Thermal Interface Silicone Rubber

Size: px
Start display at page:

Download "Thermal Interface Silicone Rubber"

Transcription

1 Thermal Interface Silicone Rubber High-hardness Thermal Interface Silicone Rubber Thermal Interface Silicone Soft Pads Double Sided Thermal Interface Silicone Tapes Thermal Interface Silicone Ultra Soft Pads Thermal Interface Phase Change Materials Electromagnetic Noise Suppression and Thermal Interface Silicone Rubber Sheets

2 Shin-Etsu products Effective tools in the quest for cool. products lineup High-hardness Thermal Interface Silicone Rubber P4-9 Thermal Interface Silicone Soft Pads P1-15 Thermal Interface Silicone Ultra Soft Pads P16-2 Electromagnetic Noise Suppression and Thermal Interface Silicone Rubber Sheets P21 Double Sided Thermal Interface Silicone Tapes P22-23 Thermal Interface Phase Change Materials P24-25 How to Read Model Numbers of TC Series Thickness The thickness of the TC Series product is specified by a two digit code corresponding to the thickness in millimeters muliplied by 1. Example Thickness.5mm Thickness 1mm Thickness Grade Form Grade The grade of the TC Series product is classified according to the physical properties of the silicone rubber. Form The form of the TC Series product is shown at the end. High-hardness Thermal Interface Silicone Rubber Example A type EG type Thermal Interface Silicone Soft Pads/Ultra Soft Pads Example HS-1.4 type TXS type Cut sheet models Cap type molded models Tube type molded models For custom-order models, the customer's order number and dimensions can be added. 2

3 Features High-hardness Thermal Interface Silicone Rubber These products have fine electrical properties (electric non-conductivity, etc.) There is a reinforcement type with the Fiberglass or Polyimide film. Not only sheet, but also Cap or Tube shapes. These products can even meet the needs for reduction of the creeping distance of transistors. Nearly all products are UL-certified for flame-retardancy. Can be used in a wide temperature (-4 C to +18 C). Thermal Interface Silicone Soft Pads These products are pliable and capable of close conformity to irregular or complex surfaces. They are easy to apply and remove, and can be used for temporary attachment. Nearly all products are UL-certified for flame-retardancy. Can be used in a wide temperature (-4 C to +18 C). Silicone oil contained in the sheet may come to the surface when the sheet is used. Thermal Interface Silicone Ultra Soft Pads Excellent cost performance and high thermal conductivity. Ultra soft-hardness that makes for good compressibility and a stress-relaxation property that can reduce stress to heat moules. Nearly all products are UL-certified for flame-retardancy. Low specific gravity. Can be used in a wide temperature (TC-SP-1.7, TC-SPA-3., TC-CAS/CAB series: -4 C to +15 C. TC-CAD/CAT-2 series: -4 C to +18 C). Silicone oil contained in the sheet may come to the surface when the sheet is used. Electromagnetic Noise Suppression and Thermal Interface Silicone Rubber Sheets Thermal interface sheets which also shield high frequency noise. Excellent heat resistance and flame retardancy. Excellent workability. The sheets are flexible and easy to cut to shape. Halogen-free, making these sheets eco-friendly. Can be used in a wide temperature range-4 C to +15 C. Silicone oil contained in the sheet may come to the surface when the sheet is used. Double Sided Thermal Interface Silicone Tapes Strong and stable adhesive strength without screws. Thermal resistance is stable across a wide temperature range. Can be applied to wide areas using automated equipment. Thermal Interface Phase Change Materials Phase change materials are high-performance thermal interface sheets that soften with heat. Heat softens the sheet for a better conforming fit, which reduces thermal resistance. The result is superior dissipation of heat. Made of silicone, so they provide long-lasting, dependable performance. Sheets are easy to handle. Reworkable. 3

4 High-hardness Thermal Interface Silicone Rubber Sheet Type General Properties Parameter Test Method Grade TC-A Series TC-CG Series TC-EG Series TC-2A TC-3A TC-45A TC-8A TC-2CG TC-3CG TC-45CG TC-8CG TC-2EG TC-3EG TC-45EG Color Dark blue Light reddish brown Light blue Thickness mm Features General purpose General purpose High thermal conductivity ISO Thermal Conductivity W/m K ASTM E Reinforced layer None Fiberglass Fiberglass Density at 23 C g/cm3 JIS K HardnessDurometer A JIS K Tensile Strength MPa JIS K Tear Strength kn/m JIS K Elongation % 11 1Dielectric Breakdown Voltage1 kv JIS K Dielectric Strength1 kv JIS C Volume Resistivity TΩ m JIS K Dielectric Constant Dielectric Dissipation Factortan 5Hz kHz JIS K MHz Hz kHz JIS K MHz Thermal Resistance TO-3P C/W Shin-Etsu Method4 2Flame-Retardance2UL94 V- V- V- 5 Low-molecular-weight siloxane content ppm 1>D3-1 1>D3-1 1>D3-1 Shin-Etsu Method5 Sheet mm Stock Size Roll AV Type with adhesive on single-sided 4 Thermal ResistanceTO-3P C/W Shin-Etsu Method Flame-Retardance2UL94 V- Stock Size Sheet mm 2949 Roll 32mm5m 32mm25m Depends on the thickness of each product.approved products for UL94 [ File No.E ]. Calculation valuetransistor method: (P.28)Acetone extraction method. Form The TC Series are available in four standard models tailored for use with a variety of transistor types. TC series products can be manufactured to custom shapes and forms upon special request. Contact your local sales representative for details. 4

5 Examples of application TC-BG Series TC-2BG TC-3BG TC-45BG TC-8BG White TC-15CG-5HSV Right reddish brown / Gray TC-15TCI Pink Thermal interface silicone rubber cap High thermal conductivity Fiberglass High insulation Polyimide film Transistor Substrate Cap Heatsink Thermal interface silicone rubber sheet Transistor Heatsink Substrate Sheet Thermal interface silicone rubber tube Not applicable for thin film. Transistor Heatsink Substrate Tube V- V- V- 1>D3-1 1>D mm6m Not specified values V mm5m Not specified values Model TO-22 Model TO-3P Model TO-3PL Model TO-3P2 5

6 Cap Type General Properties Parameter Test Method Grade TC-A-CP Series TC-C-CP Series TC-S2-CP Series TC-3A TC-45A TC-8A TC-3C TC-45C TC-8C TC-3S2 TC-45S2 TC-8S2 Color Dark blue Light reddish brown Brown Wall Thickness mm Features General purpose Medium thermal conductivity High thermal conductivity ISO Thermal Conductivity W/m K ASTM E Density at 23 C g/cm3 JIS K HardnessDurometer A JIS K Tensile Strength MPa JIS K Tear Strength kn/m JIS K Elongation % JIS K Dielectric Breakdown Voltage1 kv JIS K Dielectric Strength1 kv JIS C Volume Resistivity TΩ m JIS K Dielectric Constant Dielectric Dissipation Factortan 5Hz kHz JIS K MHz Hz kHz JIS K MHz Thermal Resistance TO-3P C/W Shin-Etsu Method3 2Flame-Retardance2UL94 V- V- V- 4 Low-molecular-weight siloxane content ppm 1>D3-1 1>D3-1 1>D3-1 Shin-Etsu Method4 Depends on the thickness of each product. Approved products for UL94 [ File No.E ]. Transistor method: (P.28)Acetone extraction method. Not specified values Form Dimensions The cap type products are registered under Japanese Patent No Length Width Wall thickness Thickness Grade TC-3A TC-3C TC-3S2 TC-45A TC-45C TC-45S2 TC-8A TC-8C TC-8S2 Parameter Widthmm Outside dimensions CP-TO CP-TO-3P Lengthmm Thicknessmm CP-TO CP-TO-3P CP-TO CP-TO-3P Wall thickness mm TC series products can be manufactured to custom shapes and forms upon special request. Contact your local sales representative for details. 6

7 High-hardness Thermal Interface Silicone Rubber Tube Type General Properties Parameter Test Method Grade TC-A-KT Series TC-3A TC-45A TC-8A Color Dark blue Wall Thickness mm Features General purpose ISO Thermal Conductivity W/m K ASTM E Density at 23 C g/cm3 JIS K HardnessDurometer A JIS K Tensile Strength MPa JIS K Tear Strength kn/m JIS K Elongation % JIS K Dielectric Breakdown Voltage1 kv JIS K Dielectric Strength1 kv JIS C Volume Resistivity TΩ m JIS K Hz 4.8 Dielectric Constant 1kHz JIS K MHz 4.7 Dielectric Dissipation Factortan 5Hz kHz JIS K MHz Thermal Resistance TO-3P C/W Shin-Etsu Method4 2Flame-Retardance2UL94 V- 5 Low-molecular-weight siloxane content ppm 1>D3-1 Shin-Etsu Method5 Depends on the thickness of each product. Approved products for UL94 [ File No.E ]. Not specified values Test piece: Dumbbell shaped test piece 2.Transistor method: (P.28)Acetone extraction method. Dimensions Form Length Inside diameter Wall thickness TC series products can be manufactured to custom shapes and forms upon special request. Contact your local sales representative for details. Grade TC-3A TC-45A TC-8A Parameter Inside diameter Length Wall thickness mm mm mm KT-9525L KT-953L KT-1725L KT-173L 31 KT-13525L KT-1353L 31 KT-1725L KT-173L 31 KT-13525L KT-1353L 31 KT-1735L KT-1725L KT-173L 31 KT-13525L KT-1353L 31 KT-1735L

8 Data Test condition: 15 C Type Parameter Status Value 2h 5h 1h TC-45A TC-45CG TC-45EG TC-45BG A Hardness Durometer A Thermal Resistance Dielectric Strength Dielectric Breakdown Voltage Tensile Strength A Hardness Durometer A Thermal Resistance Dielectric Strength Dielectric Breakdown Voltage Tensile Strength A Hardness Durometer A Thermal Resistance Dielectric Strength Dielectric Breakdown Voltage Tensile Strength A Hardness Durometer A Thermal Resistance Dielectric Strength Dielectric Breakdown Voltage Tensile Strength C/W kv kv MPa C/W kv kv MPa C/W kv kv MPa C/W kv kv MPa Not specified values 8

9 High-hardness Thermal Interface Silicone Rubber Solvent ResistanceWeight change Solvents Type TC-45A TC-45CG TC-45EG TC-45BG Pure water Ethanol Acetone Toluene Test conditionstest piece2mm x 3mm, Immersion time1 min. in each solvent, Exposure time2 min. at room temperature Torque for thread fastening vs. Thermal Resistance Thermal Resistance C / Torque for thread fasteningkgfcm TC-A TC-CG TC-EG TC-BG Transistor: TO-3P Applied power: 5V x 2A Thickness of test piece:.45 mm 9

10 Thermal Interface Silicone Soft Pads General Properties Parameter Test Method Grade TC-1HSV-1.4 TC-1TXS "1" shows 1. mm in thickness. "1" shows 1. mm in thickness. Color Gray Gray Size mm Structure Single layer Single layer Thickness mm Density at 23 C g/cm3 JIS K Hardness1Asker C Dielectric Breakdown Voltage kv JIS K Dielectric Strength kv JIS C Specific Heat J/g K Calculated Value Thermal Conductivity W/m K ISO ASTM E Thermal Resistance C/W Shin-Etsu Method2 Flame-RetardanceUL94 V- V- 3 Low-molecular-weight siloxane content ppm 26D3-1 24D3-1 Shin-Etsu Method3 HardnessAsker C Measured using 2 overlappingthermal interface silicone soft padsthickness: 6mm. Model heater method: (P.28)Acetone extraction method /-.5, 1.±.15.5±.1, 1.±.15, 1.5±.15 Thickness mm 1.5±.15, 2.±.2, 2.5±.2 2.±.15, 2.5±.2, 3.±.25 3.±.2, 4.±.2, 5.±.3 Grade TC-xxxHSV-1.4 TC-xxxTXS.5mm mm mm mm C/W Thermal Resistance depending on thickness 2.5mm mm mm mm 1.54 Structure Single layer type HSV-1.4 / THS / TXS / TXS2 Series Composite type THE / TXE Series Thermal interface silicone soft pad (Double-sided adhesive) Carrier liner film (Polyethylene) Carrier liner film (PET) Please release the Carrier liner film when using. Adhesive side: Thermal interface silicone soft pad Non adhesive side: Thermal interface silicone rubber Carrier liner film (Polyethylene or Polypropylene) Carrier liner film (PET) 1

11 Examples of application TC-1TXS2 TC-1TXE "1" shows 1. mm in thickness. "1" shows 1. mm in thickness. Gray /Light blue/gray Single layer Composite Heat dissipation of surface mount semiconductor chip Surface mount semiconductor chip Heatsink Substrate Thermal interface silicone soft pad V- V- Heat dissipation of substrate Semiconductor chip Substrate 6D3-1 24D3-1 Not specified values General properties are shown only for the selected representative products /-.5, 1.±.15, 1.5± /-.5, 1.±.15 2.±.15, 2.5±.15, 3.± /-, 2.±.25, 2.5±.25 4.±.15, 5.±.3 3.±.25, 4.±.25, 5.±.3 Thermal interface silicone soft pad Heatsink Not specified values TC-xxxTXS2 TC-xxxTXE Not specified values 11

12 Data TC-HSV-1.4 Series Compressive Load and Compressibility Compressibility% Compressive loadmpa ConditionsCompression rate.5 mm/min. Test Dimensions1 x 1 mm 5HSV-1.4 1HSV-1.4 2HSV-1.4 3HSV-1.4 Compressive Load and Thermal Resistance Thermal Resistance C/W HSV-1.4 2HSV-1.4 1HSV-1.4 5HSV Compressed loadkpa Model Heater:TO-3P Applied Power:28W Contact area:7cm 2 Hardness Change 6 Thermal Resistance Change (15 C) 3. HardnessAsker C Thermal Resistance C/W HSV-1.4 2HSV HSV HSV Aging timeh Number of cycletimes Aging timeh Measured using 2 overlapping padsthickness:6mm Breakdown Voltage Change Breakdown VoltagekV Aging timeh Number of cycletimes Thermal Resistance Change (85 C/85%RH) 3. Thermal Resistance C/W 2.5 3HSV HSV HSV-1.4 5HSV Aging timeh Thickness:1mmPressure rising rate:1kv/s Volume Resistivity Change Volume Resistivity cm 1..E E E E E Aging timeh Number of cycletimes Thermal Resistance Change (-4 C to 125 C) 3. Thermal Resistance C/W 2.5 3HSV HSV HSV HSV Number of cycletimes Thickness:1mmCharging voltage:5v 12

13 Thermal Interface Silicone Soft Pads TC-TXS Series Compressive Load and Compressibility Compressibility% Compressive loadmpa ConditionsCompression rate.5 mm/min. Test Dimensions1 x 1 mm 5TXS 1TXS 2TXS 3TXS 4TXS 5TXS Compressive Load and Thermal Resistance 3. Thermal Resistance C/W TXS 4TXS 3TXS 2TXS 1TXS 5TXS Compressed loadkpa Model Heater:TO-3P Applied Power:28W Contact area:7cm 2 Hardness Change 8 Thermal Resistance Change (15 C) 1.2 HardnessAsker C Thermal Resistance C/W 1. 3TXS.8 2TXS.6 1TXS.4 5TXS Aging timeh Number of cycletimes Aging timeh Measured using 2 overlapping padsthickness:6mm Breakdown Voltage Change Breakdown VoltagekV Aging timeh Number of cycletimes Thermal Resistance Change (85 C/85%RH) 1.2 Thermal Resistance C/W 1. 3TXS.8 2TXS.6.4 1TXS 5TXS Aging timeh Thickness:1mmPressure rising rate:1kv/s Volume Resistivity Change Volume Resistivity cm 1..E E E E E Aging timeh Number of cycletimes Thermal Resistance Change (-4 C to 125 C) 1.2 Thermal Resistance C/W 1. 3TXS.8 2TXS.6.4 1TXS 5TXS Number of cycletimes Thickness:1mmCharging voltage:5v 13

14 TC-TXS2 Series Compressive Load and Compressibility Compressibility% TXS2 1TXS2 2TXS2 3TXS2 4TXS2 5TXS Compressive loadmpa Conditions: Compression rate:.5mm/min Test Dimention:12.7mm Compressive Load and Thermal Resistance Thermal Resistance C/W TXS2 4TXS2 1. 3TXS2 2TXS2.5 1TXS2 5TXS Compressed loadkpa Model Heater:TO-3P Applied Power:28W Contact area:7cm 2 Compressed load:29.4kpa=3g/cm 2 Hardness Change 8 Thermal Resistance Change (15 C) 1.2 HardnessAsker C Thermal Resistance C/W TXS2 2TXS2 1TXS2 5TXS Aging timeh Number of cycletimes Aging timeh Measured using 2 overlapping padsthickness:6mm Breakdown Voltage Change Breakdown VoltagekV Aging timeh Number of cycletimes Thermal Resistance Change (85 C/85%RH) 1.2 Thermal Resistance C/W 1. 3TXS2.8 2TXS TXS2 5TXS Aging timeh Thickness:1mmPressure rising rate:1kv/s Volume Resistivity Change 1..E+13 Volume Resistivity cm 1..E E E+1 1..E Aging timeh Number of cycletimes Thermal Resistance Change (-4 C to 125 C) 1.2 Thermal Resistance C/W 1. 3TXS2.8 2TXS TXS2 5TXS Number of cycletimes Thickness:1mmCharging voltage:5v 14

15 Thermal Interface Silicone Soft Pads TC-TXE Series Compressive Load and Compressibility Compressibility% Compressive loadmpa ConditionsCompression rate.5 mm/min. Test Dimensions1 x 1 mm 5TXE 1TXE 2TXE 3TXE 4TXE 5TXE Compressive Load and Thermal Resistance Thermal Resistance C/W TXE 4TXE 3TXE 2TXE 1TXE 5TXE Compressed loadkpa Model Heater:TO-3P Applied Power:28W Contact area:7cm 2 Hardness Change 6 Thermal Resistance Change (15 C) 1.2 HardnessAsker C Thermal Resistance C/W TXE 2TXE.6 1TXE.4 5TXE Aging timeh Number of cycletimes Aging timeh Measured using 2 overlapping padsthickness:6mm Breakdown Voltage Change Breakdown VoltagekV Aging timeh Number of cycletimes Thermal Resistance Change (85 C/85%RH) 1.2 Thermal Resistance C/W TXE 2TXE.6 1TXE.4 5TXE Aging timeh Thickness:1mmPressure rising rate:1kv/s Volume Resistivity Change Volume Resistivity cm 1..E E E E E Aging timeh Number of cycletimes Thermal Resistance Change (-4 C to 125 C) 1.2 Thermal Resistance C/W 1. 3TXE.8 2TXE.6.4 1TXE 5TXE Number of cycletimes Thickness:1mmCharging voltage:5v 15

16 Thermal Interface Silicone Ultra Soft Pads General Properties Parameter Test Method Grade TC-1SP-1.7 TC-1SPA-3. "1" shows 1. mm in thickness. "1" shows 1. mm in thickness. Color Gray/Reddish brown Gray Size mm Structure Composite Single layer Thickness mm Density at 23 C g/cm3 JIS K Hardness1Asker C 2 4 Dielectric Breakdown Voltage kv JIS K Dielectric Strength kv JIS C Specific Heat J/g K Calculated Value Thermal Conductivity W/m K ISO ASTM E Thermal Resistance C/W Shin-Etsu Method2 Flame-RetardanceUL94 V- V- 3 Low-molecular-weight siloxane content ppm 2D3-1 2D3-1 Shin-Etsu Method3 HardnessAsker C Measured using 2 overlapping thermal interface silicone ultra soft padsthickness: 6mm. Model heater method: (P.28)Acetone extraction method..5±.1, Thickness mm.5±.1, 1.±.15, 1.5±.2, 2.±.25, 2.5±.25, 3.±.25, 4.±.25, 5.±.3 1.±.15, 1.5±.15, 2.±.15, 2.5±.2, 3.±.25 Grade TC-xxxSP-1.7 TC-xxxSPA-3..5mm mm mm mm C/W Thermal Resistance depending on thickness 2.5mm mm mm mm 2.72 Structure Single layer type SPA-3.CAS / CAB / CAD / CAT-2 Series Composite type SP-1.7 Series Thermal interface silicone ultra soft pad (Double-sided adhesive) Carrier liner film (Polyethylene) Carrier liner film (PET) Please release the Carrier liner film when using. Adhesive side: Thermal interface silicone ultra soft pad Carrier liner film (PET) Non adhesive side: Thermal interface silicone sheet rainforced with glass fiber 16

17 TC-1CAS-3 TC-2CAS-1 TC-1CAB-3 TC-2CAB-1 TC-1CAD-3 TC-2CAD-1 TC-1CAT-2 1 shows thickness. 2 shows thickness. 1 shows thickness. 2 shows thickness. 1 shows thickness. 2 shows thickness. "1" shows 1. mm in thickness. Dark gray Pink Light reddish purple Gray Single layer Single layer Single layer Single layer V- V- V- V- V- V- V- 24D3-1 22D3-1 18D3-1 26D3-1 General properties are shown only for the selected representative products. Not specified values.5±.1, 1.± ±.15, 2.±.2, 2.5±.2, 3.±.25, 4.±.3, 5.±.3, 6.±.5, 7.±.5, 8.±.5, 9.±.5, 1.±.7.5±.1, 1.± ±.15, 2.±.2, 2.5±.2, 3.±.25, 4.±.3, 5.±.3.5±.1, 1.± ±.15, 2.±.2, 2.5±.2, 3.±.25, 4.±.3, 5.±.3.5±.1, 1.±.15, 1.5±.15, 2.±.2, 2.5±.2, 3.±.25, 4.±.3, 5.±.3 Not specified values TC-xxxCAS-3 TC-xxxCAS-1 TC-xxxCAB-3 TC-xxxCAB-1 TC-xxxCAD-3 TC-xxxCAD-1 TC-xxxCAT Not specified values 17

18 Data TC-SP-1.7 Series Compressive Load and Compressibility Compressibility% Compressive loadmpa ConditionsCompression rate.5 mm/min. Test Dimensions1 x 1 mm 5SP-1.7 1SP-1.7 2SP-1.7 3SP-1.7 4SP-1.7 5SP-1.7 Compressive Load and Thermal Resistance Thermal Resistance C/W SP-1.7 4SP-1.7 3SP-1.7 2SP-1.7 1SP-1.7 5SP Compressed loadkpa Model Heater:TO-3P Applied Power:28W Contact area:7cm 2 Hardness Change 12 Thermal Resistance Change (15 C) 2.5 HardnessAsker C Thermal Resistance C/W 2. 3SP-1.7 2SP SP SP Aging timeh Number of cycletimes Aging timeh Measured using 2 overlapping padsthickness:6mm Breakdown Voltage Change Breakdown VoltagekV Aging timeh Number of cycletimes Thermal Resistance Change (85 C/85%RH) 2.5 Thermal Resistance C/W 3SP SP SP SP Aging timeh Thickness:1mmPressure rising rate:1kv/s Volume Resistivity Change Volume Resistivity cm 1..E E E E E Aging timeh Number of cycletimes Thermal Resistance Change (-4 C to 125 C) 2.5 Thermal Resistance C/W 3SP SP SP SP Number of cycletimes Thickness:1mmCharging voltage:5v 18

19 Thermal Interface Silicone Ultra Soft Pads TC-SPA-3. Series Compressive Load and Compressibility 7 Compressibility% SPA-3. 1SPA-3. 15SPA-3. 2SPA-3. 25SPA-3. 3SPA Compressive loadmpa Conditions: Compression rate:.5mm/min. Test Dimensions12.7mm Compressive Load and Thermal Resistance 3. Thermal Resistance C/W SPA-3. 2SPA-3. 1SPA-3. 5SPA Compressed loadkpa Model Heater:TO-3P Applied Power:28W Contact area:7cm 2 Compressed load:29.4kpa=3g/cm 2 Hardness Change 16 Thermal Resistance Change (15 C) 1.2 HardnessAsker C Thermal Resistance C/W SPA-3. 2SPA-3. 1SPA SPA Aging timeh Number of cycletimes Aging timeh Measured using 2 overlapping padsthickness:6mm Model Heater:TO-3P Applied Power:28W Contact area:7cm 2 Compressed load:29.4kpa=3g/cm 2 Thermal Resistance Change (85 C/85%RH) Thermal Resistance C/W Aging timeh 3SPA-3. 2SPA-3. 1SPA-3. 5SPA-3. Model Heater:TO-3P Applied Power:28W Contact area:7cm 2 Compressed load:29.4kpa=3g/cm 2 Thermal Resistance Change (-4 C to 125 C) Thermal Resistance C/W Number of cycletimes 3SPA-3. 2SPA-3. 1SPA-3. 5SPA-3. Model Heater:TO-3P Applied Power:28W Contact area:7cm 2 Compressed load:29.4kpa=3g/cm 2 TC-CAS-1 Series Compression Property 7 Hardness Change 6 Compressibility% CAS-1 3CAS-1 HardnessAsker C Stress Rate of compression:.5mm/min. Test Dimensions12.7mm Aging timeh Number of cycletimes Measured using 2 overlapping padsthickness:6mm 19

20 Thermal Interface Silicone Ultra Soft Pads TC-CAB-1 Series Compression Property 7 Hardness Change 6 Compressibility% CAB-1 3CAB-1 HardnessAsker C Stress Rate of compression:.5mm/min. Test Dimensions12.7mm Aging timeh Number of cycletimes Measured using 2 overlapping padsthickness:6mm TC-CAD-1 Series Compression Property 7 Hardness Change 6 Compressibility% CAD-1 3CAD-1 HardnessAsker C Stress Rate of compression:.5mm/min. Test Dimensions12.7mm Aging timeh Number of cycletimes Measured using 2 overlapping padsthickness:6mm TC-CAT-2 Series Compression Property 7 Hardness Change 6 Compressibility% CAT-2 1CAT-2 2CAT-2 3CAT-2 HardnessAsker C Stress Rate of compression:.5mm/min. Test Dimensions12.7mm Aging timeh Number of cycletimes Measured using 2 overlapping padsthickness:6mm Thermal Resistance Change Thermal Resistance C/W Aging timeh Number of cycletimes Breakdown Voltage Change Breakdown VoltagekV Aging timeh Number of cycletimes 2 Model Heater:TO-3P Applied Power:28W Contact area:7cm 2 Compressed load:29.4kpa=3g/cm 2

21 Electromagnetic Noise Suppression and Thermal Interface Silicone Rubber Sheets Thermal interface sheets which also shield high frequency noise. General Properties Parameter Structure 1GHz Magnetic permeability Real part: µ Concentric pipe Composite Imaginary part: µ S-parameter Method 1.4 Temperature Range C -4 to +15 ISO Thermal Conductivity W/m K ASTM E Thermal Resistance C/W.3mm.5mm 1.mm Test Method The Shin-Etsu Method Grade EMI-TC mm.93 Hardness Asker C 8 Density at 23 C g/cm 3 JIS K Flame-RetardanceUL94 V-1V-1 equivalent Thickness mm 1., 2. Examples of application Electromagnetic noise suppression and heat conduction for LSI Heatsink Connector Electromagnetic Noise Suppression and Thermal Interface Silicone Rubber Sheet Electromagnetic noise suppression and heat conduction for flat cable Electromagnetic Noise Suppression and Thermal Interface Silicone Rubber Sheet Flat cable Structure Composite sheet : EMI-TC83 EMI-TC83 Not specified values Thermal interface silicone rubber layer Carrier liner filmpolyethylene Carrier liner film Suppression of electromagnetic interference between devices within chassis Electromagnetic Noise Suppression and Thermal Interface Silicone Rubber Sheet Electromagnetic noise suppression and thermal interface silicone putty layer Please remove the carrier liner when using. Chassis Printed circuit boardpcb Magnetic permeability frequency response 7 Real part 3 Imaginary part Frequency Frequency If considering export these products discrided in this page from Japan, first talk to a Shin-Etsu sales representative. 21

22 Double Sided Thermal Interface Silicone Tapes Thermal interface tape: Single layer, double-sided adhesive. Structure New lineup will include 1 µm and 2 µm thicknesses. Strong and stable adhesive strength without screws. Thermal resistance is stable across a wide temperature range. Can be applied to wide areas using automated equipment. Examples of application Double Sided Thermal Interface Silicone Tape Double sided thermal interface silicone Tape Carrier liner film Heat dissipation of LED substrate Substrate Double Sided Thermal Interface Silicone Tape Steel case Transistor Substrate Sheet Heatsink The way to attach and the way to peel off the film. 1 The way to peel off the transparent film. 2 The way to attach. 1 Bend the orange film side, to release the edge of the transparent film. 2 Pick up the edge of the transparent film and peel off it Attach the edge of a TC-SAS on the object. Bend a TC-SAS not to attach on whale surface. Gradually attach a TC-SAS from end to end. After attach TC-SAS to whale surface of the object, equally press whale surface of TC-SAS by a roll. Defat surface of object by solvents. 3 The easy way to peel off the orange film. 1Attach the tape on the edge of the orange film. 2 Pull the tape. 3The edge area of the orange film is removed. 4Pull the orange film. General Properties Parameter Test Method Grade TC-1SAS TC-2SAS Color White White Matrix Silicone Silicone Thickness µm 1 2 Dielectric Breakdown Voltage kv JIS K Thermal Conductivity W/m K ASTM E Alminum 2Shin-Etsu Method Peeling Strength N/cm 2Shin-Etsu Method Glass epoxy 2Shin-Etsu Method Flammability UL94 V- V- Low-molecular-weight siloxane content ppm 3Shin-Etsu Method 3 1>D3-1 1>D3-1 Sheet size mm 34or 3mm5m 34or 3mm5m Laser flash method: (P.29) Not specified values After sticking a tape on a test plate, then pressed down using a 2 kg roller. After 1 minutes, the tape was then peeled off in the 18-degree direction and measurements taken. (Temp.: 23 C, peeling speed: 3 mm/min) Acetone extraction method. SAS series products can be manufactured to custom shapes and forms upon special request. Contact your local sales representative for details. 22

23 Pressure/time dependency of adhesive strength Sample Size Pressure Time Shear Strength 1sec 27 2kg 1min 45 TC-2SAS 1cm 2 1sec 46 4kg 1min 65 Tape size Sandwich the TC-2SAS sample with two SUS plates, and pressurize with various pressure and time. Afterwards, measure the shear strength. SUS/aluminum plate Shear tool Temperature dependency of adhesive strength Shear StrengthN/cm TC-2SAS Acrylic tapecompetitor Temperature C Tape size Sandwich a tape with two aluminum plates, and pressurize using a 2kg roller. After 6 minutes, measure the shear strength under several temperature conditions. Tape Shear Strength after aging Shear StrengthN/cm Aging timeh Number of cycletimes 1. Sandwich the TC-2SAS sample (1 x 1 mm size) with aluminum plates. 2. Press the sample with 2 psi clips. Spacers are inserted to ensure uniform pressure (Press condition: 25 C/1h). 3. Remove the spacer and clip, then measure initial shear strength. 4. Put w/o pressure sample into the aging chamber. 5. After aging, measure the shear strength. Thermal Resistance after aging Thermal Resistancecm 2 K/W 8 7 Acrylic tapecompetitor TC-2SAS Aging timeh Thermal Resistancecm 2 K/W Acrylic tapecompetitor TC-2SAS Aging timeh Thermal Resistancecm 2 K/W Acrylic tapecompetitor TC-2SAS Number of cycletimes 1. Sandwich the sample (TC-2SAS) with two pieces of aluminum plates. 2. Press the sample with 2 psi clips. Spacers are inserted to ensure uniform pressure (Press condition: 25 C/1h). 3. Measure the thermal resistance with laser flash method ( h). 4. Press the sample with clip again. Put sample into the aging chamber. 5. After aging, measure the thermal resistance with Laser Flash method. 23

24 Thermal Interface Phase Change Materials Phase change materials are high-performance thermal interface sheets that soften with heat. Heat softens the sheet for a better conforming fit, which reduces thermal resistance. The result is superior dissipation of heat. Non-silicone phase-change products can t compete in terms of long-term reliability under high temperature. Superior heat-dissipating effect Sheets compress easily to a fraction of their initial thickness, so they act to level multiple chips of different heights. (Developed for next-generation CPUs) The layer thins under compression, resulting in lower thermal resistance. Examples of application Heat dissipation of surface mount semiconductor chip Heatsink Before Phase-change After Phase-change Surface mount semiconductor chip Substrate Thermal interface Phase Change Material Heatsink Phase Change Material Heat Source Improving close contact reduces thermal resistance. Sheets transfer easily, making them easy to stick on. Transfer Method Position a PCS-LT sheet (with tab attached) on top of the heat sink. Apply pressure over the entire surface using the fingers or a roller (pressure: 2-3 psi). Use a spatula or similar tool to smooth down the upper left part of the PCS-LT sheet (pressure: 5-1 psi) Pull the tab firmly to remove. 1 psi = kpa Resists pump-out. Shin-Etsu PCM (after 25 cycles) Olefin type Initial size Oven-heated to 7 C for 1 h + 25 cycles Oven-heated to 7 C for one hour only. General Properties Parameter Test Method Grade PCS-LT-3 PCS-CR-1 Color Gray White Initial Thickness µm Thickness after heat / compression 1 µm Micro gauge 28 1 Density at 25 C JIS K Dielectric Breakdown Voltage kv/mm 8. Softening Point C Shin-Etsu Method Thermal Conductivity W/m K ASTM E Thermal Resistance cm 2 K/W ASTM E Sheet size mm After 1 hour compression, 2 psi/1 C. Not specified values Laser flash method: (P.29) 24

25 Data Pressure-Dependence of Thickness (7 C/1h) 5 Bond Line Thicknessµm Test Method Thickness / Thermal Resistance after aging Observations Pressurepsi PCS-LT-3 Thicknessµm PCS-LT Aging timeh Thicknessµm PCS-LT Aging timeh Thicknessµm PCS-LT Number of cycletimes Pressure-Dependence of Thermal Resistance (7 C/1h) Thermal Resistancemm 2 K/W Pressurepsi PCS-LT-3 1. The sheet is transferred to an aluminum plate used for the laser flash test. 2. Another aluminum plate is placed on the top, sandwiching the sample. Spacers are inserted to ensure uniform pressure. 3. Pressure is applied with clips. 4. This unit is heated in a 7 C oven for 1 hour. 5. The unit is taken from the oven, and a microgauge used to measure the thickness of the sample after compression. Its thermal resistance is again measured using the laser flash method. Thermal Resistancemm 2 K/W Thermal Resistancemm 2 K/W Thermal Resistancemm 2 K/W PCS-LT Aging timeh PCS-LT Aging timeh PCS-LT Number of cycletimes 1. PCS-LT series can work without deterioration in extremely severe condition like 15 C/15hrs because PCS-LT series are silicone-based phase change material. 2. In addition, PCS-LT series are excellent also in anti pumping-out properties. In a heat cycle condition (-4 C125 C/1 cycle), the increasing of thermal resistance is not observed at all. 3. The tendency for thermal resistance to decrease after aging was observed. It is surmised that the contact condition of PCS-LT and aluminum plate improved by aging, as a result, thermal resistance could be decreased. 25

26 Measuring and Test Methods Thermal Interface Silicone Rubber Dielectric Breakdown Voltage/Dielectric Breakdown Strength A test sample is inserted between two 25 mm diameter electrodes and immersed in insulating oil. An alternating current is applied, and the voltage is steadily increased at a rate of 1 kv/sec. The minimum voltage necessary to cause dielectric breakdown is measured, and this is considered the dielectric breakdown voltage. The dielectric breakdown voltage of a test sample sheet (thickness: mm) was measured, and this value divided by the thickness of the sample is considered the dielectric breakdown strength. Measured in accordance with JIS K 6249 Dielectric breakdown strength (kv/mm) Dielectric breakdown voltage as measured (kv) Thickness of test sample (mm) Dielectric Strength A test sample is inserted between two 25 mm diameter electrodes and immersed in insulating oil. A constant voltage is applied for 2 seconds to test dielectric breakdown of the test sample. Voltage is increased in stages, and the maximum voltage before dielectric breakdown is measured. This value is considered the dielectric strength. Measured in accordance with JIS C 211. Upper electrode 25 mm Test piece Insulating oil Lower electrode Flame-Retardancy The test piece (width: 13 mm; length: 125 mm) is positioned vertically, and the lower edge is exposed to a 2 mm flame for 1 seconds. The piece is then removed from the flame and afterflame time (t 1 ) is measured. After burning stops, the flame is applied again, and afterflame time (t 2 ) plus afterglow time (t 3 ) is measured again in the same manner. A set of five specimens is to be tested. Criteria Conditions Classification UL94 V- UL94 V-1 1 sec 3 sec Total flame time t 1 + t 2 for the 5 specimens 5 sec 25 sec 3 sec 6 sec Afterflame time after first flame application Afterflame time after second flame application Afterglow time after second flame application 26

27 Fig. 1: Sample setup Thermal Conductivity Based on ISO A constant current is supplied to a sensor sandwiched between two sheets which measure 6 mm 6 mm 6 mm (as shown in Fig. 1). The sensor is heated to a constant temperature, and the thermal conductivity calculated from the temperature increase of the sensor. The sensor consists of nickel foil in a double spiral pattern, and the temperature change can be measured as the change in electrical resistance of the sensor. Fig. 2 shows the signal obtained from the sensor when constant current is applied. If we scale the horizontal axis (function of time and thermal diffusivity of the sample) of the temperature increase graph (Fig. 2) with D, we see the result in Fig. 3. From equation (1), we know that the slope of this straight line is inversely proportional to the thermal conductivity of the sample. The sensor temperature increase Tave is represented theoretically by the following model. Power applied to the sensor Radius of the sensor Thermal conductivity of the sample Non-dimensional parameter defined by Thermal diffusivity of the sample Measurement time Function of non-dimensional Fig. 2: Time change of applied current and sensor signal Current applied to sensor Time Sensor temperature increase Fig. 3: Correlation between temperature increase curve and D Time Based on ASTM E153 A sample of TC silicone (thickness: 9 mm; diameter: 5 mm) is pres s-fit as shown in the diagram. When the temperature reaches equilibrium, the difference in temperature between the two sides of the silicone and heat flux are measured. Fourier's Law states that Thermal resistance Temperature of the surface of the upper plate Temperature of the surface of the lower plate Heat flux passing through the test piece Therefore Thickness of the test piece Thermal conductivity Total thermal resistance between the test piece and the surface of the plate Measuring equipment and test piece Guarded heater Upper heater Upper platetu Test piece Lower platetm Calorimeter Lower heater Heatsink Compressive Load Guarded heater Spacer Test piece 9mm 5mm 27

28 Thermal Interface Silicone Rubber Thermal Resistance Transistor method:high-hardness Thermal Interface Silicone Rubber A TC test piece (Model TO-3P) is inserted between a heatsink and transistor. The transistor is secured to the heatsink with a 3. mm diameter screw. Power is applied to the transistor for 1 minutes, then the temperatures of the transistor and heatsink are measured. Thermal resistance is calculated according to the following equation. Thermocouple Thermocouple Transistor temperature Heatsink temperature Screw Torque 51kgfcm Applied power 1W Contact area about 2.8 cm2 T1 Transistor Test piece T2 Heatsink Model heater method:thermal Interface Silicone Soft Pads/Ultra Soft Pads A model heater (aluminum case with built-in heater) is used. The test piece is inserted between a heatsink and the model heater, and a designated compressive load is applied. Power is applied for 5 minutes, then the temperatures of the heater and heatsink are measured. Thermal resistance is calculated according to the following equation. Compressive load 3gf/cm 2 Model heater temperature Heatsink temperature Compressive load 3gf/cm2 Applied power 28 Contact area about 7cm2 Test piece Side T1 T2 Model heater Pore of a thermocouple Heatsink Test piece Model heater Heater Length T1 Heatsink Pore of a thermocouple 28

29 Measuring and Test Methods Double Sided Thermal Interface Silicone Tapes Thermal Interface Phase Change Materials Laser flash method (Based on ASTM E1461) Thermal resistance and thermal conductivity were measured by the laser flash method, which is one method of analyzing thermal constants : a pulse laser is used to illuminate and heat one face of the sample. The temperature rise is measured at the opposite face using an infrared sensor, with no contact involved. IR sensor Signal amplifier Software Furnace Furnace power supply Computer + Data acquisition Sample Laser powersupply Plotter printer Laser Experimental result 29

30 Low-molecular-weightLMWSiloxane What is LMW siloxane? The figure shows the chemical formula of low-molecular-weight siloxane, a nonreactive cyclic dimethyl polysiloxane (generally D3-D1), which is volatile and therefore sublimates into the atmosphere both during and after curing. As shown below, LMW siloxane has been reported to cause electrical contact failure under certain conditions. Electrical contact failure It has already been noted that various substances may lead to contact failure. Contact failure may be caused by organic materials such as human body oils and organic gases, or inorganic materials such as hydrogen sulfide and ammonia gas. Electric and electronic manufacturers report that LMW siloxane can cause contact failure in the low-voltage, low-current range. Relationship of load conditions to contact reliability Effects of load on contact reliabilitymicro-relay Load Presence of Si accretion Contact resistance at point of contacty/n 1 DC1V 1mA N No increase measured 2 DC1V 36mA N Occasional increase of several ohms 3 DC3.5V 1mA N No increase measured Mechanisms of contact failure Cyclic dimethyl polysiloxane vapor Electrical spark energy 4 DC5.6V 1mA Y No increase measured 5 DC12V 1mA Y Increase of several ohms, up to infinity DC24V 1mA Y Around 15 times, readings of infinity were seen; at 3 times, all were infinity DC24V 35mA Y Around 3 times, readings of infinity were seen; at 45 times, all were infinity 8 DC24V 1mA Y No increase measured 9 DC24V 2mA Y No increase measured 1 DC24V 1A Y No increase measured 11 DC24V 4A Y No increase measured [Test conditions] Switching frequency1 Hz, temp.room temperature, contact force13 g Presented bythe Institute of Electronics, Information and Communication Engineerscorporation, Yoshimura and Itoh EMC76-41 Feb. 18, Formation of insulators Contact failure Functions as an abrasive Abrasion The prime ingredients of RTV silicone rubber, but the dimethyl polysiloxane derived in the normal manufacturing process does contain ring structures in trace amounts. Because this cyclic dimethyl polysiloxane is nonreactive and volatile, there is sometimes after curing. As shown in the figure above, this sublimated cyclic dimethyl polysiloxane can be a mechanism of contact failure under certain conditions. 3

31 General Features of Silicone Rubber Silicone rubbers are built on a backbone of siloxane bonds (-Si-O-Si-), which exhibit high bonding energy and are highly stable. As a result, silicones have heat resistance, electric non-conductance and chemical stability superior to that of common organic rubbers. Electric Insulation Silicone rubbers are electrically non-conductive and exhibit stable properties over a wide range of temperatures and frequencies. They are highly resistant to corona and arc discharge under high-voltage stress, making them particularly suited for use as an insulating material in high-voltage applications. Flame-Retardancy Silicone rubber exhibits excellent flame resistance. Almost all of Shin-Etsu's thermal interface silicone products have received UL V-/V-1 certification or meet equivalent specifications. The diagram shows a properties comparison between silicone and other rubbers. Heat resistance Chemical stability Resistance to weathering Resistance to chemicals Flame retardancy Electrical properties Resistance to cold Silicone rubber Ethylene-propylene rubber Chloroprene rubber Fluorine rubber Natural rubber Acrylic rubber Handling Precautions Quality, Storage and Handling 1. Products should be stored in a dry place out of direct sunlight. 2. Avoid contact with residual solvents or oils as they may deteriorate the properties of the product. 3. For better results, the substrate surface should be cleaned and dried to remove any dirt, moisture or oils before application. 4. Prior to using the product with a thermal interface grease, test a sample with a small amount to determine compatibility. 31

32 Shin-Etsu Chemical Co.,Ltd. Silicone Division Sales and Marketing Department III 6-1, Ohtemachi 2-chome, Chiyoda-ku, Tokyo, Japan Phone : +81-() Fax : +81-() Shin-Etsu Silicones of America, Inc. 115 Damar Drive, Akron, OH 4435, U.S.A. Phone : Fax : Shin-Etsu do Brasil Representação de Produtos Químicos Ltda. Rua Coronel Oscar Porto, º Andar - 114/115 Paraíso São Paulo - SP BrasilCEP: 43-3 Phone : Fax : Shin-Etsu Silicones Europe B.V. Bolderweg 32, 1332 AV, Almere, The Netherlands Phone : +31-() Fax : +31-() (Products & Servises: Fluid products) Germany Branch Rheingaustrasse , 6523 Wiesbaden, Germany Phone : +49-() Fax : +49-() (Products & Servises: Elastomer products) Shin-Etsu Silicone Taiwan Co., Ltd. Hung Kuo Bldg. 11F-D, No. 167, Tun Hua N. Rd., Taipei, 1549 Taiwan, R.O.C. Phone : +886-() Fax : +886-() Shin-Etsu Silicone Korea Co., Ltd. GT Tower 15F, 411, Seocho-daero, Seocho-gu, Seoul 6615, Korea Phone : +82-() Fax : +82-() Shin-Etsu Singapore Pte. Ltd. 4 Shenton Way, #1-3/6, SGX Centre II, Singapore 6887 Phone : Fax : Shin-Etsu Silicones India Pvt. Ltd. Flat No.712, 7th Floor, 24 Ashoka Estate, Barakhamba Road, New Delhi 111, India Phone : Fax : Shin-Etsu Silicones (Thailand) Ltd. 7th Floor, Harindhorn Tower, 54 North Sathorn Road, Bangkok 15, Thailand Phone : +66-() Fax : +66-() Shin-Etsu Silicone International Trading (Shanghai) Co., Ltd. 29F Junyao International Plaza, No.789, Zhao Jia Bang Road, Shanghai 232, China Phone : +86-() Fax : +86-() Guangzhou Branch B-249, 241, Shine Plaza, 9 Linhexi Road, Tianhe, Guangzhou, Guangdong 5161, China Phone : +86-() Fax : +86-() The data and information presented in this catalog may not be relied upon to represent standard values. Shin-Etsu reserves the right to change such data and information, in whole or in part, in this catalog, including product performance standards and specifications without notice. Users are solely responsible for making preliminary tests to determine the suitability of products for their intended use. Statements concerning possible or suggested uses made herein may not be relied upon, or be construed, as a guaranty of no patent infringement. The silicone products described herein have been designed, manufactured and developed solely for general industrial use only; such silicone products are not designed for, intended for use as, or suitable for, medical, surgical or other particular purposes. Users have the sole responsibility and obligation to determine the suitability of the silicone products described herein for any application, to make preliminary tests, and to confirm the safety of such products for their use. Users must never use the silicone products described herein for the purpose of implantation into the human body and/or injection into humans. Users are solely responsible for exporting or importing the silicone products described herein, and complying with all applicable laws, regulations, and rules relating to the use of such products. Shin-Etsu recommends checking each pertinent country's laws, regulations, and rules in advance, when exporting or importing, and before using the products. Please contact Shin-Etsu before reproducing any part of this catalog. Copyright belongs to Shin-Etsu Chemical Co., Ltd. JCQA-4 JCQA-E-2 JCQA-18 JCQA-E-64 JQA-479 JQA-EM298 The Development and Manufacture of Shin-Etsu Silicones are based on the following registered international quality and environmental management standards. Gunma Complex ISO 91 ISO 141 (JCQA-4 JCQA-E-2) Naoetsu Plant ISO 91 ISO 141 (JCQA-18 JCQA-E-64) Takefu Plant ISO 91 ISO 141 (JQA-479 JQA-EM298) Shin-Etsu Silicone is a registered trademark of Shin-Etsu Chemical Co., Ltd. This is an edited version of the product data released on Dec C Shin-Etsu 211.1/ M.G. Printed in Japan.

電気・電子用RTVシリコーンゴム

電気・電子用RTVシリコーンゴム CONTENTS P3 P4-6 P7-9 P10-11 P12-25 P12-15 P16 P17 P18-19 P20-21 P22-23 P24 P25 P26-27 2 P28 P29 P30 P31 O Si O Si O Si Si O Si O O Si O Si Si O H C H H Si O O Si O O Si H C H H 3 Feature 1 Feature 2 Feature

More information

放熱シリコーンゴム加工品 Thermal Interface Silicone Rubber

放熱シリコーンゴム加工品  Thermal Interface Silicone Rubber Thermal Interface Silicone Rubber High-hardness Thermal Interface Silicone Rubber Thermal Interface Silicone Soft Pads Thermal Interface Silicone Ultra Soft Pads Double Sided Thermal Interface Silicone

More information

電気・電子・一般工業用RTVシリコーンゴム

電気・電子・一般工業用RTVシリコーンゴム Room Temperature Vulcanizing Rubber C O N T E N T S 3 4 6 8 10 1 1 12 13 14 15 16 18 18 19 19 20 22 23 24 25 26 27 28 29 30 31 1 1 5 2 6 3 7 4 8 3 4 5 KE-42 15 50 C 100%RH KE-489 10 5 0 1 2 3 4 50 C 60%RH

More information

Thermal Interface Materials

Thermal Interface Materials Thermal Interface Materials High-hardness Thermal Interface Silicone Rubber Thermal Interface Silicone Soft Pads / Ultra Soft Pads Thermal Interface Phase Change Materials Double Sided Thermal Interface

More information

放熱用シリコーン Thermal Interface Materials

放熱用シリコーン Thermal Interface Materials Thermal Interface Materials High-hardness Thermal Interface Silicone Rubber Thermal Interface Silicone Soft Pads / Ultra Soft Pads Thermal Interface Phase Change Materials Double Sided Thermal Interface

More information

Thermal Interface Materials

Thermal Interface Materials Thermal Interface Materials High-hardness Thermal Interface Silicone Rubbers Low-hardness Thermal Interface Silicone Rubber Sheets Phase-Change Materials Double-Sided Thermal Interface Silicone Tapes Fluid

More information

Huawei G6-L22 QSG-V100R001_02

Huawei  G6-L22 QSG-V100R001_02 G6 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 1 2 3 17 4 5 18 UI 100% 8:08 19 100% 8:08 20 100% 8:08 21 100% 8:08 22 100% 8:08 ********** 23 100% 8:08 Happy birthday! 24 S S 25 100% 8:08 26 http://consumer.huawei.com/jp/

More information

The Effect of the Circumferential Temperature Change on the Change in the Strain Energy of Carbon Steel during the Rotatory Bending Fatigue Test by Ch

The Effect of the Circumferential Temperature Change on the Change in the Strain Energy of Carbon Steel during the Rotatory Bending Fatigue Test by Ch The Effect of the Circumferential Temperature Change on the Change in the Strain Energy of Carbon Steel during the Rotatory Bending Fatigue Test by Chikara MINAMISAWA, Nozomu AOKI (Department of Mechanical

More information

Microsoft Word - PCM TL-Ed.4.4(特定電気用品適合性検査申込のご案内)

Microsoft Word - PCM TL-Ed.4.4(特定電気用品適合性検査申込のご案内) (2017.04 29 36 234 9 1 1. (1) 3 (2) 9 1 2 2. (1) 9 1 1 2 1 2 (2) 1 2 ( PSE-RE-101/205/306/405 2 PSE-RE-201 PSE-RE-301 PSE-RE-401 PSE-RE-302 PSE-RE-202 PSE-RE-303 PSE-RE-402 PSE-RE-203 PSE-RE-304 PSE-RE-403

More information

Safety Performance of Steel Deck Plate (Flat Decks) Used for Concrete Slab Moulding CONTENTS 1. Introduction ---------------------------------------------------------------- (2) 2. Flat Decks ------------------------------------------------------------------

More information

I N S T R U M E N T A T I O N & E L E C T R I C A L E Q U I P M E N T Pressure-resistant gasket type retreat method effective bulk compressibility Fro

I N S T R U M E N T A T I O N & E L E C T R I C A L E Q U I P M E N T Pressure-resistant gasket type retreat method effective bulk compressibility Fro Cable Gland This is the s to use for Cable Wiring in the hazardous location. It is much easier to install and maintenance and modification compared with Conduit Wiring with Sealing Fitting. The Standard

More information

メタルバンドソー

メタルバンドソー Metal Band Saw Blades Tornado Series selection TiCN HSS Co FAX FMX PM VL Selection Chart Selection Chart Solids Selection Teeth 3 note 1) Structurals, Tubing H section steels Light gauge steels Tube 4

More information

Motivation and Purpose There is no definition about whether seatbelt anchorage should be fixed or not. We tested the same test conditions except for t

Motivation and Purpose There is no definition about whether seatbelt anchorage should be fixed or not. We tested the same test conditions except for t Review of Seatbelt Anchorage and Dimensions of Test Bench Seat Cushion JASIC Motivation and Purpose There is no definition about whether seatbelt anchorage should be fixed or not. We tested the same test

More information

Tornado Series selection SW TiCN HSS Co FAX VL PM

Tornado Series selection SW TiCN HSS Co FAX VL PM Metal Band Saw Blades Tornado Series selection SW TiCN HSS Co FAX VL PM Selection Chart Selection Chart Solids 3 Selection Teeth 4 note 1) Structurals, Tubing H section steels Light gauge steels Tube Products

More information

01.eps

01.eps 444 SumiTurn T-REX Tool Holders Cost reduction for copying with unique multiple cornered insert Carbide inserts, cermet inserts and 4 types of breakers are available. Expansion of our popular steel turning

More information

cms.pdf

cms.pdf RoHS compliant INTERNAL STRUTURE FEATURES Part name over Slider Housing Slider contact Fixed contact Terminal pin lick spring Ground terminal Material Steel (SP), Tin-plated Polyamide opper alloy, Gold-plated

More information

MIDI_IO.book

MIDI_IO.book MIDI I/O t Copyright This guide is copyrighted 2002 by Digidesign, a division of Avid Technology, Inc. (hereafter Digidesign ), with all rights reserved. Under copyright laws, this guide may not be duplicated

More information

5 11 3 1....1 2. 5...4 (1)...5...6...7...17...22 (2)...70...71...72...77...82 (3)...85...86...87...92...97 (4)...101...102...103...112...117 (5)...121...122...123...125...128 1. 10 Web Web WG 5 4 5 ²

More information

(43) Vol.33, No.6(1977) T-239 MUTUAL DIFFUSION AND CHANGE OF THE FINE STRUCTURE OF WET SPUN ANTI-PILLING ACRYLIC FIBER DURING COAGULATION, DRAWING AND

(43) Vol.33, No.6(1977) T-239 MUTUAL DIFFUSION AND CHANGE OF THE FINE STRUCTURE OF WET SPUN ANTI-PILLING ACRYLIC FIBER DURING COAGULATION, DRAWING AND (43) Vol.33, No.6(1977) T-239 MUTUAL DIFFUSION AND CHANGE OF THE FINE STRUCTURE OF WET SPUN ANTI-PILLING ACRYLIC FIBER DURING COAGULATION, DRAWING AND DRYING PROCESSES* By Hiroshi Aotani, Katsumi Yamazaki

More information

alternating current component and two transient components. Both transient components are direct currents at starting of the motor and are sinusoidal

alternating current component and two transient components. Both transient components are direct currents at starting of the motor and are sinusoidal Inrush Current of Induction Motor on Applying Electric Power by Takao Itoi Abstract The transient currents flow into the windings of the induction motors when electric sources are suddenly applied to the

More information

音響部品アクセサリ本文(AC06)PDF (Page 16)

音響部品アクセサリ本文(AC06)PDF (Page 16) Guide for Electret Condenser Microphones A microphone as an audio-electric converting device, whose audio pickup section has a structure of a condenser consisting of a diaphragm and a back plate opposite

More information

Continuous Cooling Transformation Diagrams for Welding of Mn-Si Type 2H Steels. Harujiro Sekiguchi and Michio Inagaki Synopsis: The authors performed

Continuous Cooling Transformation Diagrams for Welding of Mn-Si Type 2H Steels. Harujiro Sekiguchi and Michio Inagaki Synopsis: The authors performed Continuous Cooling Transformation Diagrams for Welding of Mn-Si Type 2H Steels. Harujiro Sekiguchi and Michio Inagaki Synopsis: The authors performed a series of researches on continuous cooling transformation

More information

Mikio Yamamoto: Dynamical Measurement of the E-effect in Iron-Cobalt Alloys. The AE-effect (change in Young's modulus of elasticity with magnetization

Mikio Yamamoto: Dynamical Measurement of the E-effect in Iron-Cobalt Alloys. The AE-effect (change in Young's modulus of elasticity with magnetization Mikio Yamamoto: Dynamical Measurement of the E-effect in Iron-Cobalt Alloys. The AE-effect (change in Young's modulus of elasticity with magnetization) in the annealed state of iron-cobalt alloys has been

More information

LC304_manual.ai

LC304_manual.ai Stick Type Electronic Calculator English INDEX Stick Type Electronic Calculator Instruction manual INDEX Disposal of Old Electrical & Electronic Equipment (Applicable in the European Union

More information

1 2 3

1 2 3 INFORMATION FOR THE USER DRILL SELECTION CHART CARBIDE DRILLS NEXUS DRILLS DIAMOND DRILLS VP-GOLD DRILLS TDXL DRILLS EX-GOLD DRILLS V-GOLD DRILLS STEEL FRAME DRILLS HARD DRILLS V-SELECT DRILLS SPECIAL

More information

I N S T R U M E N T A T I O N & E L E C T R I C A L E Q U I P M E N T box number basic type Standard Specification Material of Enclosure Material of F

I N S T R U M E N T A T I O N & E L E C T R I C A L E Q U I P M E N T box number basic type Standard Specification Material of Enclosure Material of F 01 Flameproof Junction Box Junction Box Series Our junction boxes are designed and manufactured based on the Recommended Practices for Explosion-Protected Electrical Installations in General Industries

More information

Journal of Japan Institute of Light Metals, Vol. 58, No. 2 (2008), pp

Journal of Japan Institute of Light Metals, Vol. 58, No. 2 (2008), pp 58 00847 53 * ** ** Journal of Japan Institute of Light Metals, Vol. 58, No. 008, pp. 47 53 Production of aluminum tall container with flange by hydraulic bulging with compression of surrounding material

More information

Ł\”ƒ_−mflF

Ł\”ƒ_−mflF COAXIAL CONNECTORS CAT.NO.COAX-007H.JAN.2018 Adapter for pin/socket conversion of the same series or connection between connectors of different series. Applicable to various series. A wide variety of types

More information

Direct Motor Drive Lead Screws / Resin Lead Screw type RM / RM RM Resin Lead Screw type RM / Resin MoBo 2 MRH 2 Features A 2-phase Stepping Motor is m

Direct Motor Drive Lead Screws / Resin Lead Screw type RM / RM RM Resin Lead Screw type RM / Resin MoBo 2 MRH 2 Features A 2-phase Stepping Motor is m RM Resin Lead Screw typerm / Resin MoBo MRH Features A -phase Stepping Motor is mounted directly onto the shaft end of a Resin Lead Screw, which is multi-use product. Lead Screw Shaft is ideally constructed

More information

Studies of Foot Form for Footwear Design (Part 9) : Characteristics of the Foot Form of Young and Elder Women Based on their Sizes of Ball Joint Girth

Studies of Foot Form for Footwear Design (Part 9) : Characteristics of the Foot Form of Young and Elder Women Based on their Sizes of Ball Joint Girth Studies of Foot Form for Footwear Design (Part 9) : Characteristics of the Foot Form of Young and Elder Women Based on their Sizes of Ball Joint Girth and Foot Breadth Akiko Yamamoto Fukuoka Women's University,

More information

利隆塑料

利隆塑料 w w w. d g p e n g x u. c o m TECHNO PLASTICS GUIDE TECHNO ABS TECHNO MUH TECHNO AES EXCELLOY SANREX Grade Choices Flow Sheet TECHNO MUH TECHNO MUH Molding Condistions Our resin products represented

More information

I N S T R U M E N T A T I O N & E L E C T R I C A L E Q U I P M E N T STW Symbol Symbol otary switch) 05 otary switch Symbol angle of notch 181

I N S T R U M E N T A T I O N & E L E C T R I C A L E Q U I P M E N T STW Symbol Symbol otary switch) 05 otary switch Symbol angle of notch 181 These items are using an aluminum alloy cast, so the weight is corrosion-resistant and excel halo tolerance and is light-weight and it's about 1/3 compared with conventional cast iron and made of steel

More information

WARNING To reduce the risk of fire or electric shock,do not expose this apparatus to rain or moisture. To avoid electrical shock, do not open the cabi

WARNING To reduce the risk of fire or electric shock,do not expose this apparatus to rain or moisture. To avoid electrical shock, do not open the cabi ES-600P Operating Instructions WARNING To reduce the risk of fire or electric shock,do not expose this apparatus to rain or moisture. To avoid electrical shock, do not open the cabinet. Refer servicing

More information

修士論文

修士論文 2004 Decay of timber and its mechanical characteristic 1075015 1075015 1. 1 1. 2. 3. 4. 5. 4.5. 2. JIS 3. 3.1 3.1.1 ( ) ( ) i 3.1.2 3.1.3 10 3.2 ( 3% ) 4 3% ii Decay of timber and its mechanical characteristic

More information

Bull. of Nippon Sport Sci. Univ. 47 (1) Devising musical expression in teaching methods for elementary music An attempt at shared teaching

Bull. of Nippon Sport Sci. Univ. 47 (1) Devising musical expression in teaching methods for elementary music An attempt at shared teaching Bull. of Nippon Sport Sci. Univ. 47 (1) 45 70 2017 Devising musical expression in teaching methods for elementary music An attempt at shared teaching materials for singing and arrangements for piano accompaniment

More information

- 1 -

- 1 - - 1 - - 2 - - 3 - - 4 - - 5 - - 6 - - 7 - - 8 - - 9 - - 10 - - 11 - - 12 - - 13 - - 14 - - 15 - 1 2 1-16 - 2 3 4 5 6 7-17 - 1 2 1 2 3 4-18 - 1 2 3 4 1 2-19 - 1 2 3 1 2-20 - 3 4 5 6 7 1-21 - 1 2 3 4-22

More information

Fig. 3 Flow diagram of image processing. Black rectangle in the photo indicates the processing area (128 x 32 pixels).

Fig. 3 Flow diagram of image processing. Black rectangle in the photo indicates the processing area (128 x 32 pixels). Fig. 1 The scheme of glottal area as a function of time Fig. 3 Flow diagram of image processing. Black rectangle in the photo indicates the processing area (128 x 32 pixels). Fig, 4 Parametric representation

More information

JOURNAL OF THE JAPANESE ASSOCIATION FOR PETROLEUM TECHNOLOGY VOL. 66, NO. 6 (Nov., 2001) (Received August 10, 2001; accepted November 9, 2001) Alterna

JOURNAL OF THE JAPANESE ASSOCIATION FOR PETROLEUM TECHNOLOGY VOL. 66, NO. 6 (Nov., 2001) (Received August 10, 2001; accepted November 9, 2001) Alterna JOURNAL OF THE JAPANESE ASSOCIATION FOR PETROLEUM TECHNOLOGY VOL. 66, NO. 6 (Nov., 2001) (Received August 10, 2001; accepted November 9, 2001) Alternative approach using the Monte Carlo simulation to evaluate

More information

ON A FEW INFLUENCES OF THE DENTAL CARIES IN THE ELEMENTARY SCHOOL PUPIL BY Teruko KASAKURA, Naonobu IWAI, Sachio TAKADA Department of Hygiene, Nippon Dental College (Director: Prof. T. Niwa) The relationship

More information

Influence of Material and Thickness of the Specimen to Stress Separation of an Infrared Stress Image Kenji MACHIDA The thickness dependency of the temperature image obtained by an infrared thermography

More information

Development of Induction and Exhaust Systems for Third-Era Honda Formula One Engines Induction and exhaust systems determine the amount of air intake

Development of Induction and Exhaust Systems for Third-Era Honda Formula One Engines Induction and exhaust systems determine the amount of air intake Development of Induction and Exhaust Systems for Third-Era Honda Formula One Engines Induction and exhaust systems determine the amount of air intake supplied to the engine, and as such are critical elements

More information

*1 *2 *1 JIS A X TEM 950 TEM JIS Development and Research of the Equipment for Conversion to Harmless Substances and Recycle of Asbe

*1 *2 *1 JIS A X TEM 950 TEM JIS Development and Research of the Equipment for Conversion to Harmless Substances and Recycle of Asbe *1 *2 *1 JIS A 14812008X TEM 950 TEM 1 2 3 4 JIS Development and Research of the Equipment for Conversion to Harmless Substances and Recycle of Asbestos with Superheated Steam Part 3 An evaluation with

More information

Options(Unit : mm) Finger guards Model :19-139E :19-139H 53 Surface treatment :Nickel-chrome plating (silver) :Cation electropainting (black) Inlet si

Options(Unit : mm) Finger guards Model :19-139E :19-139H 53 Surface treatment :Nickel-chrome plating (silver) :Cation electropainting (black) Inlet si AC Fan 6mm sq. San Ace 6 28mm thick, 38mm thick General Specifications Material Frame: Aluminum, Impeller:Plastics (Flammability: UL94V-1) Life Expectancy Varies for each model (L1: Survival rate: 9% at

More information

LM35 高精度・摂氏直読温度センサIC

LM35 高精度・摂氏直読温度センサIC Precision Centigrade Temperature Sensors Literature Number: JAJSB56 IC A IC D IC IC ( ) IC ( K) 1/4 55 150 3/4 60 A 0.1 55 150 C 40 110 ( 10 ) TO-46 C CA D TO-92 C IC CA IC 19831026 24120 11800 ds005516

More information

Rate of Oxidation of Liquid Iron by Pure Oxygen Shiro BAN-YA and Jae-Dong SHIM Synopsis: The rate of oxidation of liquid iron by oxygen gas has been s

Rate of Oxidation of Liquid Iron by Pure Oxygen Shiro BAN-YA and Jae-Dong SHIM Synopsis: The rate of oxidation of liquid iron by oxygen gas has been s Rate of Oxidation of Liquid Iron by Pure Oxygen Shiro BAN-YA and Jae-Dong SHIM Synopsis: The rate of oxidation of liquid iron by oxygen gas has been studied using a volume constant technique. The process

More information

Visual Evaluation of Polka-dot Patterns Yoojin LEE and Nobuko NARUSE * Granduate School of Bunka Women's University, and * Faculty of Fashion Science,

Visual Evaluation of Polka-dot Patterns Yoojin LEE and Nobuko NARUSE * Granduate School of Bunka Women's University, and * Faculty of Fashion Science, Visual Evaluation of Polka-dot Patterns Yoojin LEE and Nobuko NARUSE * Granduate School of Bunka Women's University, and * Faculty of Fashion Science, Bunka Women's University, Shibuya-ku, Tokyo 151-8523

More information

The Evaluation on Impact Strength of Structural Elements by Means of Drop Weight Test Elastic Response and Elastic Limit by Hiroshi Maenaka, Member Sh

The Evaluation on Impact Strength of Structural Elements by Means of Drop Weight Test Elastic Response and Elastic Limit by Hiroshi Maenaka, Member Sh The Evaluation on Impact Strength of Structural Elements by Means of Drop Weight Test Elastic Response and Elastic Limit by Hiroshi Maenaka, Member Shigeru Kitamura, Member Masaaki Sakuma Genya Aoki, Member

More information

Fig. 3 Coordinate system and notation Fig. 1 The hydrodynamic force and wave measured system Fig. 2 Apparatus of model testing

Fig. 3 Coordinate system and notation Fig. 1 The hydrodynamic force and wave measured system Fig. 2 Apparatus of model testing The Hydrodynamic Force Acting on the Ship in a Following Sea (1 St Report) Summary by Yutaka Terao, Member Broaching phenomena are most likely to occur in a following sea to relative small and fast craft

More information

アクアEXオイルホールロング(CC2015).indd

アクアEXオイルホールロング(CC2015).indd High Efficiency Deep Hole Drilling D 1D 20D 2D 0D UA Drills Oil-Hole Long Non-Step drilling is possible at the hole depth of 0D High efficient drilling with long tool life with Wet and MQL Cutting edge

More information

DIN Connector_p2-25.qxd

DIN Connector_p2-25.qxd INDEX 1 DIN Connectors Varieties of DIN Connectors, Kinked Contact and One Touch Lock Metal Tab Kinked Contacts One Touch Lock Metal Tabs 2 Spec Sheet Soldering/Wire wrapping type Pitch Rated current 3A

More information

特-7.indd

特-7.indd Mechanical Properties and Weldability of Turbine Impeller Materials for High Temperature Exhaust Gas Turbocharger 1 000 1 050 246 IN100 The increase in environmental awareness in recent years has led to

More information

080906_…o…−…^…b…vVSCW

080906_…o…−…^…b…vVSCW Thyristor Type Single-Phase Power Regulator 2030 A 6A 150200A TOKYO RIKOSHA CO., LTD Latest VARITAP VSCW Series Achieved 1/2 the width (our company comparison). Free Power source of 100 to 240V specification.cover-type

More information

パナソニック技報

パナソニック技報 Smaller, Lighter and Higher-output Lithium Ion Battery System for Series Hybrid Shinji Ota Jun Asakura Shingo Tode 24 ICECU Electronic Control Unit46 16 We have developed a lithium-ion battery system with

More information

J. Jpn. Inst. Light Met. 65(6): 224-228 (2015)

J. Jpn. Inst. Light Met. 65(6): 224-228 (2015) 65 62015 224 228 ** Journal of The Japan Institute of Light Metals, Vol. 65, No. 6 (2015), 224 228 2015 The Japan Institute of Light Metals Investigation of heat flow behavior on die-casting core pin with

More information

Vol. 51 No (2000) Thermo-Physiological Responses of the Foot under C Thermal Conditions Fusako IWASAKI, Yuri NANAMEKI,* Tomoko KOSHIB

Vol. 51 No (2000) Thermo-Physiological Responses of the Foot under C Thermal Conditions Fusako IWASAKI, Yuri NANAMEKI,* Tomoko KOSHIB Vol. 51 No. 7 587-593 (2000) Thermo-Physiological Responses of the Foot under 22-34 C Thermal Conditions Fusako IWASAKI, Yuri NANAMEKI,* Tomoko KOSHIBA and Teruko TAMURA * Junior College Division, Bunka

More information

75 unit: mm Fig. Structure of model three-phase stacked transformer cores (a) Alternate-lap joint (b) Step-lap joint 3 4)

75 unit: mm Fig. Structure of model three-phase stacked transformer cores (a) Alternate-lap joint (b) Step-lap joint 3 4) 3 * 35 (3), 7 Analysis of Local Magnetic Properties and Acoustic Noise in Three-Phase Stacked Transformer Core Model Masayoshi Ishida Kenichi Sadahiro Seiji Okabe 3.7 T 5 Hz..4 3 Synopsis: Methods of local

More information

Introduction Purpose This training course describes the configuration and session features of the High-performance Embedded Workshop (HEW), a key tool

Introduction Purpose This training course describes the configuration and session features of the High-performance Embedded Workshop (HEW), a key tool Introduction Purpose This training course describes the configuration and session features of the High-performance Embedded Workshop (HEW), a key tool for developing software for embedded systems that

More information

Connectors for Automobiles 62 SEALED SERIES Japanese English

Connectors for Automobiles 62 SEALED SERIES Japanese English Connectors for Automobiles 62 SEALED SERIES Japanese English 62 P-01 62 P-02 ( ) ( ) ( ) ( ) 0.6 24.6 ( ) ( ) ( ) ( ) 2.5 20.8 2.1 M(1400-0434) F(1400-0432) ( ) ( ) ( ) ( ) 0.6 24.6 ( ) ( ) ( ) ( ) 2.5

More information

塗装深み感の要因解析

塗装深み感の要因解析 17 Analysis of Factors for Paint Depth Feeling Takashi Wada, Mikiko Kawasumi, Taka-aki Suzuki ( ) ( ) ( ) The appearance and quality of objects are controlled by paint coatings on the surfaces of the objects.

More information

0810_UIT250_soto

0810_UIT250_soto UIT UNIMETER SERIES 250 201 Accumulated UV Meter Digital UV Intensity Meter Research & Development CD Medical Biotech Sterilization Exposure Bonding Manufacturing Curing Production Electronic Components

More information

Fig. 1. Schematic drawing of testing system. 71 ( 1 )

Fig. 1. Schematic drawing of testing system. 71 ( 1 ) 1850 UDC 669.162.283 : 669.162.263.24/. 25 Testing Method of High Temperature Properties of Blast Furnace Burdens Yojiro YAMAOKA, Hirohisa HOTTA, and Shuji KAJIKAWA Synopsis : Regarding the reduction under

More information

Title 社 会 化 教 育 における 公 民 的 資 質 : 法 教 育 における 憲 法 的 価 値 原 理 ( fulltext ) Author(s) 中 平, 一 義 Citation 学 校 教 育 学 研 究 論 集 (21): 113-126 Issue Date 2010-03 URL http://hdl.handle.net/2309/107543 Publisher 東 京

More information

Tab 5, 11 Tab 4, 10, Tab 3, 9, 15Tab 2, 8, 14 Tab 1, 7, 13 2

Tab 5, 11 Tab 4, 10, Tab 3, 9, 15Tab 2, 8, 14 Tab 1, 7, 13 2 COMPANION 20 MULTIMEDIA SPEAKER SYSTEM Owner s Guide Tab 5, 11 Tab 4, 10, Tab 3, 9, 15Tab 2, 8, 14 Tab 1, 7, 13 2 Tab1, 7, 13 Tab 2, 8, 14 Tab 3, 9, 15 Tab 4, 10, Tab 5, 11 This product conforms to all

More information

(1 ) (2 ) Table 1. Details of each bar group sheared simultaneously (major shearing unit). 208

(1 ) (2 ) Table 1. Details of each bar group sheared simultaneously (major shearing unit). 208 2463 UDC 621.771.251.09 : 621.791.94: 669.012.5 Improvement in Cold Shear Yield of Bar Mill by Computer Control System Koji INAZAKI, Takashi WASEDA, Michiaki TAKAHASHI, and Toshihiro OKA Synopsis: The

More information

橡

橡 CO2 Laser Treatment of Tinea Pedis Masahiro UEDA:,' Kiyotaka KITAMURA** and Yukihiro GOKOH*** Table I Specifications 1. Kind of Laser 2. Wavelength of Lasers. Power of Laser. Radiation Mode. Pulse Duration.

More information

How to read the marks and remarks used in this parts book. Section 1 : Explanation of Code Use In MRK Column OO : Interchangeable between the new part

How to read the marks and remarks used in this parts book. Section 1 : Explanation of Code Use In MRK Column OO : Interchangeable between the new part Reservdelskatalog MIKASA MVB-85 rullvibrator EPOX Maskin AB Postadress Besöksadress Telefon Fax e-post Hemsida Version Box 6060 Landsvägen 1 08-754 71 60 08-754 81 00 info@epox.se www.epox.se 1,0 192 06

More information

Page 1 of 6 B (The World of Mathematics) November 20, 2006 Final Exam 2006 Division: ID#: Name: 1. p, q, r (Let p, q, r are propositions. ) (10pts) (a

Page 1 of 6 B (The World of Mathematics) November 20, 2006 Final Exam 2006 Division: ID#: Name: 1. p, q, r (Let p, q, r are propositions. ) (10pts) (a Page 1 of 6 B (The World of Mathematics) November 0, 006 Final Exam 006 Division: ID#: Name: 1. p, q, r (Let p, q, r are propositions. ) (a) (Decide whether the following holds by completing the truth

More information

How to read the marks and remarks used in this parts book. Section 1 : Explanation of Code Use In MRK Column OO : Interchangeable between the new part

How to read the marks and remarks used in this parts book. Section 1 : Explanation of Code Use In MRK Column OO : Interchangeable between the new part Reservdelskatalog MIKASA MT65H vibratorstamp EPOX Maskin AB Postadress Besöksadress Telefon Fax e-post Hemsida Version Box 6060 Landsvägen 1 08-754 71 60 08-754 81 00 info@epox.se www.epox.se 1,0 192 06

More information

How to read the marks and remarks used in this parts book. Section 1 : Explanation of Code Use In MRK Column OO : Interchangeable between the new part

How to read the marks and remarks used in this parts book. Section 1 : Explanation of Code Use In MRK Column OO : Interchangeable between the new part Reservdelskatalog MIKASA MVC-50 vibratorplatta EPOX Maskin AB Postadress Besöksadress Telefon Fax e-post Hemsida Version Box 6060 Landsvägen 1 08-754 71 60 08-754 81 00 info@epox.se www.epox.se 1,0 192

More information

LM2940

LM2940 1A 3 1A 3 0.5V 1V 1A 3V 1A 5V 30mA (V IN V OUT 3V) 2 (60V) * C Converted to nat2000 DTD updated with tape and reel with the new package name. SN Mil-Aero: Order Info table - moved J-15 part from WG row

More information

Fig. 1 Structure of a Sebaceous Follicle (Ref.1).

Fig. 1 Structure of a Sebaceous Follicle (Ref.1). Importance and Countermeasures for Sebum Control in Application of Makeup Cosmetics Koichi NOMURA POLA Chemical Industries, Inc., R&D Planning Department 27-1, Takashimadai, Kanagawa-ku, Yokohama 221-0833,

More information

Note; a: Pressure sensor, b: Semi-permeable membrane, c: O-ring, d: Support screen, e: Solution, f: Solvent. Fig. 2. Osmometer cell. Fig. 1. Schematic

Note; a: Pressure sensor, b: Semi-permeable membrane, c: O-ring, d: Support screen, e: Solution, f: Solvent. Fig. 2. Osmometer cell. Fig. 1. Schematic Studies on Collapse of Wood Cells and Negative Pressure in Cell Lumen by Yoshiaki HATTORI* and Yasushi KANAGAWA** The negative pressure, that is liquid-tension, to cause cell-collapse was estimated with

More information

T05_Nd-Fe-B磁石.indd

T05_Nd-Fe-B磁石.indd Influence of Intergranular Grain Boundary Phases on Coercivity in Nd-Fe-B-based Magnets Takeshi Nishiuchi Teruo Kohashi Isao Kitagawa Akira Sugawara Hiroyuki Yamamoto To determine how to increase the coercivity

More information

Fig. 1 Sampling positions from the ingot. Table 2 Chemical compositions of base metal (%) Fig. 2 (unit: mm) Shape and size of fatigue test specimen. T

Fig. 1 Sampling positions from the ingot. Table 2 Chemical compositions of base metal (%) Fig. 2 (unit: mm) Shape and size of fatigue test specimen. T Friction welding of ADC 12 aluminum alloy diecastings Kazuyoshi KATO* and Hiroshi TOKISUE* Both squeeze and gravity castings of ADC 12 aluminum alloy were friction-welded, using a brake type welding machine.

More information

Estimation of Photovoltaic Module Temperature Rise Motonobu Yukawa, Member, Masahisa Asaoka, Non-member (Mitsubishi Electric Corp.) Keigi Takahara, Me

Estimation of Photovoltaic Module Temperature Rise Motonobu Yukawa, Member, Masahisa Asaoka, Non-member (Mitsubishi Electric Corp.) Keigi Takahara, Me Estimation of Photovoltaic Module Temperature Rise Motonobu Yukawa, Member, Masahisa Asaoka, Non-member (Mitsubishi Electric Corp.) Keigi Takahara, Member (Okinawa Electric Power Co.,Inc.) Toshimitsu Ohshiro,

More information

Specification for Manual Pulse Generator, GFK-2262

Specification for Manual Pulse Generator, GFK-2262 Specification change in Manual Pulse Generator () A) Abstract This document explains about the specification change in Manual Pulse Generator (). The production of the former specifications written in

More information

クイックスタートガイド [SC-06D]

クイックスタートガイド [SC-06D] SC-06D a g h a i b j c k m n o p q s t u v w d e f l r g a b c d e f g h i j k l m n o p q r s t u v w x x a ab c 3 1 2 b c d a b 1 2 e a ab c 3 1 2 b c d e f a b c d e f a b

More information

燃焼圧センサ

燃焼圧センサ 49 Combustion Pressure Sensor Kouji Tsukada, Masaharu Takeuchi, Sanae Tokumitsu, Yoshiteru Ohmura, Kazuyoshi Kawaguchi π 1000N 150 225N 1 F.S Abstract A new combustion pressure sensor capable of measuring

More information

On the Wireless Beam of Short Electric Waves. (VII) (A New Electric Wave Projector.) By S. UDA, Member (Tohoku Imperial University.) Abstract. A new e

On the Wireless Beam of Short Electric Waves. (VII) (A New Electric Wave Projector.) By S. UDA, Member (Tohoku Imperial University.) Abstract. A new e On the Wireless Beam of Short Electric Waves. (VII) (A New Electric Wave Projector.) By S. UDA, Member (Tohoku Imperial University.) Abstract. A new electric wave projector is proposed in this paper. The

More information

How to read the marks and remarks used in this parts book. Section 1 : Explanation of Code Use In MRK Column OO : Interchangeable between the new part

How to read the marks and remarks used in this parts book. Section 1 : Explanation of Code Use In MRK Column OO : Interchangeable between the new part Reservdelskatalog MIKASA MCD-L14 asfalt- och betongsåg EPOX Maskin AB Postadress Besöksadress Telefon Fax e-post Hemsida Version Box 6060 Landsvägen 1 08-754 71 60 08-754 81 00 info@epox.se www.epox.se

More information

MKS-05 "TERRA-Pプラス 日本語訳取扱説明書

MKS-05 TERRA-Pプラス 日本語訳取扱説明書 MKS-05 "TERRA-P+" BICT.412129.021 KE Sparing-Vist Center Sparing-Vist Center ECOTEST (+38 032) 242-15-15 (+38 032) 242-20-15 sales@ecotest.ua 18 ( ) 2 1. 3 2. 3 3. 4 4. 4 5. 6 6. 7 7. 11 8. 11 9. 11 10.

More information

クイックスタートガイド [SC-03E]

クイックスタートガイド [SC-03E] a L R 2.4 FH1 / DS4 / OF4 / XX8 IEEE802.11b/g/n IEEE802.11a/n J52 W52 W53 W56 g h a i b j c k m n o p q s t u v w t d e f l g a b c d r e f g h i j k l m n o p q r s t u v w x

More information

PRODUCT INFORMATION Highly Efficient FXS Carbide Ball Nose End Mills Vol. 3 PAT.P. FXS-EBT FXS-LS-EBT FXS-PC-EBT FXS-EBM

PRODUCT INFORMATION Highly Efficient FXS Carbide Ball Nose End Mills Vol. 3 PAT.P. FXS-EBT FXS-LS-EBT FXS-PC-EBT FXS-EBM PRODUCT INFORMATION Highly Efficient FXS Carbide Ball Nose End Mills Vol. 3 PAT.P. FXS-EBT FXS-LS-EBT FXS-PC-EBT FXS-EBM 3 Flutes Series Features Thanks to 3 flutes ball nose geometry, all of that reach

More information

渡辺(2309)_渡辺(2309)

渡辺(2309)_渡辺(2309) [ 29 p. 241-247 (2011)] ** *** ** ** Development of a nickel-based filler metal containing a small amount of silicon by WATANABE Takehiko, WAKATSUKI Ken, YANAGISAWA Atsusi and SASAKI Tomohiro Authors tried

More information

Fig. 1 Schematic construction of a PWS vehicle Fig. 2 Main power circuit of an inverter system for two motors drive

Fig. 1 Schematic construction of a PWS vehicle Fig. 2 Main power circuit of an inverter system for two motors drive An Application of Multiple Induction Motor Control with a Single Inverter to an Unmanned Vehicle Propulsion Akira KUMAMOTO* and Yoshihisa HIRANE* This paper is concerned with a new scheme of independent

More information

Corrections of the Results of Airborne Monitoring Surveys by MEXT and Ibaraki Prefecture

Corrections of the Results of Airborne Monitoring Surveys by MEXT and Ibaraki Prefecture August 31, 2011 Corrections of the Results of Airborne Monitoring Surveys by MEXT and Ibaraki Prefecture The results of airborne monitoring survey by MEXT and Ibaraki prefecture released on August 30 contained

More information

202

202 201 Presenteeism 202 203 204 Table 1. Name Elements of Work Productivity Targeted Populations Measurement items of Presenteeism (Number of Items) Reliability Validity α α 205 α ä 206 Table 2. Factors of

More information

A Nutritional Study of Anemia in Pregnancy Hematologic Characteristics in Pregnancy (Part 1) Keizo Shiraki, Fumiko Hisaoka Department of Nutrition, Sc

A Nutritional Study of Anemia in Pregnancy Hematologic Characteristics in Pregnancy (Part 1) Keizo Shiraki, Fumiko Hisaoka Department of Nutrition, Sc A Nutritional Study of Anemia in Pregnancy Hematologic Characteristics in Pregnancy (Part 1) Keizo Shiraki, Fumiko Hisaoka Department of Nutrition, School of Medicine, Tokushima University, Tokushima Fetal

More information

Bead Instructions First, locate the acupressure point you wish to stimulate. Next, remove a plastic bead from the bag. Remove the backing from the adh

Bead Instructions First, locate the acupressure point you wish to stimulate. Next, remove a plastic bead from the bag. Remove the backing from the adh icewave Instructions Bead Instructions First, locate the acupressure point you wish to stimulate. Next, remove a plastic bead from the bag. Remove the backing from the adhesive plastic patch included.

More information

How to read the marks and remarks used in this parts book. Section 1 : Explanation of Code Use In MRK Column OO : Interchangeable between the new part

How to read the marks and remarks used in this parts book. Section 1 : Explanation of Code Use In MRK Column OO : Interchangeable between the new part Reservdelskatalog MIKASA MVC-88 vibratorplatta EPOX Maskin AB Postadress Besöksadress Telefon Fax e-post Hemsida Version Box 6060 Landsvägen 1 08-754 71 60 08-754 81 00 info@epox.se www.epox.se 1,0 192

More information

Study on Application of the cos a Method to Neutron Stress Measurement Toshihiko SASAKI*3 and Yukio HIROSE Department of Materials Science and Enginee

Study on Application of the cos a Method to Neutron Stress Measurement Toshihiko SASAKI*3 and Yukio HIROSE Department of Materials Science and Enginee Study on Application of the cos a Method to Neutron Stress Measurement Toshihiko SASAKI*3 and Yukio HIROSE Department of Materials Science and Engineering, Kanazawa University, Kakuma-machi, Kanazawa-shi,

More information

LM mA 低ドロップアウト・リニア・レギュレータ

LM mA 低ドロップアウト・リニア・レギュレータ 800mA 800mA LM1117I 800mA LM1117 Chris Russell LM1117 800mA 1.2V LM1117 LM317 LM1117 2 1.25V 13.8V 1.8V 2.5V 2.85V 3.3V 5V 5 LM1117 1 LM1117 LLP TO-263 SOT-223 TO-220 TO-252 10 F 19970801 23900 DS100919

More information

<8B5A8F70985F95B632936EE7B22E696E6464>

<8B5A8F70985F95B632936EE7B22E696E6464> 47 Electrical Discharge Truing for Electroplated Diamond Tools Koji Watanabe Hisashi Minami Hatsumi Hiramatsu Kiyonori Masui (211 7 8 ) Electroplated diamond tools are widely used for grinding because

More information

<95DB8C9288E397C389C88A E696E6462>

<95DB8C9288E397C389C88A E696E6462> 2011 Vol.60 No.2 p.138 147 Performance of the Japanese long-term care benefit: An International comparison based on OECD health data Mie MORIKAWA[1] Takako TSUTSUI[2] [1]National Institute of Public Health,

More information

137. Tenancy specific information (a) Amount of deposit paid. (insert amount of deposit paid; in the case of a joint tenancy it should be the total am

137. Tenancy specific information (a) Amount of deposit paid. (insert amount of deposit paid; in the case of a joint tenancy it should be the total am 13Fast Fair Secure PRESCRIBED INFORMATION RELATING TO TENANCY DEPOSITS* The Letting Protection Service Northern Ireland NOTE: The landlord must supply the tenant with the Prescribed Information regarding

More information

42 1 Fig. 2. Li 2 B 4 O 7 crystals with 3inches and 4inches in diameter. Fig. 4. Transmission curve of Li 2 B 4 O 7 crystal. Fig. 5. Refractive index

42 1 Fig. 2. Li 2 B 4 O 7 crystals with 3inches and 4inches in diameter. Fig. 4. Transmission curve of Li 2 B 4 O 7 crystal. Fig. 5. Refractive index MEMOIRS OF SHONAN INSTITUTE OF TECHNOLOGY Vol. 42, No. 1, 2008 Li 2 B 4 O 7 (LBO) *, ** * ** ** Optical Scatterer and Crystal Growth Technology of LBO Single Crystal For Development with Optical Application

More information

…X…C…b…`A001_212

…X…C…b…`A001_212 RoHS compliant ITERAL STRUCTURE FEATURES RoHS compliant Meets EIAJ SP standard outline dimensions (B type) Low profile design of 2.5 mm 12 types of 1, 2, 4, 6, or 1 bit with either gull wing or J-hook

More information

03-01 Senyouki.pdf

03-01 Senyouki.pdf Special Surface Treatment Rust-free under normal use conditions. No loss of precision due to rust. Minimum maintenance required. Stub Holder KH-E KH-EC1 Stub Holder KH-A 406 KH-E Quick Change Stub Holder

More information

elemmay09.pub

elemmay09.pub Elementary Activity Bank Activity Bank Activity Bank Activity Bank Activity Bank Activity Bank Activity Bank Activity Bank Activity Bank Activity Bank Activity Bank Activity Bank Number Challenge Time:

More information

24 Depth scaling of binocular stereopsis by observer s own movements

24 Depth scaling of binocular stereopsis by observer s own movements 24 Depth scaling of binocular stereopsis by observer s own movements 1130313 2013 3 1 3D 3D 3D 2 2 i Abstract Depth scaling of binocular stereopsis by observer s own movements It will become more usual

More information