Q36SR12017NRFA [DELTA]

Delphi Series Q36SR, Quarter Brick 204W DC/DC Power Modules: 18V~75Vin,12V, 17Aout; 德尔福系列Q36SR ， 1/4砖204W DC / DC模块电源： 18V 〜 75Vin ， 12V ， 17Aout


型号：	Q36SR12017NRFA
厂家：	DELTA ELECTRONICS, INC.
描述：	Delphi Series Q36SR, Quarter Brick 204W DC/DC Power Modules: 18V~75Vin,12V, 17Aout 德尔福系列Q36SR ， 1/4砖204W DC / DC模块电源： 18V 〜 75Vin ， 12V ， 17Aout
文件：	总14页 (文件大小：455K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

FEATURES

High efficiency: 93% @ 12V/17A

Size:

58.4x36.8x11.7mm

(2.30”x1.45”x0.46”) w/o heat-spreader

58.4x36.8x12.7mm

(2.30”x1.45”x0.50”) with heat-spreader

Industry standard footprint and pin out

Fixed frequency operation

Input UVLO

OTP and OVP

Output OCP hiccup mode

Output voltage trim down : -10%

Output voltage trim up: +10% at Vin>20V

Monotonic startup into normal and

pre-biased loads

1500V isolation and basic insulation

No minimum load required

No negative current during power or enable

on/off

ISO 9001, TL 9000, ISO 14001, QS 9000,

OHSAS18001 certified manufacturing facility

UL/cUL 60950-1 (US & Canada)

Delphi Series Q36SR, Quarter Brick 204W

DC/DC Power Modules: 18V~75Vin,12V, 17Aout

The Delphi Series Q36SR, Quarter Brick, 18V~75Vin input,

single output, isolated DC/DC converters, are the latest offering from a

world leader in power systems technology and manufacturing ― Delta

Electronics, Inc. With creative design technology and optimization of

component placement, these converters possess outstanding

electrical and thermal performance, as well as extremely high reliability

under highly stressful operating conditions. Typical efficiency of the

12V/17A module is greater than 93%.

OPTIONS

Negative or positive logic remote On/Off

Through hole with heat-spreader

APPLICATIONS

Optical Transport

Data Networking

Communications

Servers

DS_Q36SR12017_12272012

TECHNICAL SPECIFICATIONS

(T_A=25°C, airflow rate=300 LFM, V_in=48Vdc, nominal Vout unless otherwise noted.)

PARAMETER

NOTES and CONDITIONS

Q36SR12017(Standard)

Min.

Typ.

Max.

Units

ABSOLUTE MAXIMUM RATINGS

Input Voltage

Vdc

°C

Continuous

100

Transient (100ms)

100ms

Operating Ambient Temperature

Storage Temperature

-40

-55

125

1500

°C

Input/Output Isolation Voltage

INPUT CHARACTERISTICS

Operating Input Voltage

Vdc

Input Under-Voltage Lockout

Turn-On Voltage Threshold

Turn-Off Voltage Threshold

Lockout Hysteresis Voltage

Maximum Input Current

1.8

Vdc

0.3

100% Load, 18Vin

Vin=48V,Io=0A

Vin=48V

No-Load Input Current

100

A²s

Off Converter Input Current

Inrush Current (I²t)

Input Reflected-Ripple Current

Input Voltage Ripple Rejection

OUTPUT CHARACTERISTICS

Output Voltage Set Point

Output Voltage Regulation

Over Load

P-P thru 12µH inductor, 5Hz to 20MHz

120 Hz

Vin=48V, Io=Io.max, Tc=25°C

11.82

11.64

12.00

12.18

Vdc

Io=Io, min to Io, max

Vin=18V to 75V

±3

±15

Over Line

Over Temperature

Tc=-40°C to 110°C

±120

12.00

Total Output Voltage Range

Output Voltage Ripple and Noise

Peak-to-Peak

Over sample load, line and temperature

5Hz to 20MHz bandwidth

Full Load, 1µF ceramic, 10µF tantalum

Vin=18V to75V

12.36

100

RMS

Operating Output Current Range

Output Over Current Protection(hiccup model)

DYNAMIC CHARACTERISTICS

Output Voltage Current Transient

Positive Step Change in Output Current

Negative Step Change in Output Current

Settling Time (within 1% Vout nominal)

Turn-On Transient

Output Voltage 10% Low

110

140

Vin=48V, 10µF Tan & 1µF Ceramic load cap, 0.1A/µs

75% Io.max to 50% Io.max

400

200

µs

50% Io.max to 75% Io.max

Start-Up Time, From On/Off Control

Start-Up Time, From Input

Output Capacitance (note1)

EFFICIENCY

µF

Full load; 5% overshoot of Vout at startup

5000

1500

100% Load

Vin=24V

Vin=48V

93.5

93.0

92.0

100% Load

60% Load

ISOLATION CHARACTERISTICS

Input to Output

Vdc

MΩ

Isolation Resistance

Isolation Capacitance

1000

260

FEATURE CHARACTERISTICS

Switching Frequency

KHz

ON/OFF Control, Negative Remote On/Off logic

Logic Low (Module On)

Von/off

0.8

Logic High (Module Off)

2.4

ON/OFF Control, Positive Remote On/Off logic

Logic Low (Module Off)

Von/off

0.8

Logic High (Module On)

ON/OFF Current (for both remote on/off logic)

Leakage Current (for both remote on/off logic)

Output Voltage Trim Range(note 2)

Ion/off at Von/off=0.0V

Logic High, Von/off=5V

Pout ≦ max rated power,Io ≦ Io.max

-10

115

140

Pout ≦ max rated power,Io ≦ Io.max

Over full temp range; % of nominal Vout

Output Voltage Remote Sense Range

Output Over-Voltage Protection

GENERAL SPECIFICATIONS

MTBF

Io=80% of Io, max; Ta=25°C, normal input,600FLM

Without heat spreader

3.0

45.5

61.1

135

120

130

M hours

grams

°C

Weight

With heat spreader

Over-Temperature Shutdown ( Without heat spreader)

Refer to Figure 19 for Hot spot 1 location

Refer to Figure 22 for Hot spot 2 location

Refer to Figure 19 for NTC resistor location

Over-Temperature Shutdown

(With heat spreader)

°C

Over-Temperature Shutdown ( NTC resistor )

°C

Note: Please attach thermocouple on NTC resistor to test OTP function, the hot spots’ temperature is just for reference.

Note1: For applications with higher output capacitive load, please contact Delta

Note2: Trim down range -10% for 18Vin ~75Vin, Trim up range +10% for 20Vin ~ 75Vin.

Q36SR12017_12272012

ELECTRICAL CHARACTERISTICS CURVES

Figure 1: Efficiency vs. load current for minimum, nominal, and

maximum input voltage at 25°C

Figure 2: Power dissipation vs. load current for minimum,

nominal, and maximum input voltage at 25°C.

15.5

10.5

5.5

0.5

15 20 25 30 35 40 45 50 55 60

65 70 75

INPUT VOLTAGE(V)

Figure 3: Typical full load input characteristics at room

temperature

Q36SR12017_12272012

ELECTRICAL CHARACTERISTICS CURVES

For Negative Remote On/Off Logic

Figure 4: Turn-on transient at full rated load current (resistive

load) (10 ms/div). Vin=48V. Top Trace: Vout, 3.0V/div; Bottom

Trace: ON/OFF input, 3V/div

Figure 5: Turn-on transient at zero load current (10 ms/div).

Vin=48V. Top Trace: Vout: 3.0V/div, Bottom Trace: ON/OFF

input, 3V/div

Figure 6: Output voltage response to step-change in load

current (50%-75%-50% of Io, max; di/dt = 0.1A/µs; Vin is 24v).

Load cap: 10µF tantalum capacitor and 1µF ceramic capacitor.

Top Trace: Vout (0.5V/div, 500us/div), Bottom Trace:Iout

(5A/div). Scope measurement should be made using a BNC

cable (length shorter than 20 inches). Position the load

between 51 mm to 76 mm (2 inches to 3 inches) from the

module

Figure 7: Output voltage response to step-change in load

current (50%-75%-50% of Io, max; di/dt = 0.1A/µs; Vin is 48v).

Load cap: 10µF tantalum capacitor and 1µF ceramic capacitor.

Top Trace: Vout (0.5V/div, 500us/div), Bottom Trace: Iout

(5A/div). Scope measurement should be made using a BNC

cable (length shorter than 20 inches). Position the load

between 51 mm to 76 mm (2 inches to 3 inches) from the

module

Q36SR12017_12272012

ELECTRICAL CHARACTERISTICS CURVES

Figure 8: Test set-up diagram showing measurement points for

Input Terminal Ripple Current and Input Reflected Ripple

Current.

Figure 9: Input Terminal Ripple Current, i_c, at full rated output

current and nominal input voltage (Vin=48V) with 12µH source

impedance and 33µF electrolytic capacitor (1A/div, 5us/div)

Note: Measured input reflected-ripple current with a simulated

source Inductance (L_TEST) of 12 µH. Capacitor Cs offset

possible battery impedance. Measure current as shown above

Copper Strip

Vo(+)

SCOPE

RESISTIVE

LOAD

10u

Vo(-)

Figure 10: Input reflected ripple current, i_s, through a 12µH

source inductor at nominal input voltage (Vin=48V) and rated

load current (20 mA/div, 5us/div)

Figure 11: Output voltage noise and ripple measurement test

setup

Figure 12: Output voltage ripple at nominal input voltage

(Vin=48V) and rated load current (50 mV/div, 2us/div).Load

capacitance: 1µF ceramic capacitor and 10µF tantalum

capacitor. Bandwidth: 20 MHz. Scope measurements should be

made using a BNC cable (length shorter than 20 inches).

Position the load between 51 mm to 76 mm (2 inches to 3

inches) from the module

Figure 13: Output voltage vs. load current showing typical

current limit curves and converter shutdown points (Vin=48V)

Q36SR12017_12272012

CSA C22.2 NO. 60950-1 2nd and IEC 60950-1 2nd : 2005

and EN 60950-1 2nd: 2006+A11+A1: 2010,if the system in

which the power module is to be used must meet safety

agency requirements.

DESIGN CONSIDERATIONS

Input Source Impedance

The impedance of the input source connecting to the DC/DC

power modules will interact with the modules and affect the

stability. A low ac-impedance input source is recommended.

If the source inductance is more than a few µH, we advise

adding a 100 µF electrolytic capacitor (ESR < 0.7 Ω at 100

kHz) mounted close to the input of the module to improve

the stability.

Basic insulation based on 75 Vdc input is provided between

the input and output of the module for the purpose of

applying insulation requirements when the input to this

DC-to-DC converter is identified as TNV-2 or SELV. An

additional evaluation is needed if the source is other than

TNV-2 or SELV.

When the input source is SELV circuit, the power module

meets SELV (safety extra-low voltage) requirements. If the

input source is a hazardous voltage which is greater than 60

Vdc and less than or equal to 75 Vdc, for the module’s

output to meet SELV requirements, all of the following must

be met:

Layout and EMC Considerations

Delta’s DC/DC power modules are designed to operate in a

wide variety of systems and applications. For design

assistance with EMC compliance and related PWB layout

issues, please contact Delta’s technical support team. An

external input filter module is available for easier EMC

compliance design. Below is the reference design for an

input filter tested with Q36SR12017 to meet class A in

CISSPR 22.

The input source must be insulated from the ac mains

by reinforced or double insulation.

The input terminals of the module are not operator

accessible.

Schematic

A SELV reliability test is conducted on the system

where the module is used, in combination with the

module, to ensure that under a single fault, hazardous

voltage does not appear at the module’s output.

When installed into a Class II equipment (without

grounding), spacing consideration should be given to the

end-use installation, as the spacing between the module

and mounting surface have not been evaluated.

The power module has extra-low voltage (ELV) outputs

when all inputs are ELV.

Test result:

This power module is not internally fused. To achieve

optimum safety and system protection, an input line fuse is

highly recommended. The safety agencies require a

Fast-acting fuse with 50A maximum rating to be installed in

the ungrounded lead. A lower rated fuse can be used

based on the maximum inrush transient energy and

maximum input current.

Soldering and Cleaning Considerations

Post solder cleaning is usually the final board assembly

process before the board or system undergoes electrical

testing. Inadequate cleaning and/or drying may lower the

reliability of a power module and severely affect the finished

circuit board assembly test. Adequate cleaning and/or

drying is especially important for un-encapsulated and/or

open frame type power modules. For assistance on

appropriate soldering and cleaning procedures, please

contact Delta’s technical support team.

25C, 48Vin, full load, Green line is quasi peak mode and

blue line is average mode.

Safety Considerations

The power module must be installed in compliance with the

spacing and separation requirements of the end-user’s

safety agency standard, i.e., UL60950-1,

Q36SR12017_12272012

Remote On/Off

The remote on/off feature on the module can be either

negative or positive logic. Negative logic turns the

module on during a logic low and off during a logic high.

Positive logic turns the modules on during a logic high

and off during a logic low.

Remote on/off can be controlled by an external switch

between the on/off terminal and the Vi(-) terminal. The

switch can be an open collector or open drain.

For negative logic if the remote on/off feature is not

used, please short the on/off pin to Vi(-). For positive

logic if the remote on/off feature is not used, please

leave the on/off pin floating.

Figure 14: Remote on/off implementation

Remote Sense

Remote sense compensates for voltage drops on the

output by sensing the actual output voltage at the point

of load. The voltage between the remote sense pins

and the output terminals must not exceed the output

voltage sense range given here:

[Vo(+) – Vo(–)] – [SENSE(+) – SENSE(–)] ≤ 10% ×

Vout

This limit includes any increase in voltage due to

remote sense compensation and output voltage set

point adjustment (trim).

Figure 15: Effective circuit configuration for remote sense

operation

Q36SR12017_12272012

FEATURES DESCRIPTIONS (CON.)

If the remote sense feature is not used to regulate the output

at the point of load, please connect SENSE(+) to Vo(+) and

SENSE(–) to Vo(–) at the module.

The output voltage can be increased by both the remote

sense and the trim; however, the maximum increase is the

larger of either the remote sense or the trim, not the sum of

both.

When using remote sense and trim, the output voltage

of the module is usually increased, which increases the

power output of the module with the same output

current.

Figure 17: Circuit configuration for trim-up (increase output

voltage)

Care should be taken to ensure that the maximum

output power does not exceed the maximum rated

power.

If the external resistor is connected between the TRIM

and SENSE (+) the output voltage set point increases.

The external resistor value required to obtain a

percentage output voltage change △% is defined as:

Output Voltage Adjustment (TRIM)

To increase or decrease the output voltage set point,

connect an external resistor between the TRIM pin and

the SENSE(+) or SENSE(-). The TRIM pin should be

left open if this feature is not used.

5.11Vo (100 + ∆ ) 511

Rtrim − up =

−

− 10.2

(

KΩ

)

1.225 ∆

∆

Ex. When Trim-up +10% (12V×1.1=13.2V)

5.11×12× (100 +10) 511

Rtrim − up =

−

−10.2 = 489.3

(

KΩ

)

1.225×10

The output voltage can be increased by both the remote

sense and the trim, however the maximum increase is

the larger of either the remote sense or the trim, not the

sum of both.

When using remote sense and trim, the output voltage

of the module is usually increased, which increases the

power output of the module with the same output

current.

Figure 16: Circuit configuration for trim-down (decrease

output voltage)

If the external resistor is connected between the TRIM

and SENSE (-) pins, the output voltage set point

decreases. The external resistor value required to

obtain a percentage of output voltage change △% is

defined as:

Care should be taken to ensure that the maximum

output power of the module remains at or below the

maximum rated power.

511





Rtrim − down =

− 10.2

(

KΩ

)





∆





Ex. When Trim-down -10% (12V×0.9=10.8V)

511





Rtrim − down =

−10.2

(

KΩ

)

= 40.9

(

KΩ

)









Q36SR12017_12272012

THERMAL CONSIDERATIONS

Thermal management is an important part of the system

design. To ensure proper, reliable operation, sufficient

cooling of the power module is needed over the entire

temperature range of the module. Convection cooling is

usually the dominant mode of heat transfer.

Hence, the choice of equipment to characterize the

thermal performance of the power module is a wind

tunnel.

Thermal Testing Setup

Delta’s DC/DC power modules are characterized in

heated vertical wind tunnels that simulate the thermal

environments encountered in most electronics

equipment. This type of equipment commonly uses

vertically mounted circuit cards in cabinet racks in which

the power modules are mounted.

The following figure shows the wind tunnel

characterization setup. The power module is mounted

on a test PWB and is vertically positioned within the

wind tunnel. The space between the neighboring PWB

and the top of the power module is constantly kept at

6.35mm (0.25’’).

PW B

MODULE

FANCING PWB

AIR VELOCITY

AND AMBIENT

TEMPERATURE

SURED BELOW

THE MODULE

AIR FLOW

Note: Wind Tunnel Test Setup Figure Dimensions are in millimeters and (Inches)

Figure 18: Wind tunnel test setup

Thermal Derating

Heat can be removed by increasing airflow over the

module. To enhance system reliability, the power

module should always be operated below the maximum

operating temperature. If the temperature exceeds the

maximum module temperature, reliability of the unit may

be affected.

Q36SR12017_12272012

THERMAL CURVES

(WITH HEAT SPREADER)

(WITHOUT HEAT SPREADER)

AIRFLOW

NTC RESISTOR

AIRFLOW

HOT SPOT 2

HOT SPOT 1

Figure 22: Temperature measurement location.* The allowed

maximum hot spot 2 temperature is defined at 110℃

Figure 19: Temperature measurement location.* The allowed

maximum hot spot1 temperature is defined at 125℃

Q36SR12017(Standard) Output Current vs. Ambient Temperature and Air Velocity

Output Current (A)

@Vin = 24V (Transverse Orientation,With Heatspreader)

@Vin = 24V (Transverse Orientation)

Natural

Convection

Natural

Convection

100LFM

200LFM

300LFM

400LFM

500LFM

600LFM

300LFM

400LFM

500LFM

600LFM

Ambient Temperature (℃)

Figure 23: Output current vs. ambient temperature and air velocity

@Vin=24V(Transverse Orientation, Airflow direction from Vin+ to

Vin-,with heat spreader)

Figure 20: Output current vs. ambient temperature and air

velocity @Vin=24V(Transverse Orientation, Airflow direction

from Vin+ to Vin-,without heat spreader)

Q36SR12017(Standard) Output Current vs. Ambient Temperature and Air Velocity

Output Current (A)

@Vin = 48V (Transverse Orientation,With Heatspreader)

@Vin = 48V (Transverse Orientation)

600LFM

Natural

Convection

Natural

Convection

100LFM

200LFM

300LFM

100LFM

200LFM

400LFM

300LFM

400LFM

500LFM

600LFM

Ambient Temperature (℃)

Figure 24: Output current vs. ambient temperature and air velocity

@Vin=48V(Transverse Orientation, Airflow direction from Vin+ to

Vin-,with heat spreader)

Figure 21: Output current vs. ambient temperature and air

velocity @Vin=48V(Transverse Orientation, Airflow direction

from Vin+ to Vin-,without heat spreader)

Q36SR12017_12272012

MECHANICAL DRAWING (WITH HEAT-SPREADER)

For modules with through-hole pins and the optional heatspreader, they are intended for wave soldering assembly

onto system boards; please do not subject such modules through reflow temperature profile.

Q36SR12017_12272012

MECHANICAL DRAWING (WITHOUT HEAT-SPREADER)

Pin No.

Name

Function

+Vin

Positive input voltage

Remote ON/OFF

ON/OFF

-Vin

Negative input voltage

Negative output voltage

Negative remote sense

Output voltage trim

-Vout

-Sense

Trim

+Sense

+Vout

Positive remote sense

Positive output voltage

Pin Specification:

Pins 1-3,5-7

1.00mm (0.040”) diameter

1.50mm (0.060”) diameter

Pins 4 & 8

Note：All pins are copper alloy with matte tin(Pb free) plated over Ni under-plating.

Q36SR12017_12272012

RECOMMENDED PAD LAYOUT(THROUGH-HOLE MODULE)

Q36SR12017_12272012

PART NUMBERING SYSTEM

Input Number of Product

Series

120

Type of

Product Voltage Outputs

Output

Voltage Current

Output

ON/OFF

Logic

Length/Type

Option Code

Q - 1/4

36 -

S - Single

R - Regular 120 - 12V

17 - 17A

N- Negative

R - 0.170”

A - Standard

Functions

H-with heat spreader

Space - RoHS 5/6

F - RoHS 6/6

(Lead Free)

Brick

18V~75V

P- Positive

N - 0.146”

K - 0.110”

MODEL LIST

MODEL NAME

Q36SR12017NRFA

Q36SR12017NNFA

INPUT

OUTPUT

EFF @ 100% LOAD

93.0% @ 48Vin

18V~75V

15A

12V

17A

93.0% @ 48Vin

Default remote on/off logic is negative and pin length is 0.170”

* For modules with through-hole pins and the optional heatspreader, they are intended for wave soldering assembly

onto system boards; please do not subject such modules through reflow temperature profile.

CONTACT: www.deltaww.com/dcdc

USA:

Telephone:

Asia & the rest of world:

Telephone: +886 3 4526107

Ext 6220~6224

Europe:

Phone: +41 31 998 53 11

Fax: +41 31 998 53 53

Email: DCDC@delta-es.com

East Coast: 978-656-3993

West Coast: 510-668-5100

Fax: (978) 656 3964

Email: DCDC@delta-corp.com

Fax: +886 3 4513485

Email: DCDC@delta.com.tw

WARRANTY

Delta offers a two (2) year limited warranty. Complete warranty information is listed on our web site or is available upon

request from Delta.

Information furnished by Delta is believed to be accurate and reliable. However, no responsibility is assumed by Delta for its

use, nor for any infringements of patents or other rights of third parties, which may result from its use. No license is granted

by implication or otherwise under any patent or patent rights of Delta. Delta reserves the right to revise these specifications

at any time, without notice.

Q36SR12017_12272012

Q36SR12017NRFA [DELTA]

相关型号：

SI9130DB

SI9135LG-T1

SI9135LG-T1-E3

SI9135_11

SI9136_11

SI9130CG-T1-E3

SI9130LG-T1-E3

SI9130_11

SI9137

SI9137DB

SI9137LG

SI9122E