Intel Xeon Processor E3-1200 v2 Product Family and LGA 1155 Socket

Intel Xeon Processor E3-1200 v2 Product Family and LGA 1155 Socket
Intel® Xeon® Processor E3-1200 v2
Product Family and LGA 1155 Socket
Thermal/Mechanical Specifications and Design Guidelines
May 2012
Document Number: 324973-001
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Intel may make changes to specifications and product descriptions at any time, without notice.
This document contains information on products in the design phase of development. The information here is subject to change
without notice. Do not finalize a design with this information.
Designers must not rely on the absence or characteristics of any features or instructions marked “reserved” or “undefined.” Intel
reserves these for future definition and shall have no responsibility whatsoever for conflicts or incompatibilities arising from future
changes to them.
The Intel® Xeon® processor E3-1200 v2 product family and Intel® C200 Series Chipset family may contain design defects or errors
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Performance varies depending on hardware, software and system configuration. For more information, visit
http://www.intel.com/technology/turboboost
Contact your local Intel sales office or your distributor to obtain the latest specifications and before placing your product order.
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Copyright © 2012, Intel Corporation. All Rights Reserved.
2
Thermal/Mechanical Specifications and Design Guidelines
Contents
1
Introduction .............................................................................................................. 9
1.1
References ......................................................................................................... 9
1.2
Definition of Terms ............................................................................................ 10
2
Package Mechanical and Storage Specifications....................................................... 11
2.1
Package Mechanical Specifications ....................................................................... 11
2.1.1 Package Mechanical Drawing.................................................................... 12
2.1.2 Processor Component Keep-Out Zones ...................................................... 12
2.1.3 Package Loading Specifications ................................................................ 13
2.1.4 Package Handling Guidelines.................................................................... 13
2.1.5 Package Insertion Specifications............................................................... 13
2.1.6 Processor Mass Specification .................................................................... 13
2.1.7 Processor Materials................................................................................. 14
2.1.8 Processor Markings................................................................................. 14
2.1.9 Processor Land Coordinates ..................................................................... 15
2.2
Processor Storage Specifications ......................................................................... 16
3
LGA1155 Socket ...................................................................................................... 17
3.1
Board Layout .................................................................................................... 18
3.1.1 Suggested Silkscreen Marking for Socket Identification................................ 20
3.2
Attachment to Motherboard ................................................................................ 20
3.3
Socket Components........................................................................................... 21
3.3.1 Socket Body Housing .............................................................................. 21
3.3.2 Solder Balls ........................................................................................... 21
3.3.3 Contacts ............................................................................................... 21
3.3.4 Pick and Place Cover............................................................................... 21
3.4
Package Installation / Removal ........................................................................... 23
3.4.1 Socket Standoffs and Package Seating Plane.............................................. 23
3.5
Durability ......................................................................................................... 23
3.6
Markings .......................................................................................................... 24
3.7
Component Insertion Forces ............................................................................... 24
3.8
Socket Size ...................................................................................................... 24
4
Independent Loading Mechanism (ILM)................................................................... 25
4.1
Design Concept................................................................................................. 25
4.1.1 ILM Assembly Design Overview ................................................................ 25
4.1.2 ILM Back Plate Design Overview ............................................................... 26
4.1.3 Shoulder Screw and Fasteners Design Overview ......................................... 27
4.2
Assembly of ILM to a Motherboard....................................................................... 28
4.3
ILM Interchangeability ....................................................................................... 29
4.4
Markings .......................................................................................................... 29
4.5
ILM Cover ........................................................................................................ 30
5
LGA1155 Socket and ILM Electrical, Mechanical and Environmental Specifications .. 33
5.1
Component Mass............................................................................................... 33
5.2
Package/Socket Stackup Height .......................................................................... 33
5.3
Loading Specifications........................................................................................ 34
5.4
Electrical Requirements ...................................................................................... 35
5.5
Environmental Requirements .............................................................................. 36
6
Thermal Specifications ............................................................................................ 37
6.1
Thermal Specifications ....................................................................................... 37
6.1.1 Intel® Xeon® Processor E3-1290 v2 (87W) Thermal Profile .......................... 41
6.1.2 Intel® Xeon® Processor E3-1200 v2 Series (77W) Thermal Profile ................ 42
6.1.3 Intel® Xeon® Processor E3-1200 v2 Series (69W) Thermal Profile ................ 44
Thermal/Mechanical Specifications and Design Guidelines
3
Intel® Xeon® Processor E3-1285L v2 (65W) Thermal Profile.........................45
Intel® Xeon® processor E3-1265L v2 (45W) Thermal Profile.........................47
Intel® Xeon® processor E3-1220L v2 (17W) Thermal Profile.........................48
Processor Specification for Operation Where Digital
Thermal Sensor Exceeds TCONTROL ............................................................49
6.1.8 Thermal Metrology ..................................................................................55
Processor Thermal Features ................................................................................56
6.2.1 Processor Temperature............................................................................56
6.2.2 Adaptive Thermal Monitor ........................................................................56
6.2.3 Digital Thermal Sensor ............................................................................58
6.2.4 PROCHOT# Signal ..................................................................................59
6.2.5 THERMTRIP# Signal ................................................................................60
Intel® Turbo Boost Technology ............................................................................60
6.3.1 Intel® Turbo Boost Technology Frequency ..................................................60
6.3.2 Intel® Turbo Boost Technology Graphics Frequency.....................................61
6.3.3 Thermal Considerations ...........................................................................61
6.3.4 Intel® Turbo Boost Technology Power Monitoring ........................................61
6.3.5 Intel® Turbo Boost Technology Power Control.............................................62
6.1.4
6.1.5
6.1.6
6.1.7
6.2
6.3
7
PECI Interface .........................................................................................................65
7.1
Platform Environment Control Interface (PECI) ......................................................65
7.1.1 Introduction ...........................................................................................65
8
Sensor Based Thermal Specification Design Guidance ..............................................67
8.1
Sensor Based Specification Overview (DTS 1.0) .....................................................67
8.2
Sensor Based Thermal Specification .....................................................................68
8.2.1 TTV Thermal Profile.................................................................................68
8.2.2 Specification When DTS value is Greater than TCONTROL ...............................69
8.3
Thermal Solution Design Process .........................................................................69
8.3.1 Boundary Condition Definition ..................................................................69
8.3.2 Thermal Design and Modelling ..................................................................70
8.3.3 Thermal Solution Validation......................................................................70
8.4
Fan Speed Control (FSC) Design Process...............................................................71
8.4.1 DTS 1.1 A New Fan Speed Control Algorithm without TAMBIENT Data ..............71
8.5
System Validation ..............................................................................................73
9
1U Thermal Solution ................................................................................................75
9.1
Performance Targets ..........................................................................................75
9.2
1U Collaboration Heatsink ...................................................................................76
9.2.1 Heatsink Performance .............................................................................76
9.2.2 Thermal Solution ....................................................................................78
9.2.3 Assembly...............................................................................................78
9.3
1U Reference Heatsink .......................................................................................79
9.3.1 Heatsink Performance .............................................................................79
9.3.2 Thermal Solution ....................................................................................80
9.3.3 Assembly...............................................................................................80
9.4
Geometric Envelope for 1U Thermal Mechanical Design ...........................................80
9.5
Thermal Interface Material ..................................................................................81
9.6
Heat Pipe Thermal Consideration .........................................................................81
10
Active Tower Thermal Solution ................................................................................83
10.1 Introduction ......................................................................................................83
10.2 Mechanical Specifications ....................................................................................84
10.2.1 Cooling Solution Dimensions ....................................................................84
10.2.2 Retention Mechanism and Heatsink Attach Clip Assembly .............................85
10.3 Electrical Requirements ......................................................................................85
10.3.1 Active Tower Heatsink Power Supply .........................................................85
10.4 Cooling Requirements ........................................................................................87
4
Thermal/Mechanical Specifications and Design Guidelines
11
Thermal Solution Quality and Reliability Requirements............................................ 89
11.1 Reference Heatsink Thermal Verification ............................................................... 89
11.2 Mechanical Environmental Testing ....................................................................... 89
11.2.1 Recommended Test Sequence.................................................................. 90
11.2.2 Post-Test Pass Criteria ............................................................................ 90
11.2.3 Recommended BIOS/Processor/Memory Test Procedures ............................. 90
11.3 Material and Recycling Requirements ................................................................... 91
A
Component Suppliers............................................................................................... 93
B
Mechanical Drawings ............................................................................................... 95
C
Socket Mechanical Drawings ................................................................................. 115
D
Package Mechanical Drawings ............................................................................... 121
E
LGA 115X Processor Tools ..................................................................................... 125
Figures
2-1
2-2
2-3
2-4
3-1
3-2
3-3
3-4
3-5
3-6
3-7
4-1
4-2
4-3
4-4
4-5
4-6
4-7
5-1
6-1
6-2
6-3
6-4
6-5
6-6
6-7
6-8
6-9
8-1
8-2
Processor Package Assembly Sketch .................................................................... 11
Package View ................................................................................................... 12
Processor Top-Side Markings .............................................................................. 14
Processor Package Lands Coordinates .................................................................. 15
LGA1155 Socket with Pick and Place Cover ........................................................... 17
LGA1155 Socket Contact Numbering (Top View of Socket) ...................................... 18
LGA1155 Socket Land Pattern (Top View of Board) ................................................ 19
Suggested Board Marking ................................................................................... 20
Attachment to Motherboard ................................................................................ 20
Pick and Place Cover.......................................................................................... 22
Package Installation / Removal Features............................................................... 23
ILM Assembly with Installed Processor ................................................................. 26
Back Plate ........................................................................................................ 27
Shoulder Screw................................................................................................. 27
ILM Assembly ................................................................................................... 28
Pin1 and ILM Lever ............................................................................................ 29
ILM Cover ........................................................................................................ 30
ILM Cover and PnP Cover Interference ................................................................. 31
Flow Chart of Knowledge-Based Reliability Evaluation Methodology .......................... 36
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® Processor E3-1290 v2 (87W)........................................................... 41
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® Processor E3-1200 v2 Series (77W) ................................................. 42
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® Processor E3-1200 v2 Series (69W) ................................................. 44
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® Processor E3-1285L v2 (65W) ......................................................... 45
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® processor E3-1265L v2 (45W) ......................................................... 47
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® processor E3-1220L v2 (17W) ......................................................... 48
TTV Case Temperature (TCASE) Measurement Location .......................................... 55
Frequency and Voltage Ordering.......................................................................... 57
Package Power Control....................................................................................... 63
Comparison of Case Temperature versus Sensor Based Specification........................ 68
DTS 1.1 Definition Points.................................................................................... 72
Thermal/Mechanical Specifications and Design Guidelines
5
9-1
9-2
9-3
9-4
9-5
9-6
10-1
10-2
10-3
10-4
10-5
10-6
B-1
B-2
B-3
B-4
B-5
B-6
B-7
B-8
B-9
B-10
B-11
B-12
B-13
B-14
B-15
B-16
B-17
B-18
B-19
C-1
C-2
C-3
C-4
D-1
D-2
E-1
1U Collaboration Heatsink Performance Curves ......................................................76
1U Collaboration Heatsink Performance Curves ......................................................77
1U Collaboration Heatsink Assembly .....................................................................78
1U Reference Heatsink Performance Curves ..........................................................79
KOZ 3-D Model (Top) in 1U Server .......................................................................80
TTV Die Size and Orientation ...............................................................................81
Mechanical Representation of the Solution.............................................................83
Physical Space Requirements for the Solution (Side View) .......................................84
Physical Space Requirements for the Solution (Top View) ........................................85
Fan Power Cable Connector Description ...............................................................86
Baseboard Power Header Placement Relative to Processor Socket.............................86
Active Tower Heatsink Airspace keep-out Requirements (side view)..........................87
Socket / Heatsink / ILM keep-out Zone Primary Side for 1U (Top) ............................96
Socket / Heatsink / ILM keep-out Zone Secondary Side for 1U (Bottom) ...................97
Socket / Processor / ILM keep-out Zone Primary Side for 1U (Top) ...........................98
Socket / Processor / ILM keep-out Zone Secondary Side for 1U (Bottom) ..................99
1U Collaboration Heatsink Assembly ................................................................... 100
1U Collaboration Heatsink ................................................................................. 101
1U Reference Heatsink Assembly ....................................................................... 102
1U Reference Heatsink ..................................................................................... 103
1U Heatsink Screw........................................................................................... 104
Heatsink Compression Spring ............................................................................ 105
Heatsink Load Cup ........................................................................................... 106
Heatsink Retaining Ring.................................................................................... 107
Heatsink Backplate Assembly ............................................................................ 108
Heatsink Backplate .......................................................................................... 109
Heatsink Backplate Insulator ............................................................................. 110
Heatsink Backplate Stud ................................................................................... 111
Thermocouple Attach Drawing ........................................................................... 112
1U ILM Shoulder Screw .................................................................................... 113
1U ILM Standard 6-32 Thread Fastener............................................................... 114
Socket Mechanical Drawing (Sheet 1 of 4)........................................................... 116
Socket Mechanical Drawing (Sheet 2 of 4)........................................................... 117
Socket Mechanical Drawing (Sheet 3 of 4)........................................................... 118
Socket Mechanical Drawing (Sheet 4 of 4)........................................................... 119
Processor Package Drawing (Sheet 1 of 2) .......................................................... 122
Processor Package Drawing (Sheet 2of 2) ........................................................... 123
LGA 115X Processor Tools................................................................................. 125
Tables
1-1
1-2
2-1
2-2
2-3
2-4
5-1
5-2
5-3
5-4
6-1
6
Reference Documents.......................................................................................... 9
Terms and Descriptions ......................................................................................10
Processor Loading Specifications ..........................................................................13
Package Handling Guidelines ...............................................................................13
Processor Materials ............................................................................................14
Storage Conditions.............................................................................................16
Socket Component Mass .....................................................................................33
1155-land Package and LGA1155 Socket Stackup Height ........................................33
Socket & ILM Mechanical Specifications.................................................................34
Electrical Requirements for LGA1155 Socket..........................................................35
Processor Thermal Specifications .........................................................................38
Thermal/Mechanical Specifications and Design Guidelines
6-2
6-3
6-4
6-5
6-6
6-7
6-8
6-9
6-10
6-11
6-12
6-13
6-14
6-15
8-1
9-1
9-2
10-1
11-1
A-1
A-2
A-3
A-4
A-5
B-1
C-1
D-1
E-1
Package Turbo Parameters ................................................................................. 39
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® Processor E3-1290 v2 (87W)........................................................... 41
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® Processor E3-1200 v2 Series (77W) ................................................. 43
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® Processor E3-1200 v2 Series (69W) ................................................. 44
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® Processor E3-1285L v2 (65W) ......................................................... 46
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® processor E3-1265L v2 (45W) ......................................................... 47
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® processor E3-1220L v2 (17W) ......................................................... 48
Thermal Solution Performance above TCONTROL for
Intel® Xeon® Processor E3-1290 v2 (87W)........................................................... 49
Thermal Solution Performance above TCONTROL for
Intel® Xeon® Processor E3-1200 v2 Series (77W) ................................................. 50
Thermal Solution Performance above TCONTROL for
Intel® Xeon® Processor E3-1200 v2 Series (69W) ................................................. 51
Thermal Solution Performance above TCONTROL for
Intel® Xeon® Processor E3-1285L v2 (65W) ......................................................... 52
Thermal Solution Performance above TCONTROL for
Intel® Xeon® processor E3-1265L v2 (45W) ......................................................... 53
Thermal Solution Performance above TCONTROL for
Intel® Xeon® processor E3-1220L v2 (17W) ......................................................... 54
Intel® Turbo Boost Technology Package Power Control Settings............................... 62
DTS 1.1 Thermal Solution Performance above TCONTROL .......................................... 72
Boundary Conditions and Performance Targets ...................................................... 75
Comparison between TTV Thermal Profile and Thermal Solution Performance
for Intel® Xeon® Processor E3-1200 v2 Series (95W) without Intergrated Graphics ... 77
Fan Power and Signal Specifications..................................................................... 86
Use Conditions (Board Level) .............................................................................. 89
Collaboration Heatsink Enabled Components-1U Server .......................................... 93
Reference Heatsink - Workstation ........................................................................ 93
Reference Heatsink Components- Workstation....................................................... 93
LGA1155 Socket and ILM Components ................................................................. 93
Supplier Contact Information .............................................................................. 94
Mechanical Drawing List ..................................................................................... 95
Mechanical Drawing List ................................................................................... 115
Mechanical Drawing List ................................................................................... 121
Tools Ordering Information ............................................................................... 126
Thermal/Mechanical Specifications and Design Guidelines
7
Revision History
Revision
Number
001
Description
•
Initial release of the document.
Date
May 2012
§
8
Thermal/Mechanical Specifications and Design Guidelines
Introduction
1
Introduction
In this document, mechanical and thermal specifications for the processor and the
associated socket are included. The usual design guidance has been retained.
The components described in this document include:
• The thermal and mechanical specifications for the Intel® Xeon® processor E3-1200
v2 product family.
• The LGA1155 socket and the Independent Loading Mechanism (ILM) and back
plate.
• The reference design thermal solution (heatsink) for the processors and associated
retention hardware.
The Intel® Xeon® processor E3-1200 v2 product family has five SKUs in terms of
different power. When required for clarity this document will use as:
• Intel® Xeon® processor E3-1290 v2 (87W)
• Intel® Xeon® processor E3-1200 v2 series (77W)
• Intel® Xeon® processor E3-1200 v2 series (69W)
• Intel® Xeon® processor E3-1285L v2 (65W)
• Intel® Xeon® processor E3-1265L v2 (45W)
• Intel® Xeon® processor E3-1220L v2 (17W)
Note:
When the information is applicable to all products the this document will use
“processor” or “processors” to simplify the document.
1.1
References
Material and concepts available in the following documents may be beneficial when
reading this document.
Table 1-1.
Reference Documents
Title
Document
Location
Intel® Xeon® Processor E3-1200 v2 Product Family Datasheet, Volume 1 of 2
326772
Intel® Xeon® Processor E3-1200 v2 Product Family Datasheet, Volume 2of 2
326773
Intel®
326774
Xeon®
Processor E3-1200 v2 Product Family Specification Update
4-Wire Pulse Width Modulation (PWM) Controlled Fans
Various system thermal design suggestions
Thermal/Mechanical Specifications and Design Guidelines
http://
www.formfactors.
org/
http://
www.formfactors.
org/
9
Introduction
1.2
Definition of Terms
Table 1-2.
Terms and Descriptions
Term
Description
Bypass
Bypass is the area between a passive heatsink and any object that can act to form a duct.
For this example, it can be expressed as a dimension away from the outside dimension of
the fins to the nearest surface.
CTE
Coefficient of Thermal Expansion. The relative rate a material expands during a thermal
event.
DTS
Digital Thermal Sensor reports a relative die temperature as an offset from TCC activation
temperature.
FSC
Fan Speed Control
IHS
Integrated Heat Spreader: a component of the processor package used to enhance the
thermal performance of the package. Component thermal solutions interface with the
processor at the IHS surface.
ILM
Independent Loading Mechanism provides the force needed to seat the 1155-LGA land
package onto the socket contacts.
PCH
Platform Controller Hub. The PCH is connected to the processor via the Direct Media
Interface (DMI) and Intel® Flexible Display Interface (Intel® FDI).
LGA1155 socket
The processor mates with the system board through this surface mount, 1155-land socket.
PECI
The Platform Environment Control Interface (PECI) is a one-wire interface that provides a
communication channel between Intel processor and chipset components to external
monitoring devices.
ΨCA
Case-to-ambient thermal characterization parameter (psi). A measure of thermal solution
performance using total package power. Defined as (TCASE – TLA) / Total Package Power. The
heat source should always be specified for Ψ measurements.
ΨCS
Case-to-sink thermal characterization parameter. A measure of thermal interface material
performance using total package power. Defined as (TCASE – TS) / Total Package Power.
ΨSA
Sink-to-ambient thermal characterization parameter. A measure of heatsink thermal
performance using total package power. Defined as (TS – TLA) / Total Package Power.
TCASE or TC
The case temperature of the processor, measured at the geometric center of the topside of
the TTV IHS.
TCASE_MAX
The maximum case temperature as specified in a component specification.
TCC
Thermal Control Circuit: Thermal monitor uses the TCC to reduce the die temperature by
using clock modulation and/or operating frequency and input voltage adjustment when the
die temperature is very near its operating limits.
TCONTROL
Tcontrol is a static value that is below the TCC activation temperature and used as a trigger
point for fan speed control. When DTS > TCONTROL, the processor must comply to the TTV
thermal profile.
TDP
Thermal Design Power: Thermal solution should be designed to dissipate this target power
level. TDP is not the maximum power that the processor can dissipate.
Thermal
Monitor
A power reduction feature designed to decrease temperature after the processor has
reached its maximum operating temperature.
Thermal Profile
Line that defines case temperature specification of the TTV at a given power level.
TIM
Thermal Interface Material: The thermally conductive compound between the heatsink and
the processor case. This material fills the air gaps and voids, and enhances the transfer of
the heat from the processor case to the heatsink.
TTV
Thermal Test Vehicle. A mechanically equivalent package that contains a resistive heater in
the die to evaluate thermal solutions.
TLA
The measured ambient temperature locally surrounding the processor. The ambient
temperature should be measured just upstream of a passive heatsink or at the fan inlet for
an active heatsink.
TSA
The system ambient air temperature external to a system chassis. This temperature is
usually measured at the chassis air inlets.
§
10
Thermal/Mechanical Specifications and Design Guidelines
Package Mechanical and Storage Specifications
2
Package Mechanical and
Storage Specifications
2.1
Package Mechanical Specifications
The processor is packaged in a Flip-Chip Land Grid Array package that interfaces with
the motherboard via the LGA1155 socket. The package consists of a processor
mounted on a substrate land-carrier. An integrated heat spreader (IHS) is attached to
the package substrate and core and serves as the mating surface for processor thermal
solutions, such as a heatsink. Figure 2-1 shows a sketch of the processor package
components and how they are assembled together. Refer to Chapter 3 and Chapter 4
for complete details on the LGA1155 socket.
The package components shown in Figure 2-1 include the following:
1. Integrated Heat Spreader (IHS)
2. Thermal Interface Material (TIM)
3. Processor core (die)
4. Package substrate
5. Capacitors
Figure 2-1.
Processor Package Assembly Sketch
IHS
Core (die)
TIM
Substrate
Capacitors
LGA1155 Socket
System Board
Note:
1.
Socket and motherboard are included for reference and are not part of processor package.
2.
For clarity the ILM not shown.
Thermal/Mechanical Specifications and Design Guidelines
11
Package Mechanical and Storage Specifications
2.1.1
Package Mechanical Drawing
Figure 2-2 shows the basic package layout and dimensions. The detailed package
mechanical drawings are in Appendix D. The drawings include dimensions necessary to
design a thermal solution for the processor. These dimensions include:
1. Package reference with tolerances (total height, length, width, and so on)
2. IHS parallelism and tilt
3. Land dimensions
4. Top-side and back-side component keep-out dimensions
5. Reference datums
6. All drawing dimensions are in mm.
Package View
37.5
Figure 2-2.
37.5
2.1.2
Processor Component Keep-Out Zones
The processor may contain components on the substrate that define component keepout zone requirements. A thermal and mechanical solution design must not intrude into
the required keep-out zones. Decoupling capacitors are typically mounted to the landside of the package substrate. See Figure D-2 for keep-out zones. The location and
quantity of package capacitors may change due to manufacturing efficiencies but will
remain within the component keep-in. This keep-in zone includes solder paste and is a
post reflow maximum height for the components.
12
Thermal/Mechanical Specifications and Design Guidelines
Package Mechanical and Storage Specifications
2.1.3
Package Loading Specifications
Table 2-1 provides dynamic and static load specifications for the processor package.
These mechanical maximum load limits should not be exceeded during heatsink
assembly, shipping conditions, or standard use condition. Also, any mechanical system
or component testing should not exceed the maximum limits. The processor package
substrate should not be used as a mechanical reference or load-bearing surface for
thermal and mechanical solution.
.
Table 2-1.
Processor Loading Specifications
Parameter
Minimum
Maximum
Notes
Static Compressive Load
—
600 N [135 lbf]
1, 2, 3
Dynamic Compressive Load
—
712 N [160 lbf]
1, 3, 4
Notes:
1.
These specifications apply to uniform compressive loading in a direction normal to the processor IHS.
2.
This is the maximum static force that can be applied by the heatsink and retention solution to maintain the
heatsink and processor interface.
3.
These specifications are based on limited testing for design characterization. Loading limits are for the
package only and do not include the limits of the processor socket.
4.
Dynamic loading is defined as an 50g shock load, 2X Dynamic Acceleration Factor with a 500g maximum
thermal solution.
2.1.4
Package Handling Guidelines
Table 2-2 includes a list of guidelines on package handling in terms of recommended
maximum loading on the processor IHS relative to a fixed substrate. These package
handling loads may be experienced during heatsink removal.
Table 2-2.
Package Handling Guidelines
Parameter
Maximum Recommended
Notes
Shear
311 N [70 lbf]
1, 4
Tensile
111 N [25 lbf]
2, 4
Torque
3.95 N-m [35 lbf-in]
3, 4
Notes:
1.
A shear load is defined as a load applied to the IHS in a direction parallel to the IHS top surface.
2.
A tensile load is defined as a pulling load applied to the IHS in a direction normal to the IHS surface.
3.
A torque load is defined as a twisting load applied to the IHS in an axis of rotation normal to the IHS top
surface.
4.
These guidelines are based on limited testing for design characterization.
2.1.5
Package Insertion Specifications
The processor can be inserted into and removed from an LGA1155 socket 15 times. The
socket should meet the LGA1155 socket requirements detailed in Chapter 5.
2.1.6
Processor Mass Specification
The typical mass of the processor is 21.5g (0.76 oz). This mass [weight] includes all
the components that are included in the package.
Thermal/Mechanical Specifications and Design Guidelines
13
Package Mechanical and Storage Specifications
2.1.7
Processor Materials
Table 2-3 lists some of the package components and associated materials.
Table 2-3.
2.1.8
Processor Materials
Component
Material
Integrated Heat Spreader (IHS)
Nickel Plated Copper
Substrate
Fiber Reinforced Resin
Substrate Lands
Gold Plated Copper
Processor Markings
Figure 2-3 shows the topside markings on the processor. This diagram is to aid in the
identification of the processor.
Figure 2-3.
14
Processor Top-Side Markings
Thermal/Mechanical Specifications and Design Guidelines
Package Mechanical and Storage Specifications
2.1.9
Processor Land Coordinates
Figure 2-4 shows the bottom view of the processor package.
.
Figure 2-4.
AY
AV
AT
AP
AM
AK
AH
AF
AD
AB
Y
V
P
T
M
K
H
F
D
B
Processor Package Lands Coordinates
AW
AU
AR
AN
AL
AJ
AG
AE
AC
AA
W
U
R
N
K
J
G
E
C
A
1
3
2
5
4
7
6
9
8
11 13 15 17 19 21 23 25 27 29 31 33 35 37 39
10 12 14 16 18 20 22 24 26 28 30 32 34 36 38 40
Thermal/Mechanical Specifications and Design Guidelines
15
Package Mechanical and Storage Specifications
2.2
Processor Storage Specifications
Table 2-4 includes a list of the specifications for device storage in terms of maximum
and minimum temperatures and relative humidity. These conditions should not be
exceeded in storage or transportation.
.
Table 2-4.
Storage Conditions
Parameter
Description
Min
Max
Notes
TABSOLUTE STORAGE
The non-operating device storage temperature.
Damage (latent or otherwise) may occur when
subjected to for any length of time.
-55 °C
125 °C
1, 2, 3
TSUSTAINED STORAGE
The ambient storage temperature limit (in
shipping media) for a sustained period of time.
-5 °C
40 °C
4, 5
RHSUSTAINED STORAGE
The maximum device storage relative humidity
for a sustained period of time.
TIMESUSTAINED STORAGE
A prolonged or extended period of time; typically
associated with customer shelf life.
60% @ 24 °C
0
Months
6
Months
5, 6
6
Notes:
1.
Refers to a component device that is not assembled in a board or socket that is not to be electrically
connected to a voltage reference or I/O signals.
2.
Specified temperatures are based on data collected. Exceptions for surface mount reflow are specified in by
applicable JEDEC standard. Non-adherence may affect processor reliability.
3.
TABSOLUTE STORAGE applies to the unassembled component only and does not apply to the shipping media,
moisture barrier bags or desiccant.
4.
Intel branded board products are certified to meet the following temperature and humidity limits that are
given as an example only (Non-Operating Temperature Limit: -40 °C to 70 °C, Humidity: 50% to 90%,
non-condensing with a maximum wet bulb of 28 °C). Post board attach storage temperature limits are not
specified for non-Intel® branded boards.
5.
The JEDEC, J-JSTD-020 moisture level rating and associated handling practices apply to all moisture
sensitive devices removed from the moisture barrier bag.
6.
Nominal temperature and humidity conditions and durations are given and tested within the constraints
imposed by TSUSTAINED STORAGE and customer shelf life in applicable intel box and bags.
§
16
Thermal/Mechanical Specifications and Design Guidelines
LGA1155 Socket
3
LGA1155 Socket
This chapter describes a surface mount, LGA (Land Grid Array) socket intended for the
processors. The socket provides I/O, power and ground contacts. The socket contains
1155 contacts arrayed about a cavity in the center of the socket with lead-free solder
balls for surface mounting on the motherboard.
The contacts are arranged in two opposing L-shaped patterns within the grid array. The
grid array is 40 x 40 with 24 x 16 grid depopulation in the center of the array and
selective depopulation elsewhere.
The socket must be compatible with the package (processor) and the Independent
Loading Mechanism (ILM). The ILM design includes a back plate which is integral to
having a uniform load on the socket solder joints. Socket loading specifications are
listed in Chapter 5.
Figure 3-1.
LGA1155 Socket with Pick and Place Cover
Thermal/Mechanical Specifications and Design Guidelines
17
LGA1155 Socket
Figure 3-2.
LGA1155 Socket Contact Numbering (Top View of Socket)
39
37
35
33
31
29
30
28
26
24
22
20
18
16
14
12
10
8
6
4
2
27
29
25
27
25
23
23
21
19
21
17
19
17
15
15
13
13
11
38
36
34
32
30
28
26
24
22
20
18
16
14
12
11
9
7
5
3
1
A
C
B
3.1
40
E
D
G
F
J
H
L
K
N
M
R
P
T
U W AA AC AE AG AJ AL AN AR AU AW
V Y AB AD AF AH AK AM AP AT AV AY
Board Layout
The land pattern for the LGA1155 socket is 36 mils X 36 mils (X by Y) within each of the
two L-shaped sections. There is no round-off (conversion) error between socket pitch
(0.9144 mm) and board pitch (36 mil) as these values are equivalent. The two Lsections are offset by 0.9144 mm (36 mil) in the x direction and 3.114 mm (122.6 mil)
in the y direction see Figure 3-3. This was to achieve a common package land to PCB
land offset which ensures a single PCB layout for socket designs from the multiple
vendors.
18
Thermal/Mechanical Specifications and Design Guidelines
LGA1155 Socket
Figure 3-3.
LGA1155 Socket Land Pattern (Top View of Board)
A
C
B
E
D
G
F
J
H
L
K
N
M
R
P
U
T
W AA AC AE AG AJ AL AN AR AU AW
V
Y
AB AD AF AH AK AM AP AT AV AY
40
39
37
35
33
31
36mil (0.9144 mm)
29
27
30
28
26
24
22
20
18
16
14
12
10
8
6
4
2
29
25
27
23
25
21
23
19
21
17
19
15
17
13
15
38
36
34
32
30
28
26
24
22
20
18
16
14
12
11
13
122.6 mil (3.1144mm)
11
9
7
5
3
1
A
C
B
E
D
G
F
J
H
L
K
N
M
Thermal/Mechanical Specifications and Design Guidelines
R
P
U
T
W AA AC AE AG AJ AL AN AR AU AW
V
Y
AB AD AF AH AK AM AP AT AV AY
19
LGA1155 Socket
3.1.1
Suggested Silkscreen Marking for Socket Identification
Intel is recommending that customers mark the socket name approximately where
shown in Figure 3-4.
Figure 3-4.
Suggested Board Marking
3.2
Attachment to Motherboard
The socket is attached to the motherboard by 1155 solder balls. There are no additional
external methods (i.e. screw, extra solder, adhesive, and so on) to attach the socket.
As indicated in Figure 3-1, the Independent Loading Mechanism (ILM) is not present
during the attach (reflow) process.
Figure 3-5.
Attachment to Motherboard
Load plate
Frame
Load Lever
Shoulder
Screw
Back Plate
20
Thermal/Mechanical Specifications and Design Guidelines
LGA1155 Socket
3.3
Socket Components
The socket has two main components, the socket body and Pick and Place (PnP) cover,
and is delivered as a single integral assembly. Refer to Appendix C for detailed
drawings.
3.3.1
Socket Body Housing
The housing material is thermoplastic or equivalent with UL 94 V-0 flame rating capable
of withstanding 260°C for 40 seconds. Which is compatible with typical reflow/rework
profiles. The socket coefficient of thermal expansion (in the XY plane), and creep
properties, must be such that the integrity of the socket is maintained for the
conditions listed in Chapter 5.
The color of the housing will be dark as compared to the solder balls to provide the
contrast needed for pick and place vision systems.
3.3.2
Solder Balls
A total of 1155 solder balls corresponding to the contacts are on the bottom of the
socket for surface mounting with the motherboard. The socket solder ball has the
following characteristics:
• Lead free SAC (SnAgCu) 305 solder alloy with a silver (Ag) content between 3%
and 4% and a melting temperature of approximately 217 °C. The alloy is
compatible with immersion silver (ImAg) and Organic Solderability Protectant
(OSP) motherboard surface finishes and a SAC alloy solder paste.
• Solder ball diameter 0.6 mm ± 0.02 mm, before attaching to the socket lead.
The co-planarity (profile) and true position requirements are defined in Appendix C.
3.3.3
Contacts
Base material for the contacts is high strength copper alloy.
For the area on socket contacts where processor lands will mate, there is a 0.381 μm
[15 μinches] minimum gold plating over 1.27 μm [50 μinches] minimum nickel
underplate.
No contamination by solder in the contact area is allowed during solder reflow.
3.3.4
Pick and Place Cover
The cover provides a planar surface for vacuum pick up used to place components in
the Surface Mount Technology (SMT) manufacturing line. The cover remains on the
socket during reflow to help prevent contamination during reflow. The cover can
withstand 260 °C for 40 seconds (typical reflow/rework profile) and the conditions
listed in Chapter 5 without degrading.
As indicated in Figure 3-6, the cover remains on the socket during ILM installation, and
should remain on whenever possible to help prevent damage to the socket contacts.
Thermal/Mechanical Specifications and Design Guidelines
21
LGA1155 Socket
Cover retention must be sufficient to support the socket weight during lifting,
translation, and placement (board manufacturing), and during board and system
shipping and handling. PnP Cover should only be removed with tools, to prevent the
cover from falling into the contacts.
The socket vendors have a common interface on the socket body where the PnP cover
attaches to the socket body. This should allow the PnP covers to be compatible between
socket suppliers.
As indicated in Figure 3-6, a Pin1 indicator on the cover provides a visual reference for
proper orientation with the socket.
Figure 3-6.
Pick and Place Cover
Pin 1
Pick & Place Cover
22
ILM Installation
Thermal/Mechanical Specifications and Design Guidelines
LGA1155 Socket
3.4
Package Installation / Removal
As indicated in Figure 3-7, access is provided to facilitate manual installation and
removal of the package.
To assist in package orientation and alignment with the socket:
• The package Pin1 triangle and the socket Pin1 chamfer provide visual reference for
proper orientation.
• The package substrate has orientation notches along two opposing edges of the
package, offset from the centerline. The socket has two corresponding orientation
posts to physically prevent mis-orientation of the package. These orientation
features also provide initial rough alignment of package to socket.
• The socket has alignment walls at the four corners to provide final alignment of the
package.
.
Figure 3-7.
Package Installation / Removal Features
Package
Pin 1
Indicator
Orientation
Notch
(2 Places)
Alignment
Post
(2 Places)
3.4.1
Finger/Tool
Access
(2 Places)
Pin 1
Chamfer
Socket Standoffs and Package Seating Plane
Standoffs on the bottom of the socket base establish the minimum socket height after
solder reflow and are specified in Appendix C.
Similarly, a seating plane on the topside of the socket establishes the minimum
package height. See Section 5.2 for the calculated IHS height above the motherboard.
3.5
Durability
The socket must withstand 20 cycles of processor insertion and removal. The max
chain contact resistance from Table 5-4 must be met when mated in the 1st and 20th
cycles.
The socket Pick and Place cover must withstand 15 cycles of insertion and removal.
Thermal/Mechanical Specifications and Design Guidelines
23
LGA1155 Socket
3.6
Markings
There are three markings on the socket:
• LGA1155: Font type is Helvetica Bold - minimum 6 point (2.125 mm). This mark
will also appear on the pick and place cap.
• Manufacturer's insignia (font size at supplier's discretion).
• Lot identification code (allows traceability of manufacturing date and location).
All markings must withstand 260°C for 40 seconds (typical reflow/rework profile)
without degrading, and must be visible after the socket is mounted on the
motherboard.
LGA1155 and the manufacturer's insignia are molded or laser marked on the side wall.
3.7
Component Insertion Forces
Any actuation must meet or exceed SEMI S8-95 Safety Guidelines for Ergonomics/
Human Factors Engineering of Semiconductor Manufacturing Equipment, example Table
R2-7 (Maximum Grip Forces). The socket must be designed so that it requires no force
to insert the package into the socket.
3.8
Socket Size
Socket information needed for motherboard design is given in Appendix C.
This information should be used in conjunction with the reference motherboard keepout drawings provided in Appendix B to ensure compatibility with the reference thermal
mechanical components.
§
24
Thermal/Mechanical Specifications and Design Guidelines
Independent Loading Mechanism (ILM)
4
Independent Loading
Mechanism (ILM)
The ILM has two critical functions – deliver the force to seat the processor onto the
socket contacts and distribute the resulting compressive load evenly through the socket
solder joints.
The mechanical design of the ILM is integral to the overall functionality of the LGA1155
socket. Intel performs detailed studies on integration of processor package, socket and
ILM as a system. These studies directly impact the design of the ILM. The Intel
reference ILM will be “build to print” from Intel controlled drawings. Intel recommends
using the Intel Reference ILM. Custom non-Intel ILM designs do not benefit from Intel's
detailed studies and may not incorporate critical design parameters.
Note:
There is a single ILM design for the LGA1155 socket and LGA1156 socket.
4.1
Design Concept
The ILM consists of two assemblies that will be procured as a set from the enabled
vendors. These two components are ILM assembly and back plate. To secure the two
assemblies, two types of fasteners are required a pair (2) of standard 6-32 thread
screws and a custom 6-32 thread shoulder screw. The reference design incorporates a
T-20 Torx head fastener. The Torx head fastener was chosen to ensure end users do not
inadvertently remove the ILM assembly and for consistency with the LGA1366 socket
ILM. The Torx head fastener is also less susceptible to driver slippage. Once assembled
the ILM is not required to be removed to install / remove the motherboard from a
chassis.
4.1.1
ILM Assembly Design Overview
The ILM assembly consists of 4 major pieces – ILM cover, load lever, load plate, and the
hinge frame assembly.
All of the pieces in the ILM assembly except the hinge frame and the screws used to
attach the back plate are fabricated from stainless steel. The hinge frame is plated. The
frame provides the hinge locations for the load lever and load plate. An insulator is preapplied to the bottom surface of the hinge frame.
Figure B-1 through Figure B-4 list the applicable keep-out zones of the socket and ILM.
Figure B-1 describes recommended maximum heights of neighboring components on
the primary side of the board to avoid interference with the Intel reference thermal
solution. The keep-out zone in Figure B-1 does not prevent incidental contact with the
ILM load plate and ILM cover while it is open for insertion/removal of the processor. In
designs requiring no cosmetic marks to be made on capacitors along the hinge side of
the ILM, the recommendation is for the location of the capacitors to be against the
keep-out zone boundary closest to the hinge of the ILM. This location does not prevent
contact between the ILM and the capacitors, however it minimizes the load applied by
the ILM to the capacitors.
Thermal/Mechanical Specifications and Design Guidelines
25
Independent Loading Mechanism (ILM)
The ILM assembly design ensures that once assembled to the back plate the only
features touching the board are the shoulder screw and the insulated hinge frame
assembly. The nominal gap of the load plate to the board is ~1 mm.
When closed the load plate applies two point loads onto the IHS at the “dimpled”
features shown in Figure 4-1. The reaction force from closing the load plate is
transmitted to the hinge frame assembly and through the fasteners to the back plate.
Some of the load is passed through the socket body to the board inducing a slight
compression on the solder joints.
A pin 1 indicator will be marked on the ILM assembly.
Figure 4-1.
ILM Assembly with Installed Processor
Hinge /
Frame
Assy
Fasteners
Load
Lever
Load
Plate
Pin 1 Indicator
Shoulder Screw
4.1.2
ILM Back Plate Design Overview
The back plate is a flat steel back plate with pierced and extruded features for ILM
attach. A clearance hole is located at the center of the plate to allow access to test
points and backside capacitors if required. An insulator is pre-applied. A notch is placed
in one corner to assist in orienting the back plate during assembly.
Caution:
Intel does NOT recommend using the server back plate for high-volume desktop
applications at this time as the server back plate test conditions cover a limited
envelope. Back plates and screws are similar in appearance. To prevent mixing,
different levels of differentiation between server and desktop back plate and screws
have been implemented.
For ILM back plate, three levels of differentiation have been implemented:
• Unique part numbers, please refer to part numbers listed in Appendix A.
• Desktop ILM back plate to use black lettering for marking versus server ILM back
plate to use yellow lettering for marking.
• Desktop ILM back plate using marking “115XDBP” versus server ILM back plate
using marking “115XSBP”.
Note:
26
When reworking a BGA component or the socket that the heatsink, battery, ILM and
ILM Back Plate are removed prior to rework. The ILM back plate should also be
removed when reworking through hole mounted components in a mini-wave or solder
pot). The maximum temperature for the pre-applied insulator on the ILM is
approximately 106 °C.
Thermal/Mechanical Specifications and Design Guidelines
Independent Loading Mechanism (ILM)
Figure 4-2.
Back Plate
Die Cut
Insulator
Assembly
Orientation
Feature
Pierced & Extruded
Thread Features
4.1.3
Shoulder Screw and Fasteners Design Overview
The shoulder screw is fabricated from carbonized steel rod. The shoulder height and
diameter are integral to the mechanical performance of the ILM. The diameter provides
alignment of the load plate. The height of the shoulder ensures the proper loading of
the IHS to seat the processor on the socket contacts. The design assumes the shoulder
screw has a minimum yield strength of 235 MPa.
A dimensioned drawing of the shoulder screw is available for local sourcing of this
component. Refer to Figure B-18 for the custom 6-32 thread shoulder screw drawing.
The standard fasteners can be sourced locally. The design assumes this fastener has a
minimum yield strength of 235 MPa. Refer to Figure B-19 for the standard 6-32 thread
fasteners drawing.
Note:
The screws for Server ILM are different from Desktop design. The length of Server ILM
screws are shorter than the Desktop screw length to satisfy Server secondary-side
clearance limitation. Server ILM back plate to use black nickel plated screws, whereas
desktop ILM back plate to use clear plated screws. Unique part numbers, refer to
Appendix A.
Note:
The reference design incorporates a T-20 Torx head fastener. The Torx head fastener
was chosen to ensure end users do not inadvertently remove the ILM assembly and for
consistency with the LGA1366 socket ILM.
Figure 4-3.
Shoulder Screw
Cap
6-32 thread
Shoulder
Thermal/Mechanical Specifications and Design Guidelines
27
Independent Loading Mechanism (ILM)
4.2
Assembly of ILM to a Motherboard
The ILM design allows a bottoms up assembly of the components to the board. See
Figure 4-4 for step by step assembly sequence.
1. Place the back plate in a fixture. The motherboard is aligned with the fixture.
2. Install the shoulder screw in the single hole near Pin 1 of the socket. Torque to a
minimum and recommended 8 inch-pounds, but not to exceed 10 inch-pounds.
3. Align and place the ILM assembly over the socket.
4. Install two (2) 6-32 fasteners. Torque to a minimum and recommended 8 inchpounds, but not to exceed 10 inch-pounds.
The thread length of the shoulder screw accommodates a nominal board thicknesses of
0.062”.
.
Figure 4-4.
ILM Assembly
Step 1
Step 3
Step 2
Step 4
As indicated in Figure 4-5, the shoulder screw, socket protrusion and ILM key features
prevent 180 degree rotation of ILM cover assembly with respect to socket. The result is
a specific Pin 1 orientation with respect to ILM lever.
28
Thermal/Mechanical Specifications and Design Guidelines
Independent Loading Mechanism (ILM)
Figure 4-5.
Pin1 and ILM Lever
Alignment
Features
Pin 1
Shoulder
Screw
Load
Lever
4.3
Load plate not
shown for
clarity
ILM Interchangeability
ILM assembly and ILM back plate built from the Intel controlled drawings are intended
to be interchangeable. Interchangeability is defined as an ILM from Vendor A will
demonstrate acceptable manufacturability and reliability with a socket body from
Vendor A, B, or C. ILM assembly and ILM back plate from all vendors are also
interchangeable.
The ILM are an integral part of the socket validation testing. ILMs from each vendor will
be matrix tested with the socket bodies from each of the current vendors. The tests
would include: manufacturability, bake and thermal cycling.
See Appendix A for vendor part numbers that were tested.
Note:
ILMs that are not compliant to the Intel controlled ILM drawings can not be assured to
be interchangeable.
4.4
Markings
There are four markings on the ILM:
•
•
•
•
115XLM: Font type is Helvetica Bold - minimum 6 point (2.125 mm).
Manufacturer's insignia (font size at supplier's discretion).
Lot identification code (allows traceability of manufacturing date and location).
Pin 1 indicator on the load plate.
All markings must be visible after the ILM is assembled on the motherboard.
115XLM and the manufacturer's insignia can be ink stamped or laser marked on the
side wall.
Thermal/Mechanical Specifications and Design Guidelines
29
Independent Loading Mechanism (ILM)
4.5
ILM Cover
Intel has developed an ILM Cover that will snap onto the ILM for the LGA115x socket
family. The ILM cover is intended to reduce the potential for socket contact damage
from operator and customer fingers being close to the socket contacts to remove or
install the pick and place cap. The ILM Cover concept is shown in Figure 4-6.
The ILM Cover is intended to be used in place of the pick and place cover once the ILM
is assembled to the motherboard. The ILM will be offered with the ILM Cover pre
assembled as well as offered as a discrete component.
ILM Cover features:
• Pre-assembled by the ILM vendors to the ILM load plate. It will also be offered as a
discrete component.
• The ILM cover will pop off if a processor is installed in the socket, and the ILM
Cover and ILM are from the same manufacturer.
• ILM Cover can be installed while the ILM is open.
• Maintain inter-changeability between validated ILM vendors for LGA115x socket,
with the exception noted below.
Note: The ILM Cover pop off feature is not supported if the ILM Covers are
interchanged on different vendor’s ILMs.
• The ILM cover for the LGA115x socket will have a flammability rating of V-2 per
UL 60950-1.
Figure 4-6.
ILM Cover
Step 1: PnP Cover installed
during ILM assembly
Step 2: Remove PnP Cover
Step 3: Close ILM
30
Thermal/Mechanical Specifications and Design Guidelines
Independent Loading Mechanism (ILM)
As indicated in Figure 4-6, the pick and place cover should remain installed during ILM
assembly to the motherboard. After assembly, the pick and place cover is removed, the
ILM Cover installed and the ILM mechanism closed. The ILM Cover is designed to pop
off if the pick and place cover is accidentally left in place and the ILM closed with the
ILM Cover installed. This is shown in Figure 4-7.
Figure 4-7.
ILM Cover and PnP Cover Interference
As indicated in Figure 4-7, the pick and place cover cannot remain in place and used in
conjunction with the ILM Cover. The ILM Cover is designed to interfere and pop off if
the pick and place cover is unintentionally left in place. The ILM cover will also interfere
and pop off if the ILM is closed with a processor in place in the socket.
§
Thermal/Mechanical Specifications and Design Guidelines
31
Independent Loading Mechanism (ILM)
32
Thermal/Mechanical Specifications and Design Guidelines
LGA1155 Socket and ILM Electrical, Mechanical and Environmental Specifications
5
LGA1155 Socket and ILM
Electrical, Mechanical and
Environmental Specifications
This chapter describes the electrical, mechanical and environmental specifications for
the LGA1155 socket and the Independent Loading Mechanism.
5.1
Component Mass
Table 5-1.
Socket Component Mass
Component
5.2
Mass
Socket Body, Contacts and PnP Cover
10 g
ILM Cover
29 g
ILM Back Plate
38 g
Package/Socket Stackup Height
Table 5-2 provides the stackup height of a processor in the 1155-land LGA package and
LGA1155 socket with the ILM closed and the processor fully seated in the socket.
Table 5-2.
1155-land Package and LGA1155 Socket Stackup Height
Component
Stackup Height
Note
Integrated Stackup Height (mm)
From Top of Board to Top of IHS
7.781 ± 0.335 mm
2
Socket Nominal Seating Plane Height
3.4 ± 0.2 mm
1
Package Nominal Thickness (lands to top of IHS)
4.381 ± 0.269 mm
1
Notes:
1.
This data is provided for information only, and should be derived from: (a) the height of the socket seating
plane above the motherboard after reflow, given in Appendix C, (b) the height of the package, from the
package seating plane to the top of the IHS, and accounting for its nominal variation and tolerances that
are given in the corresponding processor data sheet.
2.
The integrated stackup height value is a RSS calculation based on current and planned processors that will
use the ILM design.
Thermal/Mechanical Specifications and Design Guidelines
33
LGA1155 Socket and ILM Electrical, Mechanical and Environmental Specifications
5.3
Loading Specifications
The socket will be tested against the conditions listed in Chapter 11 with heatsink and
the ILM attached, under the loading conditions outlined in this section.
Table 5-3 provides load specifications for the LGA1155 socket with the ILM installed.
The maximum limits should not be exceeded during heatsink assembly, shipping
conditions, or standard use condition. Exceeding these limits during test may result in
component failure. The socket body should not be used as a mechanical reference or
load-bearing surface for thermal solutions.
Table 5-3.
Socket & ILM Mechanical Specifications
Parameter
Min
Max
Notes
311 N [70 lbf]
600 N [135 lbf]
3, 4, 7, 8
0 N [0 lbf]
222 N [50 lbf]
1, 2, 3
311 N [70 lbf]
822 N [185 lbf]
3, 4, 7, 8
Dynamic Compressive Load
(with heatsink installed)
N/A
712 N [160 lbf]
1, 3, 5, 6
Pick & Place cover insertion force
N/A
10.2 N [2.3 lbf]
-
Pick & Place cover removal force
2.2N [0.5 lbf]
7.56 N [1.7 lbf]
9
N/A
20.9N [4.7lbf] in the
vertical direction
10.2 N [2.3 lbf] in the
lateral direction.
-
N/A
500g
10
ILM static compressive load on processor IHS
Heatsink static compressive load
Total static compressive Load
(ILM plus Heatsink)
Load lever actuation force
Maximum heatsink mass
Notes:
1.
These specifications apply to uniform compressive loading in a direction perpendicular to the IHS top
surface.
2.
This is the minimum and maximum static force that can be applied by the heatsink and it’s retention
solution to maintain the heatsink to IHS interface. This does not imply the Intel reference TIM is validated
to these limits.
3.
Loading limits are for the LGA1155 socket.
4.
This minimum limit defines the static compressive force required to electrically seat the processor onto the
socket contacts. The minimum load is a beginning of life load.
5.
Dynamic loading is defined as a load a 4.3 m/s [170 in/s] minimum velocity change average load
superimposed on the static load requirement.
6.
Test condition used a heatsink mass of 500gm [1.102 lb.] with 50 g acceleration (table input) and an
assumed 2X Dynamic Acceleration Factor (DAF). The dynamic portion of this specification in the product
application can have flexibility in specific values. The ultimate product of mass times acceleration plus static
heatsink load should not exceed this limit.
7.
The maximum BOL value and must not be exceeded at any point in the product life.
8.
The minimum value is a beginning of life loading requirement based on load degradation over time.
9.
The maximum removal force is the flick up removal upwards thumb force (measured at 45°), not applicable
to SMT operation for system assembly. Only the minimum removal force is applicable to vertical removal in
SMT operation for system assembly.
10. The maximum heatsink mass includes the heatsink, screws, springs, rings and cups. This mass limit is
evaluated using the heatsink attach to the PCB.
34
Thermal/Mechanical Specifications and Design Guidelines
LGA1155 Socket and ILM Electrical, Mechanical and Environmental Specifications
5.4
Electrical Requirements
LGA1155 socket electrical requirements are measured from the socket-seating plane of
the processor to the component side of the socket PCB to which it is attached. All
specifications are maximum values (unless otherwise stated) for a single socket
contact, but includes effects of adjacent contacts where indicated.
Table 5-4.
Electrical Requirements for LGA1155 Socket
Parameter
Mated loop inductance, Loop
Socket Average Contact Resistance
(EOL)
Max Individual Contact Resistance
(EOL)
Bulk Resistance Increase
Dielectric Withstand Voltage
Insulation Resistance
Thermal/Mechanical Specifications and Design Guidelines
Value
Comment
<3.6 nH
The inductance calculated for two contacts,
considering one forward conductor and one
return conductor. These values must be satisfied
at the worst-case height of the socket.
19 mOhm
The socket average contact resistance target is
calculated from the following equation:
sum (Ni X LLCRi) / sum (Ni)
• LLCRi is the chain resistance defined as the
resistance of each chain minus resistance of
shorting bars divided by number of lands in
the daisy chain.
• Ni is the number of contacts within a chain.
• I is the number of daisy chain, ranging from
1 to 119 (total number of daisy chains).
The specification listed is at room temperature
and has to be satisfied at all time.
100 mOhm
The specification listed is at room temperature
and has to be satisfied at all time.
Socket Contact Resistance: The resistance of
the socket contact, solderball, and interface
resistance to the interposer land; gaps included.
≤ 3 mΩ
The bulk resistance increase per contact from
25 °C to 100 °C.
360 Volts RMS
800 MΩ
35
LGA1155 Socket and ILM Electrical, Mechanical and Environmental Specifications
5.5
Environmental Requirements
Design, including materials, shall be consistent with the manufacture of units that meet
the following environmental reference points.
The reliability targets in this section are based on the expected field use environment
for these products. The test sequence for new sockets will be developed using the
knowledge-based reliability evaluation methodology, which is acceleration factor
dependent. A simplified process flow of this methodology can be seen in Figure 5-1.
Figure 5-1.
Flow Chart of Knowledge-Based Reliability Evaluation Methodology
Establish the
market/expected use
environment for the
technology
Develop Speculative
stress conditions based on
historical data, content
experts, and literature
search
Freeze stressing
requirements and perform
additional data turns
Perform stressing to
validate accelerated
stressing assumptions and
determine acceleration
factors
A detailed description of this methodology can be found at: ftp://download.intel.com/
technology/itj/q32000/pdf/reliability.pdf.
§
36
Thermal/Mechanical Specifications and Design Guidelines
Thermal Specifications
6
Thermal Specifications
The processor requires a thermal solution to maintain temperatures within its operating
limits. Any attempt to operate the processor outside these operating limits may result
in permanent damage to the processor and potentially other components within the
system. Maintaining the proper thermal environment is key to reliable, long-term
system operation.
A complete solution includes both component and system level thermal management
features. Component level thermal solutions can include active or passive heatsinks
attached to the processor integrated heat spreader (IHS).
This chapter provides data necessary for developing a complete thermal solution. For
more information on thermal solution design, refer to Chapter 9 and Chapter 10.
6.1
Thermal Specifications
To allow the optimal operation and long-term reliability of Intel processor-based
systems, the processor must remain within the minimum and maximum case
temperature (TCASE) specifications as defined by the applicable thermal profile.
Thermal solutions not designed to provide this level of thermal capability may affect the
long-term reliability of the processor and system. For more details on thermal solution
design, refer to the Chapter 9.
The processors implement a methodology for managing processor temperatures which
is intended to support acoustic noise reduction through fan speed control and to assure
processor reliability. Selection of the appropriate fan speed is based on the relative
temperature data reported by the processor’s Digital Temperature Sensor (DTS). The
DTS can be read via the Platform Environment Control Interface (PECI) as described in
Section 6.2. Alternatively, when PECI is monitored by the PCH, the processor
temperature can be read from the PCH using the SMBUS protocol defined in Embedded
Controller Support Provided by Platform Controller Hub (PCH). The temperature
reported over PECI is always a negative value and represents a delta below the onset of
thermal control circuit (TCC) activation, as indicated by PROCHOT# (see Section 6.2,
Processor Thermal Features). Systems that implement fan speed control must be
designed to use this data. Systems that do not alter the fan speed only need to ensure
the case temperature meets the thermal profile specifications.
A single integer change in the PECI value corresponds to approximately 1 °C change in
processor temperature. Although each processors DTS is factory calibrated, the
accuracy of the DTS will vary from part to part and may also vary slightly with
temperature and voltage. In general, each integer change in PECI should equal a
temperature change between 0.9 °C and 1.1 °C.
Analysis indicates that real applications are unlikely to cause the processor to consume
maximum power dissipation for sustained time periods. Intel recommends that
complete thermal solution designs target the Thermal Design Power (TDP), instead of
the maximum processor power consumption. The Adaptive Thermal Monitor feature is
intended to help protect the processor in the event that an application exceeds the TDP
recommendation for a sustained time period. For more details on this feature, refer to
Thermal/Mechanical Specifications and Design Guidelines
37
Thermal Specifications
Section 6.2. To ensure maximum flexibility for future processors, systems should be
designed to the Thermal Solution Capability guidelines, even if a processor with lower
power dissipation is currently planned.
Table 6-1.
Processor Thermal Specifications
Product
Guideli
nesFMB
10
Max
Power
Package
C1E
(W)1,2,7
Max
Power
Package
C3
(W)1,2,7
Max
Power
Package
C6
(W)1,3,7
TTV
Thermal
Design
Power
(W)4
Package
Thermal
Design
Power
(W)5,6,8
Min TCASE
(°C)
Maximum
TTV
TCASE
(°C)
Intel® Xeon®
Processor E3-1290 v2
(87W)
2011D
28
22
5.5
95
87
5
Figure 6-2
& Table 6-4
Intel® Xeon®
Processor E3-1200 v2
Series (77W)
2011D
28
22
5.5
95
77
5
Figure 6-2
& Table 6-4
Intel® Xeon®
Processor E3-1200 v2
Series (69W)
2011D
28
22
5.5
95(80)10
69
5
Figure 6-3
& Table 6-5
Intel® Xeon®
processor E3-1285L v2
(65W)
2011D
25
18
5
65
65
5
Figure 6-4
& Table 6-6
Intel® Xeon®
processor E3-1265L v2
(45W)
2011B
20
12
5.5
45
45
5
Figure 6-5
& Table 6-7
Intel® Xeon®
processor E3-1220L v2
(17W)
2011A
14
10
5
17
17
5
Figure 6-6
& Table 6-8
Notes:
1.
The package C-state power is the worst case power in the system configured as follows:
- Memory configured for DDR3 1333 and populated with 2 DIMM per channel.
- DMI and PCIe links are at L1.
2.
Specification at Tj of 50 °C and minimum voltage loadline.
3.
Specification at Tj of 35 °C and minimum voltage loadline
4.
TTV Thermal Design Power provide a design target of processor thermal solution for meeting all planned processor
frequencies requirements from generation to generation.
5.
These values are specified at VCC_MAX and VNOM for all other voltage rails for all processor frequencies. Systems must be
designed to ensure the processor is not to be subjected to any static VCC and ICC combination wherein VCCP exceeds VCCP_MAX
at specified ICCP. Please refer to the loadline specifications in the Datasheet.
6.
Thermal Design Power (TDP) should be used for processor thermal solution design targets. TDP is not the maximum power
that the processor can dissipate. TDP is measured at DTS = -1.
TDP is achieved with the Memory configured for DDR3 1333 and 2 DIMMs per channel.
7.
Specified by design characterization.
8.
When the Multi-monitor feature is enabled (running 4 displays simultaneously) there could be corner cases with additional
system thermal impact on the SA and VCCP rails ≤1.5W (maximum of 1.5W measured on 16 lane PCIe card). The integrator
should perform additional thermal validation with Multi-monitor enabled to ensure thermal compliance.
9.
For 69W package TDP SKU, last generation there were two separate TTV thermal profiles(95W/80W power target) with same
slope and intersection. For Intel® Xeon® processor E3-1200 v2 product, here combine to one TTV profile (95W) due to same
package TDP.
38
Thermal/Mechanical Specifications and Design Guidelines
Thermal Specifications
Table 6-2.
Product
87W
77W
69W
Package Turbo Parameters (Sheet 1 of 2)
Parameter
Definition
Min
HW
Default
Max
Units
Notes
Power Limit 1
Time (tau)
(package)
Turbo long duration time
window
(POWER_LIMIT_1_TIME in
TURBO_POWER_LIMIT MSR
0610h bits [23:17])
0.001
1
8
s
1,2,5,
6
Power Limit 1
(PL1)
(package)
'Long duration' turbo power
limit
(POWER_LIMIT_1 in
TURBO_POWER_LIMIT MSR
0610h bits [14:0])
20
87
-
W
1,3,4,
5,6
Power Limit 2
(PL2)
(package)
'Short duration' turbo power
limit
(POWER_LIMIT_2 in
TURBO_POWER_LIMIT MSR
0610h bits [46:32])
20
108.75
-
W
1,3,4,
5,6
Power Limit 1
Time (tau)
(package)
Turbo long duration time
window
(POWER_LIMIT_1_TIME in
TURBO_POWER_LIMIT MSR
0610h bits [23:17])
0.001
1
8
s
1,2,5,
6
Power Limit 1
(PL1)
(package)
'Long duration' turbo power
limit
(POWER_LIMIT_1 in
TURBO_POWER_LIMIT MSR
0610h bits [14:0])
20
77
-
W
1,3,4,
5,6
Power Limit 2
(PL2)
(package)
'Short duration' turbo power
limit
(POWER_LIMIT_2 in
TURBO_POWER_LIMIT MSR
0610h bits [46:32])
20
96.25
-
W
1,3,4,
5,6
Power Limit 1
Time (tau)
(package)
Turbo long duration time
window
(POWER_LIMIT_1_TIME in
TURBO_POWER_LIMIT MSR
0610h bits [23:17])
0.001
1
8
s
1,2,5,
6
Power Limit 1
(PL1)
(package)
'Long duration' turbo power
limit
(POWER_LIMIT_1 in
TURBO_POWER_LIMIT MSR
0610h bits [14:0])
20
69
-
W
1,3,4,
5,6
Power Limit 2
(PL2)
(package)
'Short duration' turbo power
limit
(POWER_LIMIT_2 in
TURBO_POWER_LIMIT MSR
0610h bits [46:32])
20
86.25
-
W
1,3,4,
5,6
Thermal/Mechanical Specifications and Design Guidelines
39
Thermal Specifications
Table 6-2.
Product
65W
45W
17W
Package Turbo Parameters (Sheet 2 of 2)
Parameter
Definition
Min
HW
Default
Max
Units
Notes
Power Limit 1
Time (tau)
(package)
Turbo long duration time
window
(POWER_LIMIT_1_TIME in
TURBO_POWER_LIMIT MSR
0610h bits [23:17])
0.001
1
8
s
1,2,5,
6
Power Limit 1
(PL1)
(package)
'Long duration' turbo power
limit
(POWER_LIMIT_1 in
TURBO_POWER_LIMIT MSR
0610h bits [14:0])
20
65
-
W
1,3,4,
5,6
Power Limit 2
(PL2)
(package)
'Short duration' turbo power
limit
(POWER_LIMIT_2 in
TURBO_POWER_LIMIT MSR
0610h bits [46:32])
20
81.25
-
W
1,3,4,
5,6
Power Limit 1
Time (tau)
(package)
Turbo long duration time
window
(POWER_LIMIT_1_TIME in
TURBO_POWER_LIMIT MSR
0610h bits [23:17])
0.001
1
8
s
1,2,5,
6
Power Limit 1
(PL1)
(package)
'Long duration' turbo power
limit
(POWER_LIMIT_1 in
TURBO_POWER_LIMIT MSR
0610h bits [14:0])
16
45
-
W
1,3,4,
5,6
Power Limit 2
(PL2)
(package)
'Short duration' turbo power
limit
(POWER_LIMIT_2 in
TURBO_POWER_LIMIT MSR
0610h bits [46:32])
16
56.25
-
W
1,3,4,
5,6
Power Limit 1
Time (tau)
(package)
Turbo long duration time
window
(POWER_LIMIT_1_TIME in
TURBO_POWER_LIMIT MSR
0610h bits [23:17])
0.001
1
8
s
1,2,5,
6
Power Limit 1
(PL1)
(package)
'Long duration' turbo power
limit
(POWER_LIMIT_1 in
TURBO_POWER_LIMIT MSR
0610h bits [14:0])
16
17
-
W
1,3,4,
5,6
Power Limit 2
(PL2)
(package)
'Short duration' turbo power
limit
(POWER_LIMIT_2 in
TURBO_POWER_LIMIT MSR
0610h bits [46:32])
16
21.25
-
W
1,3,4,
5,6
Notes:
1.
Can be dynamically modified by MSR writes and PECI commands
2.
'Turbo Time Parameter' is a mathematical parameter (units in seconds) that controls IVB turbo algorithm utilizing an
exponential weighted moving average of energy usage.
3.
Shown limit is a time averaged power, based upon the time window. Absolute product power may exceed the set limits under
virus or uncharacterized workloads.
40
Thermal/Mechanical Specifications and Design Guidelines
Thermal Specifications
4.
5.
6.
Processor will be controlled to specified power limit. If power value or turbo time parameters are changed during runtime, it
may take a short period of time (approximately 3 to 5 times the Turbo Time Parameter) for the algorithm to settle to the new
control limits.
Not a characteristic of the product. Parameter and suggested nominal value is a control mechanism, implemented as a
customization to optimize turbo within system limitations.
Intel® Turbo Boost Technology may vary between the processor SKUs.
6.1.1
Intel® Xeon® Processor E3-1290 v2 (87W) Thermal Profile
Figure 6-1.
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® Processor E3-1290 v2 (87W)
Notes:
1.
Refer to Table 6-4 for discrete points that constitute the thermal profile.
2.
Refer to Chapter 9 and Chapter 11 for system and environmental implementation details.
3.
This is the 95W TTV thermal profile 1.
Table 6-3.
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® Processor E3-1290 v2 (87W) (Sheet 1 of 2)
Power (W)
TCASE_MAX (°C)
Power (W)
TCASE_MAX (°C)
0
42.5
50
50.0
2
42.8
52
50.3
4
43.1
54
50.6
6
43.4
56
50.9
8
43.7
58
51.2
10
44.0
60
51.5
12
44.3
62
51.8
14
44.6
64
52.1
16
44.9
66
52.4
18
45.2
68
52.7
20
45.5
70
53.0
Thermal/Mechanical Specifications and Design Guidelines
41
Thermal Specifications
Table 6-3.
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® Processor E3-1290 v2 (87W) (Sheet 2 of 2)
Note:
Power (W)
TCASE_MAX (°C)
Power (W)
TCASE_MAX (°C)
22
45.8
72
53.3
24
46.1
74
53.6
26
46.4
76
53.9
28
46.7
78
54.2
30
47.0
80
54.5
32
47.3
82
54.8
34
47.6
84
55.1
36
47.9
86
55.4
38
48.2
871
55.51
40
48.5
88
55.7
42
48.8
90
56.0
44
49.1
92
56.3
46
49.4
94
56.6
48
49.7
95
56.7
Intel® Xeon® Processor E3-1290 v2 (87W) TCASE_MAX is 55.5°C
6.1.2
Intel® Xeon® Processor E3-1200 v2 Series (77W) Thermal
Profile
Figure 6-2.
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® Processor E3-1200 v2 Series (77W)
Notes:
1.
Refer to Table 6-4 for discrete points that constitute the thermal profile.
2.
Refer to Chapter 9 and Chapter 11 for system and environmental implementation details.
3.
This is the 95W TTV thermal profile 1.
42
Thermal/Mechanical Specifications and Design Guidelines
Thermal Specifications
Table 6-4.
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® Processor E3-1200 v2 Series (77W)
Power (W)
TCASE_MAX (°C)
Power (W)
TCASE_MAX (°C)
0
45.1
50
59.6
2
45.7
52
60.2
4
46.3
54
60.8
6
46.8
56
61.3
8
47.4
58
61.9
10
48.0
60
62.5
12
48.6
62
63.1
14
49.2
64
63.7
16
49.7
66
64.2
18
50.3
68
64.8
20
50.9
70
65.4
22
51.5
72
66.0
24
52.1
74
66.6
26
52.6
76
67.1
28
53.2
771
67.41
30
53.8
78
67.7
32
54.4
80
68.3
34
55.0
82
68.9
36
55.5
84
69.5
38
56.1
86
70.0
40
56.7
88
70.6
42
57.3
90
71.2
44
57.9
92
71.8
46
58.4
94
72.4
48
59.0
95
72.6
Notes:
1.
Intel® Xeon® Processor E3-1200 v2 Series (77W) TCASE_MAX is 67.4 °C.
Thermal/Mechanical Specifications and Design Guidelines
43
Thermal Specifications
6.1.3
Intel® Xeon® Processor E3-1200 v2 Series (69W) Thermal
Profile
Figure 6-3.
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® Processor E3-1200 v2 Series (69W)
Notes:
1.
Refer to Table 6-5 for discrete points that constitute the thermal profile.
2.
Refer to Chapter 9 and Chapter 11 for system and environmental implementation details.
3.
This is the 95W TTV thermal profile 2.
Table 6-5.
44
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® Processor E3-1200 v2 Series (69W) (Sheet 1 of 2)
Power (W)
TCASE_MAX (°C)
Power (W)
TCASE_MAX (°C)
0
45.1
50
60.1
2
45.7
52
60.7
4
46.3
54
61.3
6
46.9
56
61.9
8
47.5
58
62.5
10
48.1
60
63.1
12
48.7
62
63.7
14
49.3
64
64.3
16
49.9
66
64.9
18
50.5
68
65.5
20
51.1
691
65.81
22
51.7
70
66.1
24
52.3
72
66.7
Thermal/Mechanical Specifications and Design Guidelines
Thermal Specifications
Table 6-5.
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® Processor E3-1200 v2 Series (69W) (Sheet 2 of 2)
Power (W)
TCASE_MAX (°C)
Power (W)
TCASE_MAX (°C)
26
52.9
74
67.3
28
53.5
76
67.9
30
54.1
78
68.5
32
54.7
80
69.1
34
55.3
82
69.7
36
55.9
84
70.3
38
56.5
86
70.9
40
57.1
88
71.5
42
57.7
90
72.1
44
58.3
92
72.7
46
58.9
94
73.3
48
59.5
95
73.6
Notes:
1.
Intel® Xeon® Processor E3-1200 v2 Series (69W) TCASE_MAX is 65.8 °C
6.1.4
Intel® Xeon® Processor E3-1285L v2 (65W) Thermal
Profile
Figure 6-4.
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® Processor E3-1285L v2 (65W)
Notes:
1.
Refer to Table 6-6 for discrete points that constitute the thermal profile.
2.
Refer to Chapter 10 and Chapter 11 for system and environmental implementation details.
3.
This processor thermal specification is worse than others and needs better cooling solution.
4.
This is the 95W TTV thermal profile 3.
Thermal/Mechanical Specifications and Design Guidelines
45
Thermal Specifications
Table 6-6.
46
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® Processor E3-1285L v2 (65W)
Power (W)
TCASE_MAX (°C)
Power (W)
TCASE_MAX (°C)
0
44.0
50
63.0
2
44.8
52
63.8
4
45.5
54
64.5
6
46.3
56
65.3
8
47.0
58
66.0
10
47.8
60
66.8
12
48.6
62
67.6
14
49.3
64
68.3
16
50.1
65
68.7
18
50.8
68
69.8
20
51.6
70
70.6
22
52.4
72
71.4
24
53.1
74
72.1
26
53.9
76
72.9
28
54.6
78
73.6
30
55.4
80
74.4
32
56.2
82
75.2
34
56.9
84
75.9
36
57.7
86
76.7
38
58.4
88
77.4
40
59.2
90
78.2
42
60.0
92
79.0
44
60.7
93
79.3
46
61.5
94
79.7
48
62.2
95
80.1
Thermal/Mechanical Specifications and Design Guidelines
Thermal Specifications
6.1.5
Intel® Xeon® processor E3-1265L v2 (45W) Thermal
Profile
Figure 6-5.
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® processor E3-1265L v2 (45W)
Notes:
1.
Refer to Table 6-7 for discrete points that constitute the thermal profile.
2.
Refer to Chapter 9 and Chapter 11 for system and environmental implementation details.
Table 6-7.
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® processor E3-1265L v2 (45W)
Power (W)
TCASE_MAX (°C)
Power (W)
TCASE_MAX (°C)
0
48.2
24
59.7
2
49.2
26
60.7
4
50.1
28
61.6
6
51.1
30
62.6
8
52.0
32
63.6
10
53.0
34
64.5
12
54.09
36
65.5
14
54.9
38
66.4
16
55.9
40
67.4
18
56.8
42
68.4
20
57.8
44
69.3
22
58.8
45
69.8
Thermal/Mechanical Specifications and Design Guidelines
47
Thermal Specifications
6.1.6
Intel® Xeon® processor E3-1220L v2 (17W) Thermal
Profile
Figure 6-6.
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® processor E3-1220L v2 (17W)
Notes:
1.
Refer to Table 6-8 for discrete points that constitute the thermal profile.
2.
Refer to Chapter 9 and Chapter 11 for system and environmental implementation details.
Table 6-8.
48
Thermal Test Vehicle Thermal Profile for
Intel® Xeon® processor E3-1220L v2 (17W)
Power (W)
TCASE_MAX (°C)
Power (W)
TCASE_MAX (°C)
0
68.5
12
73.9
2
69.4
14
74.8
4
70.3
16
75.7
6
71.2
17
76.2
8
72.1
10
73.0
Thermal/Mechanical Specifications and Design Guidelines
Thermal Specifications
6.1.7
Processor Specification for Operation Where Digital
Thermal Sensor Exceeds TCONTROL
When the DTS value is less than TCONTROL the fan speed control algorithm can reduce
the speed of the thermal solution fan. This remains the same as with the previous
guidance for fan speed control.
• Table 6-9 for the Intel® Xeon® Processor E3-1290 v2 (87W)
• Table 6-10 for the Intel® Xeon® Processor E3-1200 v2 Series (77W)
• Table 6-11 for the Intel® Xeon® Processor E3-1200 v2 Series (69W)
• Table 6-12 for the Intel® Xeon® Processor E3-1285L v2 (65W)
• Table 6-13 for the Intel® Xeon® processor E3-1265L v2 (45W)
• Table 6-14 for the Intel® Xeon® processor E3-1220L v2 (17W)
To get the full acoustic benefit of the DTS specification, ambient temperature
monitoring is necessary.
Table 6-9.
Thermal Solution Performance above TCONTROL for
Intel® Xeon® Processor E3-1290 v2 (87W)
TAMBIENT1
ΨCA at
DTS = TCONTROL2
ΨCA at
DTS = -13
42.5
0.150
0.150
41.0
0.179
0.167
40.0
0.199
0.179
39.0
0.218
0.190
38.0
0.238
0.202
37.0
0.257
0.213
36.0
0.277
0.225
35.0
0.296
0.236
34.0
0.316
0.248
33.0
0.335
0.259
32.0
0.355
0.271
31.0
0.374
0.282
30.0
0.394
0.294
29.0
0.413
0.305
28.0
0.432
0.317
27.0
0.452
0.328
26.0
0.471
0.340
25.0
0.491
0.351
24.0
0.510
0.363
23.0
0.530
0.374
22.0
0.549
0.386
21.0
0.569
0.397
20.0
0.588
0.409
Notes:
1.
The ambient temperature is measured at the inlet to the processor thermal solution.
2.
This column can be expressed as a function of TAMBIENT by the following equation:
YCA = 0.15 + (42.5 - TAMBIENT) x 0.0195
3.
This column can be expressed as a function of TAMBIENT by the following equation:
YCA = 0.15 + (42.5 - TAMBIENT) x 0.0115
Thermal/Mechanical Specifications and Design Guidelines
49
Thermal Specifications
Table 6-10. Thermal Solution Performance above TCONTROL for
Intel® Xeon® Processor E3-1200 v2 Series (77W)
TAMBIENT1
ΨCA at
DTS = TCONTROL2
ΨCA at
DTS = -13
45.1
0.290
0.289
44.0
0.310
0.301
43.0
0.328
0.312
42.0
0.346
0.322
41.0
0.364
0.333
40.0
0.383
0.343
39.0
0.401
0.354
38.0
0.419
0.364
37.0
0.437
0.375
36.0
0.455
0.385
35.0
0.473
0.396
34.0
0.491
0.406
33.0
0.510
0.417
32.0
0.528
0.427
31.0
0.546
0.438
30.0
0.564
0.448
29.0
0.582
0.459
28.0
0.600
0.469
27.0
0.618
0.480
26.0
0.637
0.491
25.0
0.655
0.501
24.0
0.673
0.512
23.0
0.691
0.522
22.0
0.709
0.533
21.0
0.727
0.543
20.0
0.746
0.554
Notes:
1.
The ambient temperature is measured at the inlet to the processor thermal solution.
2.
This column can be expressed as a function of TAMBIENT by the following equation:
YCA = 0.29 + (45.1 - TAMBIENT) x 0.0181
3.
This column can be expressed as a function of TAMBIENT by the following equation:
YCA = 0.29 + (45.1 - TAMBIENT) x 0.0105
50
Thermal/Mechanical Specifications and Design Guidelines
Thermal Specifications
Table 6-11. Thermal Solution Performance above TCONTROL for
Intel® Xeon® Processor E3-1200 v2 Series (69W)
TAMBIENT1
ΨCA at
DTS = TCONTROL2
ΨCA at
DTS = -13
45.1
0.300
0.300
44.0
0.320
0.312
43.0
0.337
0.322
42.0
0.355
0.333
41.0
0.373
0.343
40.0
0.391
0.354
39.0
0.409
0.364
38.0
0.427
0.375
37.0
0.445
0.385
36.0
0.462
0.396
35.0
0.480
0.406
34.0
0.498
0.417
33.0
0.516
0.427
32.0
0.534
0.438
31.0
0.552
0.448
30.0
0.569
0.459
29.0
0.587
0.469
28.0
0.605
0.480
27.0
0.623
0.491
26.0
0.641
0.501
25.0
0.659
0.512
24.0
0.676
0.522
23.0
0.694
0.533
22.0
0.712
0.543
21.0
0.730
0.554
20.0
0.748
0.564
Notes:
1.
The ambient temperature is measured at the inlet to the processor thermal solution.
2.
This column can be expressed as a function of TAMBIENT by the following equation:
YCA = 0.30 + (45.1 - TAMBIENT) x 0.0178
3.
This column can be expressed as a function of TAMBIENT by the following equation:
YCA = 0.30 + (45.1 - TAMBIENT) x 0.0105
Thermal/Mechanical Specifications and Design Guidelines
51
Thermal Specifications
Table 6-12. Thermal Solution Performance above TCONTROL for
Intel® Xeon® Processor E3-1285L v2 (65W)
TAMBIENT1
ΨCA at
DTS = TCONTROL2
ΨCA at
DTS = -13
44.0
0.380
0.178
43.0
0.406
0.193
42.0
0.432
0.208
41.0
0.458
0.224
40.0
0.484
0.239
39.0
0.510
0.255
38.0
0.536
0.270
37.0
0.563
0.285
36.0
0.589
0.301
35.0
0.615
0.316
34.0
0.641
0.332
33.0
0.667
0.347
32.0
0.693
0.362
31.0
0.719
0.378
30.0
0.745
0.393
29.0
0.771
0.408
28.0
0.797
0.424
27.0
0.823
0.439
26.0
0.849
0.455
25.0
0.875
0.470
24.0
0.902
0.485
23.0
0.928
0.501
22.0
0.954
0.516
21.0
0.980
0.532
20.0
1.006
0.547
Notes:
1.
The ambient temperature is measured at the inlet to the processor thermal solution.
2.
This column can be expressed as a function of TAMBIENT by the following equation:
YCA = 0.38 + (44.0 - TAMBIENT) x 0.0261
3.
This column can be expressed as a function of TAMBIENT by the following equation:
YCA = 0.38 + (44.0 - TAMBIENT) x 0.0154
52
Thermal/Mechanical Specifications and Design Guidelines
Thermal Specifications
Table 6-13. Thermal Solution Performance above TCONTROL for
Intel® Xeon® processor E3-1265L v2 (45W)
TAMBIENT1
ΨCA at
DTS = TCONTROL2
ΨCA at
DTS = -13
48.2
0.480
0.480
47.0
0.525
0.507
46.0
0.563
0.529
45.0
0.601
0.551
44.0
0.638
0.573
43.0
0.676
0.596
42.0
0.714
0.618
41.0
0.751
0.640
40.0
0.789
0.662
39.0
0.827
0.684
38.0
0.864
0.707
37.0
0.902
0.729
36.0
0.940
0.751
35.0
0.977
0.773
34.0
1.015
0.796
33.0
1.053
0.818
32.0
1.090
0.840
31.0
1.128
0.862
30.0
1.165
0.884
29.0
1.203
0.907
28.0
1.241
0.929
27.0
1.278
0.951
26.0
1.316
0.973
25.0
1.354
0.996
24.0
1.391
1.018
23.0
1.429
1.040
Notes:
1.
The ambient temperature is measured at the inlet to the processor thermal solution.
2.
This column can be expressed as a function of TAMBIENT by the following equation:
YCA = 0.48 + (48.2 - TAMBIENT) x 0.0377
3.
This column can be expressed as a function of TAMBIENT by the following equation:
YCA = 0.48 + (48.2 - TAMBIENT) x 0.0222
Thermal/Mechanical Specifications and Design Guidelines
53
Thermal Specifications
Table 6-14. Thermal Solution Performance above TCONTROL for
Intel® Xeon® processor E3-1220L v2 (17W)
TAMBIENT1
ΨCA at
DTS = TCONTROL2
ΨCA at
DTS = -13
50.0
2.018
1.375
49.0
2.103
1.425
48.0
2.187
1.475
47.0
2.272
1.525
46.0
2.357
1.575
45.0
2.442
1.625
44.0
2.526
1.675
43.0
2.611
1.725
42.0
2.696
1.775
41.0
2.781
1.825
40.0
2.865
1.875
39.0
2.950
1.925
38.0
3.035
1.975
37.0
3.119
2.025
36.0
3.204
2.075
35.0
3.289
2.125
34.0
3.374
2.175
33.0
3.458
2.225
32.0
3.543
2.275
31.0
3.628
2.325
30.0
3.713
2.375
29.0
3.797
2.425
28.0
3.882
2.475
27.0
3.967
2.525
26.0
4.052
2.575
25.0
4.136
2.625
Notes:
1.
The ambient temperature is measured at the inlet to the processor thermal solution.
2.
This column can be expressed as a function of TAMBIENT by the following equation:
YCA = 2.018+ (68.5 - TAMBIENT) x 0.0847
3.
This column can be expressed as a function of TAMBIENT by the following equation:
YCA = 1.38 + (68.5 - TAMBIENT) x 0.05
54
Thermal/Mechanical Specifications and Design Guidelines
Thermal Specifications
6.1.8
Thermal Metrology
The maximum TTV case temperatures (TCASE-MAX) can be derived from the data in the
appropriate TTV thermal profile earlier in this chapter. The TTV TCASE is measured at the
geometric top center of the TTV integrated heat spreader (IHS). Figure 6-7 illustrates
the location where TCASE temperature measurements should be made. See Figure B-17
for drawing showing the thermocouple attach to the TTV package.
Figure 6-7.
TTV Case Temperature (TCASE) Measurement Location
37.5
Measure TCASE at
the geometric
center of the
package
37.5
Note:
The following supplier can machine the groove and attach a thermocouple to the IHS.
The supplier is listed the table below as a convenience to Intel’s general customers and
the list may be subject to change without notice. THERM-X OF CALIFORNIA Inc, 3200
Investment Blvd., Hayward, Ca 94545. Ernesto B Valencia +1-510-441-7566 Ext. 242
ernestov@therm-x.com. The vendor part number is XTMS1565.
Thermal/Mechanical Specifications and Design Guidelines
55
Thermal Specifications
6.2
Processor Thermal Features
6.2.1
Processor Temperature
A software readable field in the IA32_TEMPERATURE_TARGET register that contains the
minimum temperature at which the TCC will be activated and PROCHOT# will be
asserted. The TCC activation temperature is calibrated on a part-by-part basis and
normal factory variation may result in the actual TCC activation temperature being
higher than the value listed in the register. TCC activation temperatures may change
based on processor stepping, frequency or manufacturing efficiencies.
6.2.2
Adaptive Thermal Monitor
The purpose of the Adaptive Thermal Monitor is to reduce processor core power
consumption and temperature until it operates at or below its maximum operating
temperature. Processor core power reduction is achieved by:
• Adjusting the operating frequency (using the core ratio multiplier) and input
voltage (using the SVID bus).
• Modulating (starting and stopping) the internal processor core clocks (duty cycle).
The Adaptive Thermal Monitor can be activated when any package temperature,
monitored by a digital thermal sensor (DTS), meets or exceeds the TCC activation
temperature and asserts PROCHOT#. The assertion of PROCHOT# activates the
thermal control circuit (TCC), and causes both the processor core and graphics core to
reduce frequency and voltage adaptively. The TCC will remain active as long as any
package temperature exceeds its specified limit. Therefore, the Adaptive Thermal
Monitor will continue to reduce the package frequency and voltage until the TCC is deactivated.
The temperature at which the Adaptive Thermal Monitor activates the thermal control
circuit is factory calibrated and is not user configurable. The default value is software
visible in the TEMPERATURE_TARGET (0x1A2) MSR, bits 23:16. The Adaptive Thermal
Monitor does not require any additional hardware, software drivers, or interrupt
handling routines. Note that the Adaptive Thermal Monitor is not intended as a
mechanism to maintain processor TDP. The system design should provide a thermal
solution that can maintain TDP within its intended usage range.
Note:
Adaptive Thermal Monitor protection is always enabled.
6.2.2.1
TCC Activation Offset
TCC Activation Offset can be used to activate the TCC at temperatures lower than TCC
activation temperature (DTS = 0). It is the preferred thermal protection mechanism for
Intel Turbo Boost operation since ACPI passive throttling states will pull the processor
out of turbo mode operation when triggered. An offset (in degrees Celsius) can be
written to the TEMPERATURE_TARGET (0x1A2) MSR, bits 27:24. This value will be
subtracted from the value found in bits 23:16. The default offset is 0 °C, where
throttling will occur at TCC activation temperature. The offset should be set lower than
any other protection such as ACPI _PSV trip points.
56
Thermal/Mechanical Specifications and Design Guidelines
Thermal Specifications
6.2.2.2
Frequency/VID Control
Upon TCC activation, the processor core attempts to dynamically reduce processor core
power by lowering the frequency and voltage operating point. The operating points are
automatically calculated by the processor core itself and do not require the BIOS to
program them as with previous generations of Intel processors. The processor core will
scale the operating points such that:
• The voltage will be optimized according to the temperature, the core bus ratio, and
number of cores in deep C-states.
• The core power and temperature are reduced while minimizing performance
degradation.
Once the temperature has dropped below the maximum operating temperature,
operating frequency and voltage transition will transition back to the normal system
operating point. This is illustrated in Figure 6-8.
Figure 6-8.
Frequency and Voltage Ordering
Once a target frequency/bus ratio is resolved, the processor core will transition to the
new target automatically.
• On an upward operating point transition, the voltage transition precedes the
frequency transition.
• On a downward transition, the frequency transition precedes the voltage transition.
When transitioning to a target core operating voltage, a new VID code to the voltage
regulator is issued. The voltage regulator must support dynamic VID steps to support
this method.
Thermal/Mechanical Specifications and Design Guidelines
57
Thermal Specifications
During the voltage change:
• It will be necessary to transition through multiple VID steps to reach the target
operating voltage.
• Each step is 5 mV for Intel MVP-7.0 compliant VRs.
• The processor continues to execute instructions. However, the processor will halt
instruction execution for frequency transitions.
If a processor load-based Enhanced Intel SpeedStep Technology/P-state transition
(through MSR write) is initiated while the Adaptive Thermal Monitor is active, there are
two possible outcomes:
• If the P-state target frequency is higher than the processor core optimized target
frequency, the p-state transition will be deferred until the thermal event has been
completed.
• If the P-state target frequency is lower than the processor core optimized target
frequency, the processor will transition to the P-state operating point.
6.2.2.3
Clock Modulation
If the frequency/voltage changes are unable to end an Adaptive Thermal Monitor
event, the Adaptive Thermal Monitor will use clock modulation. Clock modulation is
done by alternately turning the clocks off and on at a duty cycle (ratio between clock
“on” time and total time) specific to the processor. The duty cycle is factory configured
to 25% on and 75% off and cannot be modified. The period of the duty cycle is
configured to 32 microseconds when the TCC is active. Cycle times are independent of
processor frequency. A small amount of hysteresis has been included to prevent
excessive clock modulation when the processor temperature is near its maximum
operating temperature. Once the temperature has dropped below the maximum
operating temperature, and the hysteresis timer has expired, the TCC goes inactive and
clock modulation ceases. Clock modulation is automatically engaged as part of the TCC
activation when the frequency/voltage targets are at their minimum settings. Processor
performance will be decreased by the same amount as the duty cycle when clock
modulation is active. Snooping and interrupt processing are performed in the normal
manner while the TCC is active.
6.2.3
Digital Thermal Sensor
Each processor execution core has an on-die Digital Thermal Sensor (DTS) that detects
the core’s instantaneous temperature. The DTS is the preferred method of monitoring
processor die temperature because
• It is located near the hottest portions of the die.
• It can accurately track the die temperature and ensure that the Adaptive Thermal
Monitor is not excessively activated.
Temperature values from the DTS can be retrieved through
• A software interface via processor Model Specific Register (MSR).
• A processor hardware interface as described in Chapter 7, “PECI Interface”.
Note:
58
When temperature is retrieved by processor MSR, it is the instantaneous temperature
of the given core. When temperature is retrieved using PECI, it is the average of the
highest DTS temperature in the package over a 256 ms time window. Intel
recommends using the PECI reported temperature for platform thermal control that
Thermal/Mechanical Specifications and Design Guidelines
Thermal Specifications
benefits from averaging, such as fan speed control. The average DTS temperature may
not be a good indicator of package Adaptive Thermal Monitor activation or rapid
increases in temperature that triggers the Out of Specification status bit within the
PACKAGE_THERM_STATUS MSR 1B1h and IA32_THERM_STATUS MSR 19Ch.
Code execution is halted in C1–C6. Therefore, temperature cannot be read using the
processor MSR without bringing a core back into C0. However, temperature can still be
monitored through PECI in lower C-states.
Unlike traditional thermal devices, the DTS outputs a temperature relative to the TCC
activation temperature, regardless of TCC activation offset. It is the responsibility of
software to convert the relative temperature to an absolute temperature. The absolute
reference temperature is readable in the TEMPERATURE_TARGET MSR 1A2h. The
temperature returned by the DTS is an implied negative integer indicating the relative
offset from TCC activation temperature. The DTS does not report temperatures greater
than TCC activation temperature.
The DTS-relative temperature readout directly impacts the Adaptive Thermal Monitor
trigger point. When a package DTS indicates that it has reached the TCC activation (a
reading of 0x0, except when the TCC activation offset is changed), the TCC will activate
and indicate a Adaptive Thermal Monitor event. A TCC activation will lower both IA core
and graphics core frequency, voltage or both.
Changes to the temperature can be detected via two programmable thresholds located
in the processor thermal MSRs. These thresholds have the capability of generating
interrupts via the core's local APIC. Refer to the Intel® 64 and IA-32 Architectures
Software Developer's Manuals for specific register and programming details.
6.2.4
PROCHOT# Signal
PROCHOT# (processor hot) is asserted when the processor core temperature has
reached TCC activation temperature. See Figure 6-8 for a timing diagram of the
PROCHOT# signal assertion relative to the Adaptive Thermal Response. Only a single
PROCHOT# pin exists at a package level. When any core arrives at the TCC activation
point, the PROCHOT# signal will be asserted. PROCHOT# assertion policies are
independent of Adaptive Thermal Monitor enabling.
Note:
Bus snooping and interrupt latching are active while the TCC is active.
6.2.4.1
Bi-Directional PROCHOT#
By default, the PROCHOT# signal is defined as an output only. However, the signal may
be configured as bi-directional. When configured as a bi-directional signal, PROCHOT#
can be used for thermally protecting other platform components should they overheat
as well. When PROCHOT# is driven by an external device:
• the package will immediately transition to the minimum operation points (voltage
and frequency) supported by the processor and graphics cores. This is contrary to
the internally-generated Adaptive Thermal Monitor response.
• Clock modulation is not activated.
The TCC will remain active until the system deasserts PROCHOT#. The processor can
be configured to generate an interrupt upon assertion and deassertion of the
PROCHOT# signal.
Thermal/Mechanical Specifications and Design Guidelines
59
Thermal Specifications
6.2.4.2
Voltage Regulator Protection using PROCHOT#
PROCHOT# may be used for thermal protection of voltage regulators (VR). System
designers can create a circuit to monitor the VR temperature and activate the TCC
when the temperature limit of the VR is reached. By asserting PROCHOT# (pulled-low)
and activating the TCC, the VR will cool down as a result of reduced processor power
consumption. Bi-directional PROCHOT# can allow VR thermal designs to target thermal
design current (ICCTDC) instead of maximum current. Systems should still provide
proper cooling for the VR and rely on bi-directional PROCHOT# only as a backup in case
of system cooling failure. Overall, the system thermal design should allow the power
delivery circuitry to operate within its temperature specification even while the
processor is operating at its TDP.
6.2.5
THERMTRIP# Signal
Regardless of enabling the automatic or on-demand modes, in the event of a
catastrophic cooling failure, the package will automatically shut down when the silicon
has reached an elevated temperature that risks physical damage to the product. At this
point the THERMTRIP# signal will go active.
6.3
Intel® Turbo Boost Technology
Intel® Turbo Boost Technology is a feature that allows the processor to
opportunistically and automatically run faster than its rated operating core and/or
render clock frequency when there is sufficient power headroom, and the product is
within specified temperature and current limits. The Intel® Turbo Boost Technology
feature is designed to increase performance of both multi-threaded and singlethreaded workloads. The processor supports a Turbo mode where the processor can
utilize the thermal capacitance associated with the package and run at power levels
higher than TDP power for short durations. This improves the system responsiveness
for short, bursty usage conditions. The turbo feature needs to be properly enabled by
BIOS for the processor to operate with maximum performance. Since the turbo feature
is configurable and dependent on many platform design limits outside of the processor
control, the maximum performance cannot be ensured.
Turbo Mode availability is independent of the number of active cores; however, the
Turbo Mode frequency is dynamic and dependent on the instantaneous application
power load, the number of active cores, user configurable settings, operating
environment and system design.
Note:
Intel® Turbo Boost Technology may not be available on all SKUs.
6.3.1
Intel® Turbo Boost Technology Frequency
The processor’s rated frequency assumes that all execution cores are running an
application at the Thermal Design Power (TDP). However, under typical operation, not
all cores are active. Therefore most applications are consuming less than the TDP at the
rated frequency. To take advantage of the available TDP headroom, the active cores can
increase their operating frequency.
To determine the highest performance frequency amongst active cores, the processor
takes the following into consideration:
•
•
•
•
60
The
The
The
The
number of cores operating in the C0 state.
estimated current consumption.
estimated power consumption.
temperature.
Thermal/Mechanical Specifications and Design Guidelines
Thermal Specifications
Any of these factors can affect the maximum frequency for a given workload. If the
power, current, or thermal limit is reached, the processor will automatically reduce the
frequency to stay with its TDP limit.
Note:
Intel Turbo Boost Technology processor frequencies are only active if the operating
system is requesting the P0 state.
6.3.2
Intel® Turbo Boost Technology Graphics Frequency
Graphics render frequency is selected by the processor dynamically based on the
graphics workload demand. The processor can optimize both processor and integrated
graphics performance through Intelligent Power Sharing. For the integrated graphics,
this could mean an increase in the render core frequency (above its rated frequency)
and increased graphics performance. In addition, the processor core can increase its
frequency higher than it would without power sharing.
Enabling Intel® Turbo Boost Technology will maximize the performance of the
processor core and the graphics render frequency within the specified package power
levels. Compared with previous generation products, Intel® Turbo Boost Technology
will increase the ratio of application power to TDP. Thus, thermal solutions and platform
cooling that are designed to less than thermal design guidance might experience
thermal and performance issues since more applications will tend to run at the
maximum power limit for significant periods of time.
6.3.3
Thermal Considerations
Intel® Turbo Boost Technology allows processor cores and integrated graphics cores to
run faster than the baseline frequency. During a turbo event, the processor can exceed
its TDP power for brief periods. Turbo is invoked opportunistically and automatically as
long as the processor is conforming to its temperature, power delivery, and current
specification limits. Thus, thermal solutions and platform cooling that are designed to
less than thermal design guidance may experience thermal and performance issues
since more applications will tend to run at or near the maximum power limit for
significant periods of time.
6.3.4
Intel® Turbo Boost Technology Power Monitoring
When operating in the turbo mode, the processor will monitor its own power and adjust
the turbo frequency to maintain the average power within limits over a thermally
significant time period. The package, processor core and graphic core powers are
estimated using architectural counters and do not rely on any input from the platform.
The following considerations and limitations apply to the Intel Turbo Boost Technology
power monitoring:
• Internal power monitoring is calibrated per processor family and is not conducted
on a part-by-part basis. Therefore, some difference between actual and reported
power may be observed.
• Power monitoring is calibrated with a variety of common, realistic workloads near
TCC activation temperature. Workloads with power characteristics markedly
different from those used during the calibration process or lower temperatures may
result in increased differences between actual and estimated power.
• In the event an uncharacterized workload or power “virus” application were to
result in exceeding programmed power limits, the processor Thermal Control
Circuitry (TCC) will protect the processor when properly enabled. Adaptive Thermal
Monitor must be enabled for the processor to remain within specification.
Thermal/Mechanical Specifications and Design Guidelines
61
Thermal Specifications
6.3.5
Intel® Turbo Boost Technology Power Control
Illustration of Intel Turbo Boost Technology power control is shown in the following
sections and figures. Multiple controls operate simultaneously allowing for
customization for multiple system thermal and power limitations. These controls allow
for turbo optimizations within system constraints and are accessible using MSR, MMIO
or PECI interfaces.
6.3.5.1
Package Power Control
Intel Turbo Boost Technology package power control allows for customization in order
to implement optimal turbo within platform power delivery and package thermal
solution limitations. The control settings are shown in Table 6-15 while the behavior is
illustrated in Figure 6-9.
Table 6-15. Intel® Turbo Boost Technology Package Power Control Settings
MSR:
Address:
Control
POWER_LIMIT_1
POWER_LIMIT_1_TIME
POWER_LIMIT_2
62
MSR_TURBO_POWER_LIMIT
610h
Bit
14:0
23:17
46:32
Default
Description
SKU TDP
This value sets the exponentially weighted moving
average power limit over a long time period. This is
normally aligned to the TDP of the part and steadystate cooling capability of the thermal solution. This
limit may be set lower than TDP, real-time, for
specific needs, such as responding to a thermal
event. If set lower than TDP, the processor may not
be able to honor this limit for all workloads since this
control only applies in the turbo frequency range; a
very high powered application may exceed
POWER_LIMIT_1, even at non-turbo frequencies.
PL1 limit maybe set slightly higher than TDP. If set
higher than TDP, the processor could stay at that
power level continuously and cooling solution
improvements may be required.
1 sec
1.25 x TDP
This value is a time parameter that adjusts the
algorithm behavior. The exponentially weighted
moving average turbo algorithm will utilize this
parameter to maintain time averaged power at or
below POWER_LIMIT_1. The default value is 1
second.
Establishes the upper power limit of turbo operation
above TDP, primarily for platform power supply
considerations. Power may exceed this limit for up
to 10 ms. The default for this limit is 1.25 x TDP.
Setting this limit to TDP will limit the processor to
only operating up to TDP, it does not disable turbo.
Because turbo is opportunistic and power/
temperature dependant, many workloads will allow
some turbo frequencies at power at or below TDP.
Thermal/Mechanical Specifications and Design Guidelines
Thermal Specifications
Figure 6-9.
Package Power Control
System Thermal
Thermal Response
Response Time
Time
System
6.3.5.2
Power Plane Control
The processor core and graphics core power plane controls allow for customization to
implement optimal turbo within voltage regulator thermal limitations. It is possible to
use these power plane controls to protect the voltage regulator from overheating due
to extended high currents.
6.3.5.3
Turbo Time Parameter
'Turbo Time Parameter' is a mathematical parameter (units in seconds) that controls
the Intel Turbo Boost Technology algorithm utilizing an exponentially weighted moving
average of energy usage. During a maximum power turbo event of about 1.25 x TDP,
the processor could sustain POWER_LIMIT_2 for up to approximately 1.5 times the
Turbo Time Parameter. If the power value and/or ‘Turbo Time Parameter’ is changed
during runtime, it may take a period of time (possibly up to approximately 3 to 5 times
the ‘Turbo Time Parameter’, depending on the magnitude of the change and other
factors) for the algorithm to settle at the new control limits. There is an individual Turbo
Time parameter associated with Package Power Control and another associated with
each power plane.
§
Thermal/Mechanical Specifications and Design Guidelines
63
Thermal Specifications
64
Thermal/Mechanical Specifications and Design Guidelines
PECI Interface
7
PECI Interface
7.1
Platform Environment Control Interface (PECI)
7.1.1
Introduction
PECI uses a single wire for self-clocking and data transfer. The bus requires no
additional control lines. The physical layer is a self-clocked one-wire bus that begins
each bit with a driven, rising edge from an idle level near zero volts. The duration of the
signal driven high depends on whether the bit value is a logic ‘0’ or logic ‘1’. PECI also
includes variable data transfer rate established with every message. In this way, it is
highly flexible even though underlying logic is simple.
The interface design was optimized for interfacing to Intel processors in both single
processor and multiple processor environments. The single wire interface provides low
board routing overhead for the multiple load connections in the congested routing area
near the processor and chipset components. Bus speed, error checking, and low
protocol overhead provides adequate link bandwidth and reliability to transfer critical
device operating conditions and configuration information.
The PECI bus offers:
• A wide speed range from 2 Kbps to 2 Mbps.
• CRC check byte used to efficiently and atomically confirm accurate data delivery.
• Synchronization at the beginning of every message minimizes device timing
accuracy requirements.
For single processor temperature monitoring and fan speed control management
purpose, the PECI 3.0 commands that are commonly implemented includes Ping(),
GetDIB(), GetTemp(), TCONTROL and TjMax(TCC) read. The TCONTROL and TCC read
command can be implemented by utilizing the RdPkgConfig() command.
7.1.1.1
Fan Speed Control with Digital Thermal Sensor
Processor fan speed control is managed by comparing DTS temperature data against
the processor-specific value stored in the static variable, TCONTROL. When the DTS
temperature data is less than TCONTROL, the fan speed control algorithm can reduce the
speed of the thermal solution fan. This remains the same as with the previous guidance
for fan speed control. Please refer to Section 6.1.6 for guidance where the DTS
temperature data exceeds TCONTROL.
The DTS temperature data is delivered over PECI, in response to a GetTemp()
command, and reported as a relative value to TCC activation target. The temperature
data reported over PECI is always a negative value and represents a delta below the
onset of thermal control circuit (TCC) activation, as indicated by the PROCHOT# signal.
Therefore, as the temperature approaches TCC activation, the value approaches zero
degrees.
§
Thermal/Mechanical Specifications and Design Guidelines
65
PECI Interface
66
Thermal/Mechanical Specifications and Design Guidelines
Sensor Based Thermal Specification Design Guidance
8
Sensor Based Thermal
Specification Design Guidance
The sensor based thermal specification presents opportunities for the system designer
to optimize the acoustics and simplify thermal validation. The sensor based
specification utilizes the Digital Thermal Sensor information accessed via the PECI
interface.
This chapter will review thermal solution design options, fan speed control design
guidance & implementation options and suggestions on validation both with the TTV
and the live die in a shipping system.
Note:
A new fan speed control implementation scheme is introduced for the Intel® Xeon®
processor called DTS 1.1. Refer to Section 8.4.1 for more details.
8.1
Sensor Based Specification Overview (DTS 1.0)
Create a thermal specification that meets the following requirements:
• Use Digital Thermal Sensor (DTS) for real-time thermal specification compliance.
• Single point of reference for thermal specification compliance over all operating
conditions.
• Does not required measuring processor power & case temperature during
functional system thermal validation.
• Opportunity for acoustic benefits for DTS values between TCONTROL and -1.
Thermal specifications based on the processor case temperature have some notable
gaps to optimal acoustic design. When the ambient temperature is less than the
maximum design point, the fan speed control system (FSC) will over cool the processor.
The FSC has no feedback mechanism to detect this over cooling, this is shown in the
top half of Figure 8-1.
The sensor based specification will allow the FSC to be operated at the maximum
allowable silicon temperature or TJ for the measured ambient. This will provide optimal
acoustics for operation above TCONTROL. See lower half of Figure 8-1.
Thermal/Mechanical Specifications and Design Guidelines
67
Sensor Based Thermal Specification Design Guidance
Figure 8-1.
Comparison of Case Temperature versus Sensor Based Specification
Ta = 45.1 °C
Tcontrol
Ta = 30 °C
Ψ-ca = 0.292
Power
TDP
Current Specification (Case Temp)
Ψ-ca = 0.448
Ψ-ca = 0.564
Tcontrol
Ta = 30 C
TDP
Power
Sensor Based Specification (DTS Temp)
8.2
Sensor Based Thermal Specification
The sensor based thermal specification consists of two parts. The first is a thermal
profile that defines the maximum TTV TCASE as a function of TTV power dissipation. The
thermal profile defines the boundary conditions for validation of the thermal solution.
The second part is a defined thermal solution performance (ΨCA) as a function of the
DTS value as reported over the PECI bus when DTS is greater than TCONTROL. This
defines the operational limits for the processor using the TTV validated thermal
solution.
8.2.1
TTV Thermal Profile
For the sensor based specification the only reference made to a case temperature
measurement is on the TTV. Functional thermal validation will not require the user to
apply a thermocouple to the processor package or measure processor power.
Note:
All functional compliance testing will be based on fan speed response to the reported
DTS values above TCONTROL. As a result no conversion of TTV TCASE to processor TCASE
will be necessary.
A knowledge of the system boundary conditions is necessary to perform the heatsink
validation. Section 8.3.1 will provide more detail on defining the boundary conditions.
The TTV is placed in the socket and powered to the recommended value to simulate the
TDP condition.
68
Thermal/Mechanical Specifications and Design Guidelines
Sensor Based Thermal Specification Design Guidance
8.2.2
Specification When DTS value is Greater than TCONTROL
The product specification provides a table of ΨCA values at DTS = TCONTROL and
DTS = -1 as a function of TAMBIENT (inlet to heatsink). Between these two defined
points, a linear interpolation can be done for any DTS value reported by the processor.
The fan speed control algorithm has enough information using only the DTS value and
TAMBIENT to command the thermal solution to provide just enough cooling to keep the
part on the thermal profile.
In the prior thermal specifications this region, DTS values greater than TCONTROL, was
defined by the processor thermal profile. This required the user to estimate the
processor power and case temperature. Neither of these two data points are accessible
in real time for the fan speed control system. As a result the designer had to assume
the worst case TAMBIENT and drive the fans to accommodate that boundary condition.
8.3
Thermal Solution Design Process
Thermal solution design guidance for this specification is the same as with previous
products. The initial design needs to take into account the target market and overall
product requirements for the system. This can be broken down into several steps:
• Boundary condition definition
• Thermal design / modelling
• Thermal testing.
8.3.1
Boundary Condition Definition
Using the knowledge of the system boundary conditions, for example, inlet air
temperature, acoustic requirements, cost, design for manufacturing, package and
socket mechanical specifications and chassis environmental test limits the designer can
make informed thermal solution design decisions.
For the thermal boundary conditions for system are as follows:
• TEXTERNAL = 35 °C. This is typical of a maximum system operating environment
• TRISE = 5 °C.
• TAMBIENT = 40 °C (TAMBIENT = TEXTERNAL + TRISE)
Based on the system boundary conditions the designer can select a TAMBIENT and ΨCA
to use in thermal modelling. The assumption of a TAMBIENT has a significant impact on
the required ΨCA needed to meet TTV TCASEMAX at TDP. A system that can deliver lower
assumed TAMBIENT can utilize a design with a higher ΨCA, which can have a lower cost.
Note:
If the assumed TAMBIENT is inappropriate for the intended system environment, the
thermal solution performance may not be sufficient to meet the product requirements.
The results may be excessive noise from fans having to operate at a speed higher than
intended. In the worst case this can lead to performance loss with excessive activation
of the Thermal Control Circuit (TCC).
Thermal/Mechanical Specifications and Design Guidelines
69
Sensor Based Thermal Specification Design Guidance
8.3.2
Thermal Design and Modelling
Based on the boundary conditions the designer can now make the design selection of
the thermal solution components. The major components that can be mixed are the
fan, fin geometry, heat pipe or air cooled solid core design. There are cost and acoustic
trade-offs the customer can make.
To aide in the design process Intel provides TTV thermal models. Please consult your
Intel Field Sales Engineer for these tools.
8.3.3
Thermal Solution Validation
8.3.3.1
Test for Compliance to the TTV Thermal Profile
This step is the same as previously suggested for prior products. The thermal solution
is mounted on a test fixture with the TTV and tested at the following conditions:
• TTV is powered to the TDP condition
• Thermal solution fan operating at full speed
• TAMBIENT at the boundary condition from Section 8.3.1
The following data is collected: TTV power, TTV TCASE and TAMBIENT. and used to
calculate ΨCA which is defined as:
ΨCA = (TTV TCASE - TAMBIENT) / Power
This testing is best conducted on a bench to eliminate as many variables as possible
when assessing the thermal solution performance.
8.3.3.2
Thermal Solution Characterization for Fan Speed Control
The final step in thermal solution validation is to establish the thermal solution
performance,ΨCA and acoustics as a function of fan speed. This data is necessary to
allow the fan speed control algorithm developer to program the device. It also is
needed to asses the expected acoustic impact of the processor thermal solution in the
system.
The fan speed control device may modulate the thermal solution fan speed (RPM) by
one of two methods. The first and preferred is pulse width modulation (PWM) signal
compliant to the 4-Wire Pulse Width Modulation (PWM) Controlled Fans specification.
the alternative is varying the input voltage to the fan. As a result the characterization
data needs to also correlate the RPM to PWM or voltage to the thermal solution fan. The
fan speed algorithm developer needs to associate the output command from the fan
speed control device with the required thermal solution performance.
70
Thermal/Mechanical Specifications and Design Guidelines
Sensor Based Thermal Specification Design Guidance
8.4
Fan Speed Control (FSC) Design Process
The next step is to incorporate the thermal solution characterization data into the
algorithms for the device controlling the fans.
As a reminder the requirements are:
• When the DTS value is at or below TCONTROL, the fans can be slowed down – just as
with prior processors.
• When DTS is above TCONTROL, FSC algorithms will use knowledge of TAMBIENT and
ΨCA versus RPM to achieve the necessary level of cooling.
DTS 1.1 provides another option to do fan speed control without the Tambient data.
Refer to Section 8.4.1 for more details. This chapter will discuss two implementations.
The first is a FSC system that is not provided the TAMBIENT information and a FSC
system that is provided data on the current TAMBIENT. Either method will result in a
thermally compliant solution and some acoustic benefit by operating the processor
closer to the thermal profile. But only the TAMBIENT aware FSC system can fully utilize
the specification for optimized acoustic performance.
In the development of the FSC algorithm it should be noted that the TAMBIENT is
expected to change at a significantly slower rate than the DTS value. The DTS value will
be driven by the workload on the processor and the thermal solution will be required to
respond to this much more rapidly than the changes in TAMBIENT.
An additional consideration in establishing the fan speed curves is to account for the
thermal interface material performance degradation over time.
8.4.1
DTS 1.1 A New Fan Speed Control Algorithm without
TAMBIENT Data
In most system designs incorporating processor ambient inlet data in fan speed control
adds design and validation complexity with a possible BOM cost impact to the system.
A new fan speed control methodology is introduced to improve system acoustics
without needing the processor inlet ambient info.
The DTS 1.1 implementation consists of two parts, a ΨCA requirement at Tcontrol and a
ΨCA point at DTS = -1.
The ΨCA point at DTS = -1 defines the minimum ΨCA required at TDP considering the
worst case system design Tambient design point:
ΨCA = (TCASE_max – TAmbient target) / TDP
For example, for a 77W SKU TTV profile , the Tcase max is 72.6 °C and at a worst case
design point of 40 °C local ambient this will result in
ΨCA = (72.6 – 40) / 95 = 0.34 °C/W
Similarly for a system with a design target of 45 °C ambient the ΨCA at DTS = -1 needed
will be 0.29 °C/W
The second point defines the thermal solution performance (ΨCA) at Tcontrol. Table 8-1
lists the required ΨCA for various TDP processors.
Thermal/Mechanical Specifications and Design Guidelines
71
Sensor Based Thermal Specification Design Guidance
These two points define the operational limits for the processor for DTS 1.1
implementation. At TCONTROL the fan speed must be programed such that the resulting
ΨCAis better than or equivalent to the required ΨCA listed in Table 8-1. Similarly the fan
speed should be set at DTS = -1 such that the thermal solution performance is better
than or equivalent to the ΨCArequirements at Tambient_Max. Based on the processor
temperature, the fan speed controller must linearly change the fan speed from
DTS = TCONTROL to DTS = -1 between these points. Figure 8-2 gives a visual
description on DTS 1.1.
Figure 8-2.
DTS 1.1 Definition Points
Table 8-1.
DTS 1.1 Thermal Solution Performance above TCONTROL
ψCA at
DTS =
TCONTROL1,2
ψCA at
DTS = -1 At System
ambient_max= 40 °C
ψCA at
DTS = -1 At System
ambient_max= 45 °C
ψCA at
DTS = -1 At System
ambient_max= 50 °C
87W
0.394
0.179
0.121
0.064
77W
0.564
0.343
0.291
0.238
69W
0.569
0.354
0.300
0.248
65W
0.745
0.239
0.162
0.085
45W
1.165
0.662
0.551
0.440
17W
3.713
1.875
1.625
1.37565W
Processor TDP
Notes:
ΨCA at “DTS = Tcontrol” is applicable to systems that has Internal Trise (Troom temperature to Processor
1.
cooling fan inlet) of less than 10 °C. In case your expected Trise is grater than 10 °C a correction factor
should be used as explained below. For each 1 deggree C Trise above 10 °C, the correction factor CF is
defined as
CF= 1.7 / Processor_TDP
72
Thermal/Mechanical Specifications and Design Guidelines
Sensor Based Thermal Specification Design Guidance
2.
8.5
Example, For A Chassis Trise assumption of 12°C for the processor(77W) with 95W TTV thermal profile
specification.
CF = 1.7/95W = 0.018/C
For Trise > 10 °C
ΨCA at TCONTROL = Value listed in Column_2 - (Trise - 10) * CF
ΨCA = 0.564 - (12 - 10) * 0.18 =0.528°C/W
In this case the fan speed should be set slightly higher equivalent to ΨCA=0.528°C/W
System Validation
System validation should focus on ensuring the fan speed control algorithm is
responding appropriately to the DTS values and TAMBIENT data in the case of DTS 1.0 as
well as any other device being monitored for thermal compliance.
Since the processor thermal solution has already been validated using the TTV to the
thermal specifications at the predicted TAMBIENT, additional TTV based testing in the
chassis is not necessary.
Once the heatsink has been demonstrated to meet the TTV Thermal Profile, it should be
evaluated on a functional system at the boundary conditions.
In the system under test and Power/Thermal Utility Software set to dissipate the TDP
workload confirm the following item:
• Verify if there is TCC activity by instrumenting the PROCHOT# signal from the
processor. TCC activation in functional application testing is unlikely with a
compliant thermal solution. Some very high power applications might activate TCC
for short intervals this is normal.
• Verify fan speed response is within expectations - actual RPM (ΨCA) is consistent
with DTS temperature and TAMBIENT.
• Verify RPM versus PWM command (or voltage) output from the FSC device is within
expectations.
• Perform sensitivity analysis to asses impact on processor thermal solution
performance and acoustics for the following:
— Other fans in the system.
— Other thermal loads in the system.
In the same system under test, run real applications that are representative of the
expected end user usage model and verify the following:
• Verify fan speed response versus expectations as done using Power/Thermal Utility
Software
• Validate system boundary condition assumptions: Trise, venting locations, other
thermal loads and adjust models / design as required.
§§
Thermal/Mechanical Specifications and Design Guidelines
73
Sensor Based Thermal Specification Design Guidance
74
Thermal/Mechanical Specifications and Design Guidelines
Active Tower Thermal Solution
10
Active Tower Thermal Solution
10.1
Introduction
This active tower thermal solution is intended for system integrators who build systems
from baseboards and standard components. This chapter documents baseboard and
system requirements for the cooling solution. It is particularly important for OEMs that
manufacture baseboards for system integrators.
Note:
Unless otherwise noted, all figures in this chapter are dimensioned in millimeters and
inches [in brackets]. Figure 10-1 shows a mechanical representation of the active
tower thermal solution.
Note:
Drawings in this chapter reflect only the specifications on this active tower thermal
solution. These dimensions should not be used as a generic keep-out zone for all
cooling solutions. It is the system designers’ responsibility to consider their proprietary
cooling solution when designing to the required keep-out zone on their system
platforms and chassis. Refer to Chapter 2 for further guidance on keep-in and keep-out
zones.
Figure 10-1. Mechanical Representation of the Solution
Thermal/Mechanical Specifications and Design Guidelines
83
Active Tower Thermal Solution
10.2
Mechanical Specifications
10.2.1
Cooling Solution Dimensions
This section documents the mechanical specifications. Figure 10-1 shows a mechanical
representation of the solution.
Clearance is required around the fan heatsink to ensure unimpeded airflow for proper
cooling. The physical space requirements and dimensions for the processor with
assembled thermal solution are shown in Figure 10-2 (Side View), and Figure 10-3
(Top View). The airspace requirements for this active tower heatsink must also be
incorporated into new baseboard and system designs. Note that some figures have
centerlines shown (marked with alphabetic designations) to clarify relative
dimensioning.
Figure 10-2. Physical Space Requirements for the Solution (Side View)
84
Thermal/Mechanical Specifications and Design Guidelines
Active Tower Thermal Solution
Figure 10-3. Physical Space Requirements for the Solution (Top View)
Note:
10.2.2
Diagram does not show the attached hardware for the clip design and is provided only as a mechanical
representation.
Retention Mechanism and Heatsink Attach Clip Assembly
The thermal solution requires a heatsink attach clip assembly, to secure the processor
and fan heatsink in the baseboard socket.
10.3
Electrical Requirements
10.3.1
Active Tower Heatsink Power Supply
The active tower heatsink requires a +12 V power supply. A fan power cable will be
with solution to draw power from a power header on the baseboard. The power cable
connector and pinout are shown in Figure 10-4. Baseboards must provide a matched
power header to support this. Table 10-1 contains specifications for the input and
output signals at the heatsink connector.
The active tower heatsink outputs a SENSE signal, which is an open- collector output
that pulses at a rate of 2 pulses per fan revolution. A baseboard pull-up resistor
provides VOH to match the system board-mounted fan speed monitor requirements, if
applicable. Use of the SENSE signal is optional. If the SENSE signal is not used, pin 3 of
the connector should be tied to GND.
The fan heatsink receives a PWM signal from the motherboard from the 4th pin of the
connector labeled as CONTROL.
The active tower heatsink requires a constant +12 V supplied to pin 2 and does not
support variable voltage control or 3-pin PWM control.
Thermal/Mechanical Specifications and Design Guidelines
85
Active Tower Thermal Solution
The power header on the baseboard must be positioned to allow the fan power cable to
reach it. The power header identification and location should be documented in the
platform documentation, or on the system board itself. Figure 10-5 shows the location
of the fan power connector relative to the processor socket. The baseboard power
header should be positioned within 110 mm [4.33 inches] from the center of the
processor socket.
Figure 10-4. Fan Power Cable Connector Description
Pin Signal
1
2
3
4
GND
+12 V
SENSE
CONTROL
Straight square pin, 4-pin terminal housing with
polarizing ribs and friction locking ramp.
0.100" pitch, 0.025" square pin width.
Match with straight pin, friction lock header on
mainboard.
1 2 3 4
Table 10-1. Fan Power and Signal Specifications
Description
+12V: 12 volt fan power supply
Min
Typ
Max
Unit
Notes
9.0
12.0
13.8
V
—
1
2, 3
SENSE: SENSE frequency
—
2
—
pulses per fan
revolution
CONTROL
21
25
28
kHz
Notes:
1. Baseboard should pull this pin up to 5 V with a resistor.
2. Open drain type, pulse width modulated.
3. Fan will have pull-up resistor for this signal to maximum of 5.25 V.
Figure 10-5. Baseboard Power Header Placement Relative to Processor Socket
B
R110
[4.33]
C
86
Thermal/Mechanical Specifications and Design Guidelines
Active Tower Thermal Solution
10.4
Cooling Requirements
The processor may be directly cooled with a fan heatsink. However, meeting the
processor's temperature specification is also a function of the thermal design of the
entire system, and ultimately the responsibility of the system integrator. The processor
temperature specification is found in Chapter 6 of this document. The active tower
heatsink is able to keep the processor temperature within the specifications (see
Table 6-1) in chassis that provide good thermal management. For fan heatsink to
operate properly, it is critical that the airflow provided to the heatsink is unimpeded.
Airflow of the fan heatsink is into the front of fan and straight out of the heatsink rear
side. Airspace is required around the fan to ensure that the airflow through the fan
heatsink is not blocked. Blocking the airflow to the fan heatsink reduces the cooling
efficiency and decreases fan life. Figure 10-6 illustrate an acceptable front airspace
clearance for the fan heatsink which is recommended to at least 15 mm or larger. The
air temperature entering the fan should be kept below 40 ºC. Again, meeting the
processor's temperature specification is the responsibility of the system integrator.
Figure 10-6. Active Tower Heatsink Airspace keep-out Requirements (side view)
§
Thermal/Mechanical Specifications and Design Guidelines
87
Active Tower Thermal Solution
88
Thermal/Mechanical Specifications and Design Guidelines
1U Thermal Solution
9
1U Thermal Solution
Note:
The thermal mechanical solution information shown in this document represents the
current state of the data and may be subject to modification.The information
represents design targets, not commitments by Intel.
This chapter describes the overall requirements for enabled thermal solutions designed
to cool the Intel® Xeon® processor E3-1200 v2 product family including critical to
function dimensions, operating environment and validation criteria in 1U server
system. Intel has developed two different collaboration/reference 1U thermal solutions
to meet the cooling needs in this document.
9.1
Performance Targets
Table 9-1 provides boundary conditions and performance targets for a 1U heatsink to
cool processor in 1U server. These values are used to provide guidance for heatsink
design.
Table 9-1.
Boundary Conditions and Performance Targets
Altitude
Thermal
Design
Power
TLA
Ψca2
Air Flow3
Pressure
Drop4
Intel® Xeon® processor
E3-1290 v2 (87W)
Sea Level
87W
40.2 °C
0.176 °C/W
15CFM
0.383
Intel® Xeon® processor
E3-1200 v2 series (77W)
Sea Level
77W
41.0 °C
0.343 °C/W
15CFM
0.383
Intel® Xeon® processor
E3-1200 v2 series (69W)
Sea Level
69W
41.4 °C
0.353 °C/W
15.5CFM
0.383
Intel® Xeon® processor
E3-1285L v2 (65W)
Sea Level
65W
44.0 °C
0.447 °C/W
15CFM
0.383
Intel® Xeon® processor
E3-1265L v2 (45W)
Sea Level
45W
44.6 °C
0.560 °C/W
15CFM
0.383
Intel® Xeon® processor
E3-1220L v2 (17W)
Sea Level
17W
67.2 °C
0.527 °C/W
10CFM
0.123
Processor
Notes:
1.
The values in Table 9-1 are from preliminary design review.
2.
Max target (mean + 3 sigma) for thermal characterization parameter.
3.
Airflow through the heatsink fins with zero bypass.
4.
Max target for pressure drop (dP) measured in inches H2O.
Thermal/Mechanical Specifications and Design Guidelines
75
1U Thermal Solution
9.2
1U Collaboration Heatsink
9.2.1
Heatsink Performance
For 1U collaboration heatsink, see Appendix B for detailed drawings. Figure 9-1 shows
ΨCA and pressure drop for the 1U collaboration heatsink versus the airflow provided.
Best-fit equations are provided to prevent errors associated with reading the graph.
Figure 9-1.
1U Collaboration Heatsink Performance Curves
Collaboration thermal solution Ψca (mean+3sigma) is computed to 0.319 °C/W at the
airflow of 15 CFM. As the Table 9-1 shown when TLA is 40 °C, equation representing
thermal solution of this heatsink is calculated as:
Y=0.319*X+40
where,
Y=Processor TCASE Value (°C)
X=Processor Power Value (W)
Table 9-2 shows thermal solution performance is compliant with Intel® Xeon®
processor E3-1200 v2 series (69W) TTV thermal profile specification. At the TDP (69W)
with local ambient of 40 °C, there is a 3.8 °C margin.
76
Thermal/Mechanical Specifications and Design Guidelines
1U Thermal Solution
Figure 9-2.
1U Collaboration Heatsink Performance Curves
Table 9-2.
Comparison between TTV Thermal Profile and Thermal Solution Performance
for Intel® Xeon® Processor E3-1200 v2 Series (95W) without Intergrated
Graphics
Power (W)
TTV TCASE_MAX
(°C)
Thermal
Solution
TCASE_MAX
(°C)
Power (W)
TTV TCASE_MAX
(°C)
Thermal
Solution
TCASE_MAX (°C)
0
45.1
40.0
50
60.1
56.0
2
45.7
40.6
52
60.7
56.6
4
46.3
41.3
54
61.3
57.2
6
46.9
41.9
56
61.9
57.9
8
47.5
42.6
58
62.5
58.5
10
48.1
43.2
60
63.1
59.1
12
48.7
43.8
62
63.7
59.8
14
49.3
44.5
64
64.3
60.4
16
49.9
45.1
66
64.9
61.1
18
50.5
45.7
68
65.5
61.7
20
51.1
46.4
69
65.8
62.0
22
51.7
47.0
70
66.1
62.3
24
52.3
47.7
72
66.7
63.0
26
52.9
48.3
74
67.3
63.6
28
53.5
48.9
76
67.9
64.2
30
54.1
49.6
78
68.5
64.9
32
54.7
50.2
80
69.1
65.5
34
55.3
50.8
82
69.7
66.2
36
55.9
51.5
84
70.3
66.8
38
56.5
52.1
86
70.9
67.4
40
57.1
52.8
88
71.5
68.1
42
57.7
53.4
90
72.1
68.7
44
58.3
54.0
92
72.7
69.3
46
58.9
54.7
94
73.3
70.0
48
59.5
55.3
95
73.6
70.3
Thermal/Mechanical Specifications and Design Guidelines
77
1U Thermal Solution
9.2.2
Thermal Solution
The collaboration thermal solution consists of two assemblies – heatsink assembly &
back plate.
Heatsink is designed with the Aluminum base and Aluminum stack fin that
volumetrically is 95x95x24.85 mm. The heatpipe technology is used in the heatsink to
improve thermal conduction.
Heatsink back plate is a 1.8 mm thick flat steel plate with threaded studs for heatsink
attach. A clearance hole is located at the center of the heatsink backplate to
accommodate the ILM back plate. An insulator is pre-applied.
Note:
Heatsink back plate herein is only applicable to 1U server. Desktop has a specific
heatsink back plate for its form factor.
9.2.3
Assembly
Figure 9-3.
1U Collaboration Heatsink Assembly
The assembly process for the 1U collaboration heatsink with application of thermal
interface material begins with placing back plate in a fixture. The motherboard is
aligned with fixture.
78
Thermal/Mechanical Specifications and Design Guidelines
1U Thermal Solution
Next is to place the heatsink such that the heatsink fins are parallel to system airflow.
While lowering the heatsink onto the IHS, align the four captive screws of the heatsink
to the four holes of motherboard.
Using a #2 Phillips driver, torque the four captive screws to 8 inch-pounds.
This assembly process is designed to produce a static load compliant with the minimum
preload requirement (26.7 lbf) for the selected TIM and to not exceed the package
design limit (50 lbf).
9.3
1U Reference Heatsink
9.3.1
Heatsink Performance
For 1U reference heatsink, see Appendix B for detailed drawings. Figure 9-4 shows
ΨCAand pressure drop for the 1U reference heatsink versus the airflow provided. Bestfit equations are provided to prevent errors associated with reading the graph.
Figure 9-4.
1U Reference Heatsink Performance Curves
This 1U Reference thermal solution Ψca(mean+3 sigma) is computed to 0.353 °C/W at
the airflow of 15.5 CFM, which has 1.4 °C margin compared with Intel® Xeon®
processor E3-1200 v2 series (69W) TTV thermal profile when TLA is 40 °C.
Thermal/Mechanical Specifications and Design Guidelines
79
1U Thermal Solution
9.3.2
Thermal Solution
The reference thermal solution consists of two assemblies: heatsink assembly & back
plate.
Heatsink is designed with extruded Aluminum, which volumetrically is
95x95x24.85 mm with total 43 fins. Refer to Appendix B for detailed drawings.
Heatsink back plate is a 1.8 mm thick flat steel plate with threaded studs for heatsink
attach. A clearance hole is located at the center of the heatsink backplate to
accommodate the ILM back plate. An insulator is pre-applied.
Note:
Heatsink back plate herein is only applicable to 1U server. Desktop has a specific
heatsink back plate for its form factor.
9.3.3
Assembly
The assembly process is same as the way described in Section 9.2.3 – refer to this
description for more details.
9.4
Geometric Envelope for 1U Thermal Mechanical
Design
Figure 9-5.
KOZ 3-D Model (Top) in 1U Server
9.5mm Maximum
Component Height
(5 places)
1.6mm Maximum
Component Height
(2 places)
2.5mm Maximum
Component Height
(6 places)
80
2.07mm Maximum
Component Height
(1 place)
1.2mm Maximum
Component Height
(1 place)
Thermal/Mechanical Specifications and Design Guidelines
1U Thermal Solution
9.5
Thermal Interface Material
A thermal interface material (TIM) provides conductivity between the IHS and heatsink.
The collaboration thermal solution uses Honeywell PCM45F, which pad size is
35x35 mm.
TIM should be verified to be within its recommended shelf life before use. Surfaces
should be free of foreign materials prior to application of TIM.
9.6
Heat Pipe Thermal Consideration
Figure 9-6 shows the orientation and position of the 1155-land LGA Package TTV die,
this is the same package layout as used in the 1156-land LGA Package TTV. The TTV die
is sized and positioned similar to the production die.
Figure 9-6.
TTV Die Size and Orientation
37.5
Package Centerline
37.5
10.94
Die Centerline
10.94
Drawing Not to Scale
All Dimensions in mm
§
Thermal/Mechanical Specifications and Design Guidelines
81
1U Thermal Solution
82
Thermal/Mechanical Specifications and Design Guidelines
Thermal Solution Quality and Reliability Requirements
11
Thermal Solution Quality and
Reliability Requirements
11.1
Reference Heatsink Thermal Verification
Each motherboard, heatsink and attach combination may vary the mechanical loading
of the component. Based on the end user environment, the user should define the
appropriate reliability test criteria and carefully evaluate the completed assembly prior
to use in high volume. The Intel reference thermal solution will be evaluated to the
boundary conditions in Chapter 5.
The test results, for a number of samples, are reported in terms of a worst-case mean
+ 3σ value for thermal characterization parameter using the TTV.
11.2
Mechanical Environmental Testing
Each motherboard, heatsink and attach combination may vary the mechanical loading
of the component. Based on the end user environment, the user should define the
appropriate reliability test criteria and carefully evaluate the completed assembly prior
to use in high volume. Some general recommendations are shown in Table 11-1.
The Intel reference heatsinks will be tested in an assembled to the LGA1155 socket and
mechanical test package. Details of the Environmental Requirements, and associated
stress tests, can be found in Table 11-1 are based on speculative use condition
assumptions, and are provided as examples only.
Table 11-1. Use Conditions (Board Level)
Test1
Requirement
Pass/Fail Criteria2
Mechanical Shock
3 drops each for + and - directions in each of 3 perpendicular
axes (that is, total 18 drops)
Profile: 50 g, Trapezoidal waveform, 4.3 m/s [170 in/s]
minimum velocity change
Visual Check and Electrical
Functional Test
Random Vibration
Duration: 10 min/axis, 3 axes
Frequency Range: 5 Hz to 500 Hz
5 Hz @ 0.01 g2/Hz to 20 Hz @ 0.02 g2/Hz (slope up)
20 Hz to 500 Hz @ 0.02 g2/Hz (flat)
Power Spectral Density (PSD) Profile: 3.13 g RMS
Visual Check and Electrical
Functional Test
Thermal Cycling
–25 °C to +100 °C;Ramp rate ~ 8C/minute; Cycle time:~30
minutes per cycle for 500 cycles.
Visual Check and Thermal
Performance Test
Notes:
1.
It is recommended that the above tests be performed on a sample size of at least ten assemblies from
multiple lots of material.
2.
Additional pass/fail criteria may be added at the discretion of the user.
Thermal/Mechanical Specifications and Design Guidelines
89
Thermal Solution Quality and Reliability Requirements
11.2.1
Recommended Test Sequence
Each test sequence should start with components (that is, baseboard, heatsink
assembly, and so on) that have not been previously submitted to any reliability testing.
Prior to the mechanical shock & vibration test, the units under test should be
preconditioned for 72 hours at 45 °C. The purpose is to account for load relaxation
during burn-in stage.
The test sequence should always start with a visual inspection after assembly, and
BIOS/Processor/memory test. The stress test should be then followed by a visual
inspection and then BIOS/Processor/memory test.
11.2.2
Post-Test Pass Criteria
The post-test pass criteria are:
1. No significant physical damage to the heatsink and retention hardware.
2. Heatsink remains seated and its bottom remains mated flatly against the IHS
surface. No visible gap between the heatsink base and processor IHS. No visible tilt
of the heatsink with respect to the retention hardware.
3. No signs of physical damage on baseboard surface due to impact of heatsink.
4. No visible physical damage to the processor package.
5. Successful BIOS/Processor/memory test of post-test samples.
6. Thermal compliance testing to demonstrate that the case temperature specification
can be met.
11.2.3
Recommended BIOS/Processor/Memory Test Procedures
This test is to ensure proper operation of the product before and after environmental
stresses, with the thermal mechanical enabling components assembled. The test shall
be conducted on a fully operational baseboard that has not been exposed to any
battery of tests prior to the test being considered.
Testing setup should include the following components, properly assembled and/or
connected:
• Appropriate system baseboard.
• Processor and memory.
• All enabling components, including socket and thermal solution parts.
The pass criterion is that the system under test shall successfully complete the
checking of BIOS, basic processor functions and memory, without any errors. Intel PC
Diags is an example of software that can be used for this test.
90
Thermal/Mechanical Specifications and Design Guidelines
Thermal Solution Quality and Reliability Requirements
11.3
Material and Recycling Requirements
Material shall be resistant to fungal growth. Examples of non-resistant materials
include cellulose materials, animal and vegetable based adhesives, grease, oils, and
many hydrocarbons. Synthetic materials such as PVC formulations, certain
polyurethane compositions (for example, polyester and some polyethers), plastics that
contain organic fillers of laminating materials, paints, and varnishes also are
susceptible to fungal growth. If materials are not fungal growth resistant, then MILSTD-810E, Method 508.4 must be performed to determine material performance.
Material used shall not have deformation or degradation in a temperature life test.
Any plastic component exceeding 25 grams should be recyclable per the European Blue
Angel recycling standards.
The following definitions apply to the use of the terms lead-free, Pb-free, and RoHS
compliant.
Lead-free and Pb-free: Lead has not been intentionally added, but lead may still
exist as an impurity below 1000 ppm.
RoHS compliant: Lead and other materials banned in RoHS Directive are either
(1) below all applicable substance thresholds as proposed by the EU or (2) an
approved/pending exemption applies.
Note:
RoHS implementation details are not fully defined and may change.
§
Thermal/Mechanical Specifications and Design Guidelines
91
Thermal Solution Quality and Reliability Requirements
92
Thermal/Mechanical Specifications and Design Guidelines
Component Suppliers
A
Component Suppliers
Note:
The part numbers listed below identifies the reference components. End-users are
responsible for the verification of the Intel enabled component offerings with the
supplier. These vendors and devices are listed by Intel as a convenience to Intel's
general customer base, but Intel does not make any representations or warranties
whatsoever regarding quality, reliability, functionality, or compatibility of these devices.
Customers are responsible for thermal, mechanical, and environmental validation of
these solutions. This list and/or these devices may be subject to change without notice.
Table A-1.
Collaboration Heatsink Enabled Components-1U Server
Intel® PN
Item
Table A-2.
1U Collaboration heatsink Assembly
E49069-001
SQ41900001
1U Reference Heatsink Assembly
E95498-001
SQ00S00001
Heatsink Back Plate Assembly
E49060-001
P209000071
Reference Heatsink - Workstation
Intel® PN
Delta
Foxconn
Nidec
2011D DHA-A Heatsink
Assembly (Active)
E41759-002
DTC-DAA07
1A01C7T00DHA_XA02
F90T12MS1Z764A01A1
DHX-B Socket H
Compatible Xtreme
Edition
E88216-001
N/A
1A01GQ110-DHX
N/A
Item
Table A-3.
Reference Heatsink Components- Workstation
Item
DHA-A Heatsink Clip
DHA-A Fastener
Table A-4.
AVC
Intel® PN
AVC
E36830-001
A208000389
N/A
N/A
Base: C33389
Cap: C33390
E49060-001
ITW
LGA1155 Socket and ILM Components
Intel® PN
Foxconn
Molex
Tyco
Lotes
E52846-002
PE1155274041-01F
475962032
2069570-1
N/A
LGA115x ILM
without cover
E36142-002
PT44L61-6401
475969911
2013882-3
ACA-ZIF-078Y02
LGA115x ILM with
cover
G11449-002
PT44L61-6411
N/A
2013882-8
ACA-ZIF-078Y28
LGA115x ILM
cover only
G12451-001
012-1000-5377
N/A
1-2134503-1
ACA-ZIF-127P01
LGA115x ILM Back
Plate (with
screws)
E36143-002
PT44P19-6401
475969930
2069838-2
DCA-HSK-144Y09
1U ILM Back Plate
(with Screws)
E66807-001
PT44P18-6401
N/A
N/A
DCA-HSK-157Y03
Item
LGA1155 Socket
Thermal/Mechanical Specifications and Design Guidelines
93
Component Suppliers
Table A-5.
Supplier Contact Information
Supplier
Contact
Phone
Email
AVC
(Asia Vital
Components Co.,
Ltd.)
Kai Chang
+86 755 3366 8888
x63588
kai_chang@avc.com.tw
Delta
Jason Tsai
+1 503 533-8444 x111
+1 503 539-3547
jtsai@delta-corp.com
Foxconn
Julia Jiang
Cary Huang
+1 408 919 6178
+1 512 681 1120
juliaj@foxconn.com
cary.huang@foxconn.com
ITW Fastex
Chak Chakir
+1 512 989 7771
Chak.chakir@itweba.com
Lotes Co., Ltd.
Windy Wong
+1 604 721 1259
windy@lotestech.com
Molex
Carol Liang
+86 21 504 80889 x3301
carol.liang@molex.com
Nidec
Karl Mattson
+1 360 666 2445
karl.mattson@nidec.com
Tyco
Billy Hsieh
+81 44 844 8292
billy.hsieh@tycoelectronics.com
The enabled components may not be currently available from all suppliers. Contact the
supplier directly to verify time of component availability.
§
94
Thermal/Mechanical Specifications and Design Guidelines
Mechanical Drawings
B
Mechanical Drawings
Table B-1 lists the mechanical drawings included in this appendix.
Table B-1.
Mechanical Drawing List
Drawing Description
Socket / Heatsink / ILM keep-out Zone Primary Side for 1U (Top)
Figure Number
Figure B-1
Socket / Heatsink / ILM keep-out Zone Secondary Side for 1U (Bottom)
Figure B-2
Socket / Processor / ILM keep-out Zone Primary Side for 1U (Top)
Figure B-3
Socket / Processor / ILM keep-out Zone Secondary Side for 1U (Bottom)
Figure B-4
1U Collaboration Heatsink Assembly
Figure B-5
1U Collaboration Heatsink
Figure B-6
1U Reference Heatsink Assembly
Figure B-7
1U Reference Heatsink
Figure B-8
1U Heatsink Screw
Figure B-9
Heatsink Compression Spring
Figure B-10
Heatsink Load Cup
Figure B-11
Heatsink Retaining Ring
Figure B-12
Heatsink Backplate Assembly
Figure B-13
Heatsink Backplate
Figure B-14
Heatsink Backplate Insulator
Figure B-15
Heatsink Backplate Stud
Figure B-16
Thermocouple Attach Drawing
Figure B-17
1U ILM Shoulder Screw
Figure B-18
1U ILM Standard 6-32 Thread Fastener
Figure B-19
Thermal/Mechanical Specifications and Design Guidelines
95
Mechanical Drawings
Figure B-1.
96
Socket / Heatsink / ILM keep-out Zone Primary Side for 1U (Top)
Thermal/Mechanical Specifications and Design Guidelines
Mechanical Drawings
Figure B-2.
Socket / Heatsink / ILM keep-out Zone Secondary Side for 1U (Bottom)
Thermal/Mechanical Specifications and Design Guidelines
97
98
3.18
3.18
19.50
C
C
15.92
8.97
9.26
51.00
B
A
SEE DETAIL
2.50
8.12
2
17.00
5
8.97
B
9.26
A
8 MINIMUM OPEN ANGLE TO CLEAR LOAD PLATE
7 MAXIMUM OPEN ANGLE TO OPEN LOAD PLATE
6 MOTHERBOARD BACKSIDE COMPONENT KEEP-IN
(R 65.21 )
130.0
8
(R 46.51 )
5.00
SECTION B-B
( 49.50 )
3X
21.25
42.50
C
LOAD PLATE OPENING
MOTION SPACE
70.37
3.75
CLEARANCE NEEDED
FOR WIRE TRAVEL
SECTION A-A
3X 2.58
NOTES:
1 SOCKET CENTER PLANES ARE REFERENCED FROM GEOMETRIC
CENTER OF SOCKET HOUSING CAVITY FOR CPU PACKAGE (ALIGNS
WITH DATUM REFERENCE GIVEN FOR BOARD COMPONENT KEEP-INS).
2 SOCKET KEEP-IN VOLUME VERTICAL HEIGHT ESTABLISHES LIMIT OF SOCKET
AND CPU PACKAGE ASSEMBLY IN THE SOCKET LOCKED DOWN POSITION.
IT ENCOMPASSES SOCKET AND CPU PACKAGE DIMENSIONAL TOLERANCES
AND DEFLECTION / SHAPE CHANGES DUE TO ILM LOAD.
3. SOCKET KEEP-IN VOLUME ENCOMPASS THE SOCKET NOMINAL VOLUME
AND ALLOWANCES FOR SIZE TOLERANCES. THERMAL/MECHANICAL COMPONENT
DEVELOPERS SHALL DESIGN TO THE OUTSIDE OF SOCKET KEEP IN VOLUME WITH
CLEARANCE MARGINS. SOCKET DEVELOPERS SHALL DESIGN TO THE INSIDE VOLUME.
4.DIMENSIONS ARE IN MILLIMETERS
5 NO COMPONENT BOUNDARY-FINGER ACCESS AREA
1.75
A
4.00
B
40.71
5.50
( 78.25 )
37.54
13.00
6.76
1
MIN LEVER MOTION SPACE
TO OPEN LID
8
MAX LEVER MOTION SPACE
TO LEVER STOP
7
170.0
2.50
( 2.50 )
11.75
LEVER UNLATCHED
POSITION
8.12
3X 6.34
B
2
( 94.76 )
( 37.54 )
( 1.50 )
( 1.50 )
TYP PCB THICKNESS
7.00
7
6.55
4.00
( 15.16 )
49.50
6
B
SCALE:
A1
SIZE
R
2200 MISSION COLLEGE BLVD.
P.O. BOX 58119
SANTA CLARA, CA 95052-8119
78.25
1.000
E21320
DO NOT SCALE DRAWING SHEET 1 OF
DRAWING NUMBER
2
J
REV
LGA1156 & 1155 SOCKET,
ILM & PROCESSOR KEEPIN
PST-TMI
DEPARTMENT
TITLE
27.33
6
19.99
( 42.50 )
SECONDARY SIDE
COMPONENT CLEARANCE
PRIMARY SIDE COMPONENT
CLEARANCE
BOTTOM SIDE
3.75
12.29
18.72
C
( 42.50 )
Figure B-3.
6.76
1.25
TOP SIDE
Mechanical Drawings
Socket / Processor / ILM keep-out Zone Primary Side for 1U (Top)
Thermal/Mechanical Specifications and Design Guidelines
0.00
PIN 1
35.21
40.71
25.81
25.50
C
0.00
18.00
R3.50
TOP SIDE
PCB ILM MOUNTING HOLES
18.00
Thermal/Mechanical Specifications and Design Guidelines
( 47.50 )
3X
5 FINGER ACCESS
COMPONENT KEEPOUT
AREA
B
+0.05
NPTH
-0.03
B C
( 10.50 )
3.80
0.1
6.00
+0.05
-0.03
NO ROUTE ON
PRIMARY & SECONDARY SIDES
3X
4.70 NO ROUTE ON
ALL OTHER LAYERS
COPPER PAD ON PRIMARY SIDE,
NON-GROUNDED.
COPPER PAD CAN INSET MAXIMUM
OF .127MM FROM THE NO ROUTE EDGE
3X
B
25.70
C
ADD SILKSCREEN OUTLINE
ON PCB PRIMARY SIDE
AS SHOWN
TOP SIDE
PCB ILM SILKSCREEN
0.00
23.81
37.31
3.50
SIZE
E21320
DO NOT SCALE DRAWING SHEET 2 OF
DRAWING NUMBER
SCALE: NONE
A1
TOP SIDE VIEW
DETAIL A
( 15.83 )
( 13.75 )
( 11.78 )
10.97
( 6.30 )
8.00
3.50
2
J
REV
( 18.12 )
17.00
Figure B-4.
0.00
LEVER UNLATCHED
Mechanical Drawings
Socket / Processor / ILM keep-out Zone Secondary Side for 1U (Bottom)
99
25.70
100
3
A
5
4
1
SECTION A-A
5
3
2
6
4
3
A
4
3
2
1
1
4
4
4
PART NUMBER
DATE
FINISH
APPROVED BY
MATERIAL
2
DATE
CHECKED BY
-
DESCRIPTION
R
2200 MISSION COLLEGE BLVD.
P.O. BOX 58119
SANTA CLARA, CA 95052-8119
SCALE: 1:1
1
DO NOT SCALE DRAWINGSHEET 1 OF 1
E49069
B
REV
ASSY, HEAT SINK, FOXHOLLOW, 1U
SIZE DRAWING NUMBER
C
TITLE
EASD-SH
DEPARTMENT
PARTS LIST
SEE NOTES
07/15/08
SEE NOTES
DATE
07/15/08
DRAWN BY
JUN LU
JUN LU
DATE
DESIGNED BY
C
D
A
B
THIRD ANGLE PROJECTION
UNLESS OTHERWISE SPECIFIED
INTERPRET DIMENSIONS AND TOLERANCES
IN ACCORDANCE WITH ASME Y14.5M-1994
DIMENSIONS ARE IN INCHES
TOLERANCES:
.X
0.5 Angles
1.0
.XX
0.25
.XXX
0.127
QTY ITEM NO
-
SPRING, COMPRESSION, PRELOAD
RING, RETAINING, 3.2MM GROOVE DIA
CUP, SPRING RETENTION
HEAT SINK, FOXHOLLOW, 1U
SCREW, SHOULDER, M3X0.5, FOXHOLLOW
TIM, 0.25x35x35MM, HONEYWELL
THE MARK CAN BE AN INK MARK, LASER MARK, PUNCH MARK
OR ANY OTHER PERMANENT MARK THAT IS READABLE AT 1.0X
MAGNIFICATION
6. PRESS FIT CUP LIP FLUSH TO TOP SURFACE OF HEAT SINK
7. MINIMUM PUSH OUT FORCE = 30LBF PER CUP
"RECOMMENDED SCREW TORQUE: 8 IN-LBF"
-
APPR
REV
D89882
DATE
09/20/08
07/15/08
1
D89885
D91472
E49059
E50686
PCM-45F
UPDATE
INITIAL RELEASE
SHT.
TOP E49069
5
4
DETAIL A
SCALE 4:1
6
3
1
+0.20
-0.25
B
2
1
E49069
A
SEE DETAIL
0.5
A
1
DESCRIPTION
REVISION HISTORY
NOTES:
1. THIS DRAWING TO BE USED IN CONJUNCTION WITH SUPPLIED 3D DATABASE.
ALL DIMENSIONS AND TOLERENCES ON THIS DRAWING TAKE PRECEDENCE OVER
SUPPLIED DATABASE
2. PRIMARY DIMENSIONS STATED IN MILLINETERS. [BRACKETED] DIMESNIONS
STATED IN INCHS.
3 CRITICAL TO FUNCTION DIMENSION.
4. REMOVE ALL BURRS, SHARP EDGES, GREASES, AND/OR SOLVENTS AFTER MACHINING
AND FIN ASSEMBLY
5 PART NUMBER AND TORGUE SPEC MARK:
PLACE PART NUMBER AND TORGUE SPEC IN ALLOWABLE AREA
EITHER SIDE OF PART WHERE SHOWN. BELOW PART NUMBER CALLOUT,
PLACE THE FOLLOW TEXT:
REV
ZONE
2
DWG. NO
A
B
C
D
4
Figure B-5.
THIS DRAWING CONTAINS INTEL CORPORATION CONFIDENTIAL INFORMATION. IT IS DISCLOSED IN CONFIDENCE AND ITS CONTENTS
MAY NOT BE DISCLOSED, REPRODUCED, DISPLAYED OR MODIFIED, WITHOUT THE PRIOR WRITTEN CONSENT OF INTEL CORPORATION.
Mechanical Drawings
1U Collaboration Heatsink Assembly
Thermal/Mechanical Specifications and Design Guidelines
Thermal/Mechanical Specifications and Design Guidelines
3
24.85
4
4X
2.5
8
0.076
5.5
3
FLATNESS ZONE 6
55.7 0
75
0
-0.4
3
11/01/08
THIRD ANGLE PROJECTION
DATE
FINISH
APPROVED BY
MATERIAL
2
DATE
CHECKED BY
-
SEE NOTES
07/15/08
SEE NOTES
DATE
07/15/08
DRAWN BY
JUN LU
DESCRIPTION
R
2200 MISSION COLLEGE BLVD.
P.O. BOX 58119
SANTA CLARA, CA 95052-8119
SCALE: 1:1
1
DO NOT SCALE DRAWINGSHEET 1 OF 1
E49059
HEAT SINK, FOXHOLLOW, 1U
SIZE DRAWING NUMBER
C
TITLE
EASD-SH
DEPARTMENT
PARTS LIST
C
REV
A
C
JUN LU
DATE
DESIGNED BY
C
D
REV
UNLESS OTHERWISE SPECIFIED
INTERPRET DIMENSIONS AND TOLERANCES
IN ACCORDANCE WITH ASME Y14.5M-1994
DIMENSIONS ARE IN MILLIMETERS
TOLERANCES:
.X
0.5 Angles
1.0
.XX
0.25
.XXX
0.025
-
-
APPR
1
PART NUMBER
TOP E49059
95
HS TOLERANCE UPDATED TO 0/-0.4MM
DATE
09/20/08
07/15/08
SHT.
QTY ITEM NO
0.15 3
0.13 3 BASE THICKNESS
36
C
3
UPDATE
INITIAL RELEASE
1
NOTES:
1. THIS DRAWING TO BE USED IN CONJUNCTION WITH SUPPLIED 3D DATABASE.
ALL DIMENSIONS AND TOLERENCES ON THIS DRAWING TAKE PRECEDENCE OVER
SUPPLIED DATABASE
2. PRIMARY DIMENSIONS STATED IN MILLINETERS.
3 CRITICAL TO FUNCTION DIMENSION
4. FIN PARAMETERS CAN BE DECIDED BASED ON SUPPLIERS'SUGGESTION.
5. REMOVE ALL BURRS, SHARP EDGES, GREASES, AND/OR SOLVENTS AFTER MACHINING
AND FIN ASSEMBLY
6 LOCAL FLATNESS ZONE .076 MM [0.003''] CENTERED ON HEAT SINK PEDESTAL
7. MECHANICAL STITCHING OR CONNECTION ALLOWED ON TOP SURFACE OF HEATSINK TO
INCREASE FIN STRUCTURAL STABILITY. OVERALL FIN HEIGHT MUST STILL BE MAINTAINED.
8. MATERIAL:ALUMINUM 6063-T5
B
A
2
1
DESCRIPTION
REVISION HISTORY
E49059
0.13 3 PEDESTAL
0
-0.06
36
55.7 0
0.15 3
75
3
0
-0.4
95
REV
ZONE
2
DWG. NO
A
B
C
D
4
Figure B-6.
THIS DRAWING CONTAINS INTEL CORPORATION CONFIDENTIAL INFORMATION. IT IS DISCLOSED IN CONFIDENCE AND ITS CONTENTS
MAY NOT BE DISCLOSED, REPRODUCED, DISPLAYED OR MODIFIED, WITHOUT THE PRIOR WRITTEN CONSENT OF INTEL CORPORATION.
Mechanical Drawings
1U Collaboration Heatsink
(
101
Mechanical Drawings
Figure B-7.
102
1U Reference Heatsink Assembly
Thermal/Mechanical Specifications and Design Guidelines
Mechanical Drawings
Figure B-8.
1U Reference Heatsink
Thermal/Mechanical Specifications and Design Guidelines
103
104
3
0.35
+0.05
0
5
SEE DETAIL
A
C
6
3
2X
5
2
5
7
0.32
6
( 5.6 )
0
-0.1
5
7
DATE
DATE
FINISH
CHECKED BY
APPROVED BY
MATERIAL
DESCRIPTION
SCALE: 1:1
2200 MISSION COLLEGE BLVD.
P.O. BOX 58119
SANTA CLARA, CA 95052-8119
E50686
1
DO NOT SCALE DRAWINGSHEET 1 OF 1
SIZE DRAWING NUMBER
C
R
SCALE 5:1
B
REV
SCREW,SHOULDER, M3 X 0.5, FOXHOLLOW
TITLE
EASD-SH
DEPARTMENT
PARTS LIST
SEE NOTES
07/20/08
SEE NOTES
DATE
07/20/08
DRAWN BY
JUN LU
JUN LU
DATE
DESIGNED BY
2
3.9
M3 X 0.5
EXTERNAL THREAD
2.93
0.06 5
MAJOR DIA,
M3 x 0.5
TOLERANCE CLASS 6G
( 14.5 )
2 .00
C
A
B
THIRD ANGLE PROJECTION
UNLESS OTHERWISE SPECIFIED
INTERPRET DIMENSIONS AND TOLERANCES
IN ACCORDANCE WITH ASME Y14.5M-1994
DIMENSIONS ARE IN MILLIMETERS
TOLERANCES:
.X
0.5 Angles
1.0
.XX
0.25
.XXX
0.025
-
SECTION A-A
6 .00
7 .00
7 INSPECT SHAFT DIAMETER IN THESE LOCATIONS
6 PER ASME B18,6,3-1998
PART NUMBER
TOP E50686
0.13
5
6
D
REV
QTY ITEM NO
19.5 0
14.5
11
0 .00
0.13
0.17
3.5 0
4.06
-
1
4
B
CRITICAL INTERFACE FEATURE:
THIS SHOULDER MUST BE SQUARE
SEE DETAIL
A
A
0.72 MIN.
01/19/09
APPR
SHT.
DETAIL C
SCALE 40:1
DETAIL B
SCALE 25:1
DETAIL A
SCALE 15:1
SEE DETAIL
4X
B
2
ADDED MAJOR SCREW DIA AS CTF
UPDATED SHAFT INSPECTION CRITERIA
ADDED NOTE 7
ADDED SHOULDER NOTE
DATE
07/20/08
INITIAL RELEASE
1
NOTES:
1. THIS DRAWING TO BE USED IN CONJUNCTION WITH SUPPLIED 3D DATABASE.
ALL DIMENSIONS AND TOLERENCES ON THIS DRAWING TAKE PRECEDENCE OVER
SUPPLIED DATABASE
2. PRIMARY DIMENSIONS STATED IN MILLINETERS. [BRACKETED] DIMESNIONS
STATED IN INCHS.
3. MATERIAL: 18-8 STAINLESS STEEL: AISI 303, 304, 305, J1S, SUS304
OR EQUIVALENT, MINIMUM TENSILE STRENGTH: 60,000 PSI
4. TORQUE TO FAILURE SHALL BE NOT LESS THEN 20 IN-LBF
5 CRITICAL TO FUNCTION DIMENSION
A
1
DESCRIPTION
REVISION HISTORY
E50686
0.5 X 45
ALL AROUND
0.64
R0.2
TYPE 1. CROSS RECESSED
#2 DRIVER 6
REV
ZONE
2
DWG. NO
A
B
C
D
4
Figure B-9.
THIS DRAWING CONTAINS INTEL CORPORATION CONFIDENTIAL INFORMATION. IT IS DISCLOSED IN CONFIDENCE AND ITS CONTENTS
MAY NOT BE DISCLOSED, REPRODUCED, DISPLAYED OR MODIFIED, WITHOUT THE PRIOR WRITTEN CONSENT OF INTEL CORPORATION.
Mechanical Drawings
1U Heatsink Screw
Thermal/Mechanical Specifications and Design Guidelines
Mechanical Drawings
Figure B-10. Heatsink Compression Spring
Thermal/Mechanical Specifications and Design Guidelines
105
Mechanical Drawings
Figure B-11. Heatsink Load Cup
106
Thermal/Mechanical Specifications and Design Guidelines
Mechanical Drawings
Figure B-12. Heatsink Retaining Ring
Thermal/Mechanical Specifications and Design Guidelines
107
108
3
75
C
4
( 89.25 ) 6
A
5
A
4
75
SECTION A-A
( 74.05 ) 6
( 68.55 ) 6
( 89.25 ) 6
( 92.25 ) 6
3
A
2
1
1
DATE
FINISH
APPROVED BY
MATERIAL
2
DATE
CHECKED BY
-
DESCRIPTION
R
2200 MISSION COLLEGE BLVD.
P.O. BOX 58119
SANTA CLARA, CA 95052-8119
C
SCALE: 1:1
E49060-001
1
DO NOT SCALE DRAWINGSHEET 1 OF 1
SIZE DRAWING NUMBER
C
REV
ASSY, BACK PLATE, HS, FOXHOLLOW
TITLE
EASD-SH
DEPARTMENT
PARTS LIST
SEE NOTES
04/10/08
SEE NOTES
DATE
04/10/08
DRAWN BY
JUN LU
JUN LU
DATE
DESIGNED BY
-
HS BACKPLATE
A
C
THIRD ANGLE PROJECTION
UNLESS OTHERWISE SPECIFIED
INTERPRET DIMENSIONS AND TOLERANCES
IN ACCORDANCE WITH ASME Y14.5M-1994
DIMENSIONS ARE IN MILLIMETERS
TOLERANCES:
.X
0.5 Angles
0.5
.XX
0.25
.XXX
0.025
PART NUMBER
HS BACKPLATE INSULATOR
HS BACKPLATE STANDOFF
4 X ( 3.52 )
C
D
REV
E49062-001
E49058-001
E49063-001
3
-
APPR
1
TOP E49060-001
3
1
3
01/21/09
-TORQUE TO FAILURE > 20 IN-LBF
3
-FAILURE MODES: STUDS MUST NOT SHEAR, DEFORM, STRIP, CRACK, OR TORQUE OUT
BELOW THIS TORQUE LIMIT.
-LIMITS BASED ON A 3 SIGMA DISTRIBUTION
6 CRITICAL TO FUNCTION: NO METAL OF THE FLAT PLATE CAN BE EXPOSED
7. CLEAN AND DEGREASE BACKPLATE ASSEMBLY BEFORE ATTACHING INSULATION
8. AFTER APPLICATION THE INSULATOR MUST BE FREE OF BUBBLES, POCKETS,
GREASED, AND ANY OTHER DEFORMATIONS.
9. PLATING CORROSION REQUIREMENTS:
48 HRS 85 C / 85% HUMIDITY WITH NO VISIBLE CORROSION
-PUSHOUT FORCE > 100LBF
5 HEAT SINK ATTACH STUDS:
4 INSTALL ALL STUDS FLUSH TO THIS SURFACE +0.00 / -0.25
DATE
04/10/08
07/20/08
SHT.
4
DETAIL A
SCALE 8:1
ADDED PLATING CORROSION REQUIREMENT
1
NOTES:
1. THIS DRAWING TO BE USED IN CONJUNCTION WITH SUPPLIED 3D DATABASE.
ALL DIMENSIONS AND TOLERENCES ON THIS DRAWING TAKE PRECEDENCE OVER
SUPPLIED DATABASE
2. PRIMARY DIMENSIONS STATED IN MILLINETERS. [BRACKETED] DIMESNIONS
STATED IN INCHS.
3 CRITICAL TO FUNCTION DIMENSION
C
INITIAL RELEASE
UPDATE
DESCRIPTION
REVISION HISTORY
E49060-001
QTY ITEM NO
A
( 2.03 )
AFTER INSULATOR
APPLICATION
( 60.25 ) 6
3.8
A
SEE DETAIL
4X
( 49.75 ) 6
B
3
A
B
1
REV
2
ZONE
2
DWG. NO
A
B
C
D
4
THIS DRAWING CONTAINS INTEL CORPORATION CONFIDENTIAL INFORMATION. IT IS DISCLOSED IN CONFIDENCE AND ITS CONTENTS
MAY NOT BE DISCLOSED, REPRODUCED, DISPLAYED OR MODIFIED, WITHOUT THE PRIOR WRITTEN CONSENT OF INTEL CORPORATION.
Mechanical Drawings
Figure B-13. Heatsink Backplate Assembly
Thermal/Mechanical Specifications and Design Guidelines
Mechanical Drawings
Figure B-14. Heatsink Backplate
Thermal/Mechanical Specifications and Design Guidelines
109
Mechanical Drawings
Figure B-15. Heatsink Backplate Insulator
110
Thermal/Mechanical Specifications and Design Guidelines
Thermal/Mechanical Specifications and Design Guidelines
3
6
4
6
A
0.05 7
SECTION A-A
3.8
6
5.55
0.13 7
B
C
2
3
ADDED PLATING CORROSION REQUIREMENT
REDEFINE THE HEIGHT OF STUD
INITIAL RELEASE
TOP
THIRD ANGLE PROJECTION
DATE
FINISH
APPROVED BY
MATERIAL
2
DATE
CHECKED BY
-
SEE NOTES
04/10/08
SEE NOTES
DATE
04/10/08
DRAWN BY
JUN LU
DESCRIPTION
SCALE: 1:1
2200 MISSION COLLEGE BLVD.
P.O. BOX 58119
SANTA CLARA, CA 95052-8119
E49063-001
1
DO NOT SCALE DRAWINGSHEET 1 OF 1
SIZE DRAWING NUMBER
C
R
C
REV
STUD, FEMALE, M3X0.5, FOXHOLLOW
TITLE
EASD-SH
DEPARTMENT
PARTS LIST
-
C
D
A
C
JUN LU
DATE
01/21/09
APPR
REV
DESIGNED BY
-
DATE
07/15/08
04/10/08
1
UNLESS OTHERWISE SPECIFIED
INTERPRET DIMENSIONS AND TOLERANCES
IN ACCORDANCE WITH ASME Y14.5M-1994
DIMENSIONS ARE IN MILLIMETERS
TOLERANCES:
.X
0.5 Angles
0.5
.XX
0.25
.XXX
0.025
PART NUMBER
1
SHT.
QTY ITEM NO
6
NOTES:
1. THIS DRAWING TO BE USED IN CONJUNCTION WITH SUPPLIED 3D DATABASE.
ALL DIMENSIONS AND TOLERENCES ON THIS DRAWING TAKE PRECEDENCE
OVER SUPPLIED DATABASE
2. PRIMARY DIMENSIONS STATED IN MILLINETERS. [BRACKETED] DIMESNIONS
STATED IN INCHS.
3. MATERIAL: STEEL, MUST MEET LOAD, TORQUE, AND FAILURE REQUIREMENTS LISTED ON
ASSEMBLY DRAWING
4. FINISH: ZINC OR ELECTROLYTIC NICKEL PLATING PLUS CLEAR CHROMATE PER ASTM B
633 COLORLESS
5. MATERIAL PROPERTIES: YIELD 235 MPA MIN ULTINATE STRENGTH 395 MPA MIN
6 FEATURE DETAIL PER MANUFACTURE SPECS.PRESS FIT FLUSH MOUNT FOR > 100 LBF
PULL OUT, AND >20 IN-LBF TORQUE TO FAILURE.
7 CRITICAL TO FUNCTION DIMENSION
8. PLATING CORROSION REQUIREMENTS:
48 HRS 85 C / 85% HUMIDITY WITH NO VISIBLE CORROSION
A
1
DESCRIPTION
REVISION HISTORY
FOXHOLLOW_THICK_BP_STANDOFF
3
M3 X 0.5 INTERNAL THREAD, THRU
A
REV
ZONE
2
DWG. NO
A
B
C
D
4
THIS DRAWING CONTAINS INTEL CORPORATION CONFIDENTIAL INFORMATION. IT IS DISCLOSED IN CONFIDENCE AND ITS CONTENTS
MAY NOT BE DISCLOSED, REPRODUCED, DISPLAYED OR MODIFIED, WITHOUT THE PRIOR WRITTEN CONSENT OF INTEL CORPORATION.
Mechanical Drawings
Figure B-16. Heatsink Backplate Stud
111
112
A
B
3
A
C
4
B
PACKAGE
CENTER
SECTION A-A
7.
0.381 ±0.038
0.0150 ±0.0015
0.51 ±0.08
0.020 ±0.003
3
FINISH:
UNLESS OTHERWISE SPECIFIED:
DIMENSIONS ARE IN INCHES.
TOLERANCES:
TOL: .X
0.2
ANGLES: 0.5
.XX
0.05
0.001
.XXX
INTERPRET DIM AND TOL PER
ASME Y14.5M-1994.
MATERIAL:
PACKAGE CENTER
REFERENCED FROM
PACKAGE EDGES
PACKAGE
EDGES
NOTES: UNLESS OTHERWISE SPECIFIED
1. NORMAL AND LATERAL LOADS ON THE IHS MUST BE
MINIMIZED DURING MACHINING.
2. MACHINE WITH CLEAN DRY AIR ONLY, NO FLUIDS OR
OILS.
3. ALL MACHINED SURFACES TO BE #32 MILL FINISH OR
BETTER.
4. IHS MATERIAL IS NICKEL PLATED COPPER.
5. CUT DIRECTION/ORIENTATION OF GROOVE IS AS SHOWN.
6. ALL MACHINED EDGES ARE TO BE FREE OF BURRS.
7. THE 0.0150 DEPTH AT THE PACKAGE CENTER IS CRITICAL.
D
A
THIS DRAWING CONTAINS INTEL CORPORATION CONFIDENTIAL INFORMATION. IT IS DISCLOSED
IN CONFIDENCE AND ITS CONTENTS MAY NOT BE DISCLOSED, REPRODUCED, DISPLAYED OR
MODIFIED, WITHOUT THE PRIOR WRITTEN CONSENT OF INTEL CORPORATION.
4
DATE
DATE
CHECKED BY
APPROVED BY
THIRD ANGLE
PROJECTION
DATE
DRAWN BY
2
1
SCALE: 2:1
03
1
DETAIL D
SCALE 15 : 1
5000 W. CHANDLER BLVD.
CHANDLER, ARIZONA 85226
0.25 ±0.05
2X R0.010 ±0.002
NOTE DIRECTION OF MILLED GROOVE
RELATIVE TO ALIGNMENT NOTCHES.
REV.
E38918
1
DO NOT SCALE DRAWING
DRAWING NUMBER
REV
03
SHEET 1 OF 1
LGA 1160 IHS GROOVE FOR SOLDER
THERMOCOUPLE ATTACH
SIZE CAGE CODE
B
TITLE
DEPARTMENT
0.38 ±0.03
0.015 ±0.001
3/04/2008
DATE
DESIGNED BY
SH.
1.02 ±0.25
0.040 ±0.010
0.79 ±0.15
0.031 ±0.006
3/04/2008
DETAIL C
SCALE 15 : 1
DETAIL B
SCALE 10 : 1
DWG. NO.
A
B
Mechanical Drawings
Figure B-17. Thermocouple Attach Drawing
Thermal/Mechanical Specifications and Design Guidelines
Thermal/Mechanical Specifications and Design Guidelines
A
B
C
D
E
F
G
H
8
7
6
5
4
3
2
8
7
6
5
1. THIS DRAWING TO BE USED IN CONJUNCTION WITH THE SUPPLIED 3D
DATABASE FILE. ALL DIMENSIONS AND TOLERANCES ON THIS DRAWING
TAKE PRECEDENCE OVER SUPPLIED FILE.
2. UNLESS OTHERWISE NOTED, TOLERANCES ON DIMENSIONED FEATURES
ARE AS IN TOLERANCE BLOCK.
3 CRITICAL TO FUNCTION (CTF).
4. MATERIAL: LOW CARBON STEEL,
MIN HARDNESS - ROCKEWELL HARDNESS B70.
5. PLATING: 2 MICRON MIN. ELECTROLYTIC "BLACK" NICKEL PLATING.
PROCESS TEST: 48 HRS. 85°
C/85% HUMIDITY WITH NO VISIBLE CORROSION.
6. REMOVE ALL BURRS OR SHARP EDGES AROUND PERIMETER OF PART.
SHARPNESS OF EDGES SUBJECT TO HANDLING ARE REQUIRED TO MEET
UL1439 TEST.
7. BREAK ALL SHARP CORNERS, EDGES, AND BURRS TO 0.10MM MAX.
8. PART SHALL BE DEGREASED AND FREE OF OIL AND DIRT MARKS.
NOTES:
4
+0.2
0
3
45° X 0.15+/- 0.1
0.05
0.35 ± 0.1
45° X
45° X
A
2
A
5.75± 0.05
0.1
7.25± 0.05
THIS DRAWING CONTAINS INTEL CORPORATION CONFIDENTIAL INFORMATION. IT IS DISCLOSED IN CONFIDENCE AND ITS CONTENTS
MAY NOT BE DISCLOSED, REPRODUCED, DISPLAYED OR MODIFIED, WITHOUT THE PRIOR WRITTEN CONSENT OF INTEL CORPORATION.
3
1
3
3
3.8± 0.2
3
6-32 UNC CLASS 2A THREAD
3.25± 0.05
1.35±0.1
6 POINT T-20 DRIVE
HEAD DEPTH 2MM MIN
TOP
PART NUMBER
THIRD ANGLE PROJECTION
D UPDATED TO BLACK NICKEL PLATING
4
FINISH
SEE NOTES
MATERIAL
DATE
SEE NOTES
APPROVED BY
DATE
05/19/08
DATE
05/19/08
DATE
PARTS LIST
SCALE:
A1
SIZE
TITLE
SHT.
REV
D
APPROVED
1
2200 MISSION COLLEGE BLVD.
P.O. BOX 58119
SANTA CLARA, CA 95052-8119
07/06/09
06/10/09
02/20/09
11/01/08
DATE
E49065-001
13
E49065-001
DO NOT SCALE DRAWING SHEET 1 OF
DRAWING NUMBER
1
D
REV
FOXHOLLOW SERVER ILM SHOULDER SCREW
EASD-SH
DEPARTMENT
DESCRIPTION
R
C ADD CTF TO THREAD LENGTH
DECREASE .1MM TO SHOULDER HEIGHT;
B UPDATED PLATING SPEC
3
FOXHOLLOW 1U ILM SHOULDER SCREW
DESIGNED BY
UNLESS OTHERWISE SPECIFIED
INTERPRET DIMENSIONS AND TOLERANCES
JUN LU
IN ACCORDANCE WITH ASME Y14.5M-1994
DRAWN BY
DIMENSIONS ARE IN MILLIMETERS
ALL UNTOLERANCED LINEAR
JUN LU
DIMENSIONS ±0.1
CHECKED BY
ANGLES ±1
QTY ITEM NO
DWG. NO
REVISION HISTORY
DESCRIPTION
A INITIAL RELEASE
REV
2
1
ZONE
A
B
C
D
E
F
G
H
Mechanical Drawings
Figure B-18. 1U ILM Shoulder Screw
113
114
A
B
C
D
E
F
G
H
8
7
6
5
4
3
2
UNLESS OTHERWISE NOTED, TOLERANCES ON DIMENSIONS AND
UNDIMENSIONED FEATURES ARE AS IN TABLE.
CRITICAL TO FUNCTION (CTF)
2.
3
4.
8
+/- 0.25 mm
6
+/- 0.15 mm
1 - 10 mm
7
TOLERANCE
0 - 1 mm
5
4
MAX 2.41
PHYSICAL PAN HEAD HEIGHT
DELETED
8.
FEATURE SIZE
REFERENCE AND UNDIMENSIONED FEATURES MAY BE MODIFIED PER INTEL
APPROVAL.
7.
6.
MATERIAL:
a) LOW CARBON STEEL,
MIN HARDNESS - ROCKWELL HARDNESS B70
b) TENSILE YIELD STRENGTH (ASTM D638) >= 235 MPa
PLATING: 2 MICRON MIN. ELECTROLYTIC "BLACK" NICKEL PLATING.
5.
SHARPNESS OF EDGES SUBJECT TO HANDLING ARE REQUIRED TO MEET UL1439
TEST.
THIS DRAWING IS TO BE USED IN CONJUNCTION WITH THE SUPPLIED 3D
DATABASE FILE. ALL DIMENSIONS AND TOLERANCES ON THIS DRAWING TAKE
PRECEDENCE OVER SUPPLIED FILE.
1.
NOTES:
5.17± 0.2
3
3
2
THIS DRAWING CONTAINS INTEL CORPORATION CONFIDENTIAL INFORMATION. IT IS DISCLOSED IN CONFIDENCE AND ITS CONTENTS
MAY NOT BE DISCLOSED, REPRODUCED, DISPLAYED OR MODIFIED, WITHOUT THE PRIOR WRITTEN CONSENT OF INTEL CORPORATION.
6.86
3
1
6-32 UNC - 2B THREAD
TOP
PART NUMBER
E49066-001
-
THIRD ANGLE PROJECTION
PARTS LIST
DATE
05/20/08
DATE
05/20/08
DATE
FINISH
SEE NOTES
MATERIAL
-
DATE
-
DWG. NO
DESCRIPTION
REVISION HISTORY
R
1
07/06/09
11/01/08
DATE
SHT.
-
E49066-001
DO NOT SCALE DRAWING SHEET 1 OF
DRAWING NUMBER
SCALE: 13
A1
SIZE
1
B
APPR
REV
2200 MISSION COLLEGE BLVD.
P.O. BOX 58119
SANTA CLARA, CA 95052-8119
E49066-001
B
REV
SCR, PAN, T20, 6X32, 5.17MM L
TITLE
EASD-SH
DEPARTMENT
DESCRIPTION
UPDATED TO BLACK NICKEL PLATING
INITIAL RELEASE
SEE NOTES
APPROVED BY
DESIGNED BY
UNLESS OTHERWISE SPECIFIED
INTERPRET DIMENSIONS AND TOLERANCES
JUN LU
IN ACCORDANCE WITH ASME Y14.5M-1994
DRAWN BY
DIMENSIONS ARE IN MILLIMETERS
ALL UNTOLERANCED LINEAR
JUN LU
DIMENSIONS ±0.1
CHECKED BY
ANGLES ±0.5
QTY ITEM NO
6 POINT T-20 TORX DRIVE
RECESS DEPTH 2MM MIN
PARTIAL THREAD TAP IN TOOL RECESS OKAY
B
A
1
2
REV
ZONE
A
B
C
D
E
F
G
H
Mechanical Drawings
Figure B-19. 1U ILM Standard 6-32 Thread Fastener
§
Thermal/Mechanical Specifications and Design Guidelines
Socket Mechanical Drawings
C
Socket Mechanical Drawings
Table C-1 lists the mechanical drawings included in this appendix.
Table C-1.
Mechanical Drawing List
Drawing Description
Figure Number
“Socket Mechanical Drawing (Sheet 1 of 4)”
Figure C-1
“Socket Mechanical Drawing (Sheet 2 of 4)”
Figure C-2
“Socket Mechanical Drawing (Sheet 3 of 4)”
Figure C-3
“Socket Mechanical Drawing (Sheet 4 of 4)”
Figure C-4
Thermal/Mechanical Specifications and Design Guidelines
115
Socket Mechanical Drawings
Figure C-1.
116
Socket Mechanical Drawing (Sheet 1 of 4)
Thermal/Mechanical Specifications and Design Guidelines
Socket Mechanical Drawings
Figure C-2.
Socket Mechanical Drawing (Sheet 2 of 4)
Thermal/Mechanical Specifications and Design Guidelines
117
Socket Mechanical Drawings
Figure C-3.
(
118
Socket Mechanical Drawing (Sheet 3 of 4)
Thermal/Mechanical Specifications and Design Guidelines
Socket Mechanical Drawings
Figure C-4.
Socket Mechanical Drawing (Sheet 4 of 4)
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Thermal/Mechanical Specifications and Design Guidelines
119
Socket Mechanical Drawings
120
Thermal/Mechanical Specifications and Design Guidelines
Package Mechanical Drawings
D
Package Mechanical
Drawings
Table D-1 lists the mechanical drawings included in this appendix.
Table D-1.
Mechanical Drawing List
Drawing Description
Figure Number
“Processor Package Drawing (Sheet 1 of 2)”
Figure D-1
“Processor Package Drawing (Sheet 2of 2)”
Figure D-2
Thermal/Mechanical Specifications and Design Guidelines
121
Package Mechanical Drawings
Figure D-1. Processor Package Drawing (Sheet 1 of 2)
122
Thermal/Mechanical Specifications and Design Guidelines
Package Mechanical Drawings
Figure D-2. Processor Package Drawing (Sheet 2of 2)
.
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Thermal/Mechanical Specifications and Design Guidelines
123
Package Mechanical Drawings
124
Thermal/Mechanical Specifications and Design Guidelines
LGA 115X Processor Tools
E
LGA 115X Processor Tools
There are three specific tools designed to help reduce LGA 115X socket bent contacts.
Two tools are intended to install or remove the Processor, and the third tool is to
removes the PnP cover.
Figure E-1.
LGA 115X Processor Tools
Tool
LGA Processor Insertion /
Removal Tool(Field/Channel Tool)
Stage
LGA Processor Insertion /
Removal Tool and
Stage(Factory Tool)
Socket PnP Cap Removal Tool
Note:
Field / Channel Tool designed for lifetime of approximately ~1-10 cycles, and designed
to eliminate the risk of socket bent contact damage during processor insertion or
removal in the end user environment.
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125
LGA 115X Processor Tools
Table E-1.
Tools Ordering Information
Tool Type
Tool Compatability
G17794 (Tool)
G21825 (Stage)
Factory Tool
Field /
Channel Tool
Socket PnP
Cap Removal
Tool
Tool Order P/N
These tools are
compatible across all
LGA1156, LGA1155
and LGA1150
Versions
G29483 (tool)
G34436 (optional
cover)
G29360
Supplier Info
Monica Chih
Chaun Choung Technology Corp. (CCI)
12F., 123-1, Hsing-De Rd.,
Sanchung City, Taipei, Taiwan. R. O. C
Telephone: +886-2-29952666 ext.1131
Fax:+886-2-29958258
Mobile: +886-935513481
monica_chih@ccic.com.tw
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Thermal/Mechanical Specifications and Design Guidelines
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