditions to meet the system output voltage stabilization accuracy requirements;
4. When starting up under pure resistive load conditions of 0%, 25%, 50%, 75%and 100%, the system output voltage power-on waveform must be smooth;
5. Repeatedly plug and pull modules, and the power system must not cause other modules to die due to plugging and pulling;
6. Switching, plugging and unplugging the power supply must not cause abnormality in the output signal of the relevant power supply;
7. The power module should be able to support up to 4 power supplies in parallel for current sharing;

Cold redundancy requirement

Cold redundancy configuration
There is a register Cold Redundancy configuration (D0h) inside the power supply, which can be read or written accessed by the system. An example of the command format, such as S B0 w D0 01 PEC P means to set the D0h address register value in power supply B0 to 01h. The register value can be set to 00h/01h/02h/03h/04h as needed.

The meanings represented by different values are describe in the following table:

Value	State	Description	Active	Stop
00h	Standard Redundancy	Power load sharing redundant backup operation
01h	Cold Redundant Active	Power supply with normal operating output power in cold backup

02h	Cold Standby 1	The first power supply to exit cold backup and enter working status	40% of max	0.9 x（40% of max x 1/2）=18%
03h	Cold Standby 2	The second power supply exits the cold backup and enters the working state	62% of max	0.9 x（62% of max x 2/3）=37.2%
04h	Cold Standby 3	The third power supply exits the cold backup and enters the working state	84% of max	0.9 x（84% of max x 3/4）=56.7%

Note: The factory default state of the power supply is Standard Redundancy, and the corresponding D0h register value is 00h.

PSU turn on function
The power on and off power supply in cold backup is only controlled by the output load. Once the load exceeds the enable threshold, the power supply is turned on; when the load decreases to the disable threshold, the power supply enters Cold standby.

Cold Standby work condition
The necessary conditions for the power supply to enter the Cold standby state are: PSON low level and the register value is 02h/03h/04h. At the same time, for the power supply that enters the Cold standby state, the requirements are:

• When CRB is low, the power supply in Cold Redundant Active and Cold Standby should be able to wake up immediately and the D0h value returns to 00h, entering the standard redundancy state.
• Keep PWOK high
• All states of the power supply should remain normal, and no faults or abnormalities should be reported unless a fault or abnormality does occur.
• The indicator light flashes according to the specifications.
• All fans remain running
• LED flashes green
• Any time any power supply is abnormal, pull down the CRB level, and all power supplies will automatically enter the Standard Redundancy state. The CRB low level range is 0V-0.6V; the high level range is 2.0V-3.46V, and the timing priority of CRB pulling down must be High to ensure timely wake-up of other Cold Redundant power supplies.
• The cold redundancy power supply must exit the cold backup state under fault or overcurrent conditions
• Any abnormality in the power supply will restore the register value to the default value 00h, and set the Cold Redundant BUS abbreviation CRB (B22 PIN) to low level, forcing other power supplies working in parallel to enter the standard redundancy state.

Trigger conditions:

1. A 12V OCP alarm failure occurs
2. 12V OVP fault
3. 12V UVP
4. OTP alarm failure
5. Fan speed alarm failure
6. AC power failure

Turn on smart opening function
Here are the steps to put your PSU into smart-on mode. PSUs designated as smart standby can be powered off and on to main power when
necessary. For practical applications, the above trigger levels may have a tolerance of +/-10%.

• Step 1: Make sure each PSU has an AC power cord connected. Use the Write Bytes command to set command 0xD0 for each PSU to have its own role (there must be one PSU as the active role). The command format of the smart enable function is as follows.
  B0 is in smart on state (S B0 w D0 01 PEC P)
  B2 is in smart on standby state (S B2 w D0 02 PEC P)
• Step 2: Once the load drops below the corresponding trigger point, the PSU will enter smart slave mode.
• Step 3: If the CRB signal drops low, all PSUs will turn on main power and reset Cold_Redundancy_CONFIG to 0x00. The system needs to reassign the positions of all PSUs to enable the smart on feature again.

PMBUS AND EEPROM

PMBUS
The power supply should support access to PMBUS information via the I2C bus. The power supply is equipped with four pin connectors, namely SCL, SDA, A1, and A0. Clock bus (SCL) and data bus (SDA), the two pins communicate each other and form a continuous bus, A0 and A1 are used to determine the address. The backplane defines the state of these lines so that the power supply address is unique within the system. The generated I2C address should conform to the table below. The write protect pin is used to ensure data is not lost due to accidental overwriting. The bus operates at 3.3V voltage, and SDA and SCL need to be pulled up to 3.3V on the system board.

	MCU Address		System addressing
	PMBUS	IPMI FRU	A1	A0
PSU-1	B0	A0	0	0
PSU-2	B2	A2	0	1
PSU-3	B4	A4	1	0
PSU-4	B6	A6	1	1

The power supply can monitor and read the input voltage, input power, output voltage, output current and other data of the power supply in real time.

CMD Code	Name	Type	Bytes	Conditions
01h	OPERATION	Read/Write	1	Power on/off sign, 0x80means power on (default value), 0x00 means power off
02h	ON_OFF_CONFIG	Read/Write	1	0x15 (hardware controlled power on and off, default value), 0x19 (software controlled power on and off)

03h	CLEAR_FAULTS	N/A	0
19h	CAPABILITY	Read Byte	1	Value 90h
1Ah	QUERY	Block Write-Block Read Process Call	1
20h	VOUT_MODE	Read Byte	1
3Ah	FAN_CONFIG_1_2	R/W	1	D0h
3Bh	FAN_COMMAND_1	R/W	2
79h	STATUS_WORD	Read Word	2
7Ah	STATUS_VOUT	Read Byte	1
7Bh	STATUS_IOUT	Read Byte	1
7Ch	STATUS_INPUT	Read Byte	1
7Dh	STATUS_TEMPERATURE	Read Byte	1
88h	READ_VIN	Read Word	2
8Bh	READ_VOUT	Read Word	2
8Ch	READ_IOUT	Read Word	2
8Dh	READ_TEMPERATURE_1	Read Word	2
96h	READ_POUT	Read Word	2
97h	READ_PIN	Read Word	2
98h	PMBUS_REVISION	Read Byte	1	Value 22h
99h	MFR_ID	Read Block	Variable
9Ah	MFR_MODEL	Read Block	Variable
9Bh	MFR_REVISION	Read Block	Variable
A0h	MFR_VIN_MIN	Read Word	2
A1h	MFR_VIN_MAX	Read Word	2
A2h	MFR_IIN_MAX	Read Word	2
A3h	MFR_PIN_MAX	Read Word	2
A4h	MFR_VOUT_MIN	Read Word	2
A5h	MFR_VOUT_MAX	Read Word	2
A6h	MFR_IOUT_MAX	Read Word	2
A7h	MFR_POUT_MAX	Read Word	2
A8h	MFR_TAMBIENT_MAX	Read Word	2
A9h	MFR_TAMBIENT_MIN	Read Word	2
ABh	MFR_EFFICIENCY_HL	Read Block	14
D0h	Cold standby	R/W	1

EEPROM

EEPROM Data
The EEPROM data format shall comply with the IPMI version 1.0 (document revision 1.3 March 24, 2015) specification.

EEPROM data format

EEPROM Addressing

Item	Address	Byte Value (hex)	Description	Area
0	00H	01	Common Header	Format Version Number
1	01H	00	Internal Use Area
2	02H	00	Chassis Info Area
3	03H	00	Board Info Area
4	04H	01	Product Info Area
5	05H	0C	Multi Record Info Area
6	06H	00	PAD Area
7	07H	F2	Common Header Checksum (Total Of Bytes)
8	08H	01	Product Area Format Version	Product Information Area
9	09H	0B	Product Area Length
10	0AH	19	Language Code
11	0BH	C9	Manufacturer Name type/length byte
12	0CH	46	Manufacturer Name bytes
13	0DH	53	Manufacturer Name bytes
14	0EH	50	Manufacturer Name bytes
15	0FH	20	Manufacturer Name bytes
16	10H	47	Manufacturer Name bytes
17	11H	52	Manufacturer Name bytes
18	12H	4F	Manufacturer Name bytes
19	13H	55	Manufacturer Name bytes
20	14H	50	Manufacturer Name bytes
21	15H	CD	Product Name type/length byte
22	16H	46	Product Name bytes
23	17H	53	Product Name bytes
24	18H	50	Product Name bytes
25	19H	31	Product Name bytes

26	1AH	33	Product Name bytes
27	1BH	30	Product Name bytes
28	1CH	30	Product Name bytes
29	1DH	2D	Product Name bytes
30	1EH	32	Product Name bytes
31	1FH	51	Product Name bytes
32	20H	30	Product Name bytes
33	21H	31	Product Name bytes
34	22H	41	Product Name bytes
35	23H	31	Product Name bytes
36	24H		Product Part/Model Number type/length byte
37	25H		Product Part Number bytes	Need be consistent with SPEC label
38	26H		Product Part Number bytes
39	27H		Product Part Number bytes
40	28H		Product Part Number bytes
41	29H		Product Part Number bytes
42	2AH		Product Part Number bytes
43	2BH		Product Part Number bytes
44	2CH		Product Part Number bytes
45	2DH		Product Part Number bytes
46	2EH		Product Part Number bytes
47	2FH	C2	Product Version type/length byte
48	30H		Product Version	Need be consistent with BOM
49	31H		Product Version
50	32H		Product Serial Number type/length byte
51	33H		Product Serial Number bytes	Need be consistent with SPEC label
52	34H		Product Serial Number bytes
53	35H		Product Serial Number bytes
54	36H		Product Serial Number bytes
55	37H		Product Serial Number bytes
56	38H		Product Serial Number bytes
57	39H		Product Serial Number bytes
58	3AH		Product Serial Number bytes
59	3BH		Product Serial Number bytes
60	3CH		Product Serial Number bytes
61	3DH		Product Serial Number bytes
62	3EH		Product Serial Number bytes
63	3FH	C1	type/length byte encoded to indicate no more info fields
64	40H	00	PAD

65	41H	00	PAD
66	42H	00	PAD
67	43H	00	PAD
68	44H	00	PAD
69	45H	00	PAD
70	46H	00	PAD
71	47H	00	PAD
72	48H	00	PAD
73	49H	00	PAD
74	4AH	00	PAD
75	4BH	00	PAD
76	4CH	00	PAD
77	4DH	00	PAD
78	4EH	00	PAD
79	4FH	00	PAD
80	50H	00	PAD
81	51H	00	PAD
82	52H	00	PAD
83	53H	00	PAD
84	54H	00	PAD
85	55H	00	PAD
86	56H	00	PAD
87	57H	00	PAD
88	58H	00	PAD
89	59H	00	PAD
90	5AH	00	PAD
91	5BH	00	PAD
92	5CH	00	PAD
93	5DH	00	PAD
94	5EH	00	PAD
95	5FH		Product Info Area Checksum	Sum Of Byte8 ~95
96	60H	00	Record Type ID	Power Supply Information
97	61H	02	End of List/Record Format Version
98	62H	18	Record Length
99	63H		Record Checksum (zero checksum)
100	64H		Header Checksum (zero checksum)
101	65H	14	Overall Capacity in Watts (LSB)	1300W
102	66H	05	Overall Capacity in Watts (MSB)
103	67H	FF
104	68H	FF	Peak VA

105	69H	32	Inrush current	50A
106	6AH	05	Inrush interval in ms.	5ms
107	6BH	28	Low end Input voltage range 1 (10mV ,LSB)	90V
108	6CH	23	Low end Input voltage range 1 (10mV ,MSB)
109	6DH	20	High end Input voltage range 1 (10mV ,LSB)	264V
110	6EH	67	High end Input voltage range 1 (10mV ,MSB)
111	6FH	00	Low end Input voltage range 2 (10mV ,LSB)
112	70H	00	Low end Input voltage range 2 (10mV ,MSB)
113	71H	00	High end Input voltage range 2 (10mV ,LSB)
114	72H	00	High end Input voltage range 2 (10mV ,MSB)
115	73H	2F	Low end Input frequency range	47Hz
116	74H	3F	High end Input frequency range	63Hz
117	75H	0C	A/C dropout tolerance in ms(100%Load)	12mS
118	76H	1B	Binary flags
119	77H	48	Peak Wattage(LSB)	1352W，15S
120	78H	F5	Peak Wattage(MSB) – Hold up time in seconds
121	79H	00	Combined Wattage	15S7:4 – Voltage 1；3:0 – Voltage 2
122	7AH	00	Combined Wattage (LSB)
123	7BH	00	Combined Wattage (MSB)
124	7CH	00	Predictive fail tachometer lower threshold (RPS)
125	7DH	09	Record Type ID (0x01: DC Output, 0x09: Extended DC Output)	12V Output Record
126	7EH	02	End of List/Record Format Version
127	7FH	0D	Record Length
128	80H		Record Checksum (zero checksum)
129	81H		Header Checksum (zero checksum)
130	82H	1	Output Information
131	83H	C4	Nominal voltage (10 mV) (LSB)	12.2V
132	84H	04	Nominal voltage (10 mV) (MSB)
133	85H	88	Maximum negative voltage (10 mV) (LSB)	11.6V
134	86H	04	Maximum negative voltage (10 mV) (MSB)
135	87H	00	Maximum positive voltage (10 mV) (LSB)	12.8V
136	88H	05	Maximum positive voltage (10 mV) (MSB)
137	89H	78	Ripple and Noise (1mV) (LSB)	120mV
138	8AH	00	Ripple and Noise (1mV) (MSB)
139	8BH	32	Minimum current draw (10mA) (LSB)	2A

140	8CH	00	Minimum current draw (10mA) (MSB)
141	8DH	22	Maximum current draw (10mA) (LSB)	105.3A
142	8EH	29	Maximum current draw (10mA) (MSB)
143	8FH	09	Record Type ID	12Vsb Output Record
144	90H	82	End of List/Record Format Version
145	91H	0D	Record Length
146	92H		Record Checksum (zero checksum)
147	93H		Header Checksum (zero checksum)
148	94H	82	Output Information
149	95H	C4	Nominal voltage (10 mV) (LSB)	12.2V
150	96H	04	Nominal voltage (10 mV) (MSB)
151	97H	88	Maximum negative voltage (10 mV) (LSB)	11.6V
152	98H	04	Maximum negative voltage (10 mV) (MSB)
153	99H	00	Maximum positive voltage (10 mV) (LSB)	12.8V
154	9AH	05	Maximum positive voltage (10 mV) (MSB)
155	9BH	78	Ripple and Noise (1mV) (LSB)	120mV
156	9CH	00	Ripple and Noise (1mV) (MSB)
157	9DH	00	Minimum current draw (10mA) (LSB)	0.5A
158	9EH	00	Minimum current draw (10mA) (MSB)
159	9FH	2C	Maximum current draw (10mA) (LSB)	3A
160	A0H	01	Maximum current draw (10mA) (MSB)
161	A1H	FF
162	A2H	FF
163	A3H	FF
164	A4H	FF
165	A5H	FF
166	A6H	FF
167	A7H	FF
168	A8H	FF
169	A9H	FF
170	AAH	FF
171	ABH	FF
172	ACH	FF
173	ADH	FF
174	AEH	FF
175	AFH	FF
176	B0H	FF
177	B1H	FF
178	B2H	FF
179	B3H	FF

180	B4H	FF
181	B5H	FF
182	B6H	FF
183	B7H	FF
184	B8H	FF
185	B9H	FF
186	BAH	FF
187	BBH	FF
188	BCH	FF
189	BDH	FF
190	BEH	FF
191	BFH	FF
192	C0H	FF
193	C1H	FF
194	C2H	FF
195	C3H	FF
196	C4H	FF
197	C5H	FF
198	C6H	FF
199	C7H	FF
200	C8H	FF
201	C9H	FF
202	CAH	FF
203	CBH	FF
204	CCH	FF
205	CDH	FF
206	CEH	FF
207	CFH	FF
208	D0H	FF
209	D1H	FF
210	D2H	FF
211	D3H	FF
212	D4H	FF
213	D5H	FF
214	D6H	FF
215	D7H	FF
216	D8H	FF
217	D9H	FF
218	DAH	FF
219	DBH	FF

220	DCH	FF
221	DDH	FF
222	DEH	FF
223	DFH	FF
224	E0H	FF
225	E1H	FF
226	E2H	FF
227	E3H	FF
228	E4H	FF
229	E5H	FF
230	E6H	FF
231	E7H	FF
232	E8H	FF
233	E9H	FF
234	EAH	FF
235	EBH	FF
236	ECH	FF
237	EDH	FF
238	EEH	FF
239	EFH	FF
240	F0H	FF
241	F1H	FF
242	F2H	FF
243	F3H	FF
244	F4H	FF
245	F5H	FF
246	F6H	FF
247	F7H	FF
248	F8H	FF
249	F9H	FF
250	FAH	FF
251	FBH	FF
252	FCH	FF
253	FDH	FF
254	FEH	FF
255	FFH	FF

Environmental and reliability requirements

Environment

Item	Unit	MIN	NORMAL	MAX	Item
Operating temperature	℃	0	25	55	100% load
Storage temperature	℃	-40		85
Storage humidity	%			95	Not turn on the power and on the no condensation.
Altitude	m	0	/	5000	When the power supply works for a long time, the maximum temperature at sea level (the maximum temperature defined in the specification book) decreases by 0.33°C for every 100mincrease in altitude.
Heat dissipation method	The power supply comes with air cooling (exhaust air from the DC terminal side to the AC input side)
Noise	58dB,@33℃,230Vac				Test method refers to ISO7779 bystander sound pressure level noise test

MTBF
When the environment is 35℃ and 100% load, the mean time between failures (MTBF) of the power supply is greater than 200,000 hours.

Test environment requirement

No	Test item	Standard	Note
1	Low Temperature Work)	0℃	24h
2	High Temperature Work)	55℃	24h
3	Low Temperature Storage)	-40℃	24h
4	High Temperature Storage)	85℃	24h
5	Temperature Cycling	-5～55℃	Each cycle is 3 hours, high and low temperature are 1 hour, 380 cycles

Safety requirement

Safety

Standard	Description
IEC 60950-1	‘Information technology equipment – Safety. Part 1: General requirements’, plus all existing national and group differences within the IECEE CB Scheme
GB 4943.1	Safety of Information Technology Equipment (Including Electrical Business Equipment) (standard for China, equivalent to IEC 60950)
IEC 60664-1	Insulation coordination for equipment within low-voltage systems -Part 1:Principles, requirements and tests
IEC62368-1	Audio/video, information and communication technology equipment– Part 1: Safety requirements

Withstand voltage test and leakage current requirements

Test item	Requirement
primary versus secondary	The primary and secondary should be able to withstand 2545Vdc or 1800Vac for 1 minute, leakage current ≤20mA, and no breakdown or arcing.
Insulation resistance	Under normal atmospheric pressure, relative humidity <90%, no condensation, when the test voltage is 500VDC, the insulation resistance between primary and secondary, primary and protective ground and secondary and protective ground is ≥10M
Leakage current	＜3.5mA，264Vac

EMC Requirement

Item	Requirement	Standard	Note
（RE）	Frequency：30MHz～1GHz Class A	EN 55022	230V@50Hz powered
		FCC part 15	120V@60Hz powered
（CE）	Frequency：150KHz～30MHz Class A	EN 55022	230V@50Hz powered
		FCC part 15	120V@60Hz powered
（harmonic）	EN 61000-3-2 class A and Class D requiremnet.	EN 61000-3-2	230V@50Hz powered
（Flicker）	Pst not higher then 1.0； Plt value not over 0.65；The relative voltage change dc does not exceed 3.3%;The maximum relative voltage change dmax does not exceed 4%;The time during which the d(t) value exceeds 3.3% during voltage changes shall not exceed 500ms.	EN 61000-3-3	230V@50Hz powered

Item	Requirement	Category	Standard	Note
SURGE	AC input： Differential mode：±1KV， Common mode：±2KV	B	EN61000-4-5 EN 55024	Basic requirement
EFT	AC input：±2KV	B	EN61000-4-4 EN 55024YD/T 1082
ESD	contact discharge：±6KVair discharge：±8KV	B	EN61000-4-2EN 55024
RS	80M～800MHz 3V/m 800M～960MHz 10V/m 960M～1GHz 3V/m 1.4G～2GHz 10V/m2G～ 2.7GHz 3V/m 80% AM	A	EN 61000-4-3
CS	150KHz～80MHz 3V，80% AM	A	EN 61000-4-6EN 55024

Dimension
73.5mm (W) x 40mm (H) x 185mm (D)

Pin Define

Pin Number	Definition	Pin Number	Definition
A1	GND	B1	GND
A2	GND	B2	GND
A3	GND	B3	GND
A4	GND	B4	GND
A5	GND	B5	GND
A6	GND	B6	GND
A7	GND	B7	GND
A8	GND	B8	GND
A9	GND	B9	GND
A10	+12V	B10	+12V
A11	+12V	B11	+12V
A12	+12V	B12	+12V
A13	+12V	B13	+12V
A14	+12V	B14	+12V
A15	+12V	B15	+12V
A16	+12V	B16	+12V
A17	+12V	B17	+12V
A18	+12V	B18	+12V
A19	SDA	B19	A0
A20	SCL	B20	A1
A21	PSON	B21	+12VSB
A22	SMB_ALERT	B22	CRB
A23	RETURN_SENSE	B23	SHARE
A24	REMOTE_SENSE	B24	PRESENT
A25	PWOK	B25	AC_FAIL

SilverStone Technology Co., Ltd. 
www.silverstonetek.com
support@silverstonetek.com

Frequently Asked Questions

• Q: What is the maximum output power of the Gemini 1300C Platinum Module?
  A: The maximum output power of the module is 1300W.
• Q: Does the module have protection functions for input voltage?
  A: Yes, the module has protection functions for input overcurrent, under voltage, and overvoltage.
• Q: What is the efficiency certification of the Gemini 1300C Platinum Module?
  A: The module is Cybenetics Platinum efficiency certified.

Documents / Resources

SILVERSTONE Gemini Series 1300C Platinum Module [pdf] Owner's Manual Gemini Series, Gemini Series 1300C Platinum Module, 1300C Platinum Module, Platinum Module, Module

References

• User Manual