低温材料物性表

Presented at the 11th International Cryocooler Conference

June 20-22, 2000

Keystone, Co Cryogenic Material Properties Database Cryogenic Material Properties Database

E.D. Marquardt, J.P. Le, and Ray Radebaugh

National Institute of Standards and Technology

Boulder, CO 80303

ABSTRACT

NIST has published at least two references compiling cryogenic material properties. These include the Handbook on Materials for Superconducting Machinery and the LNG Materials & Fluids. Neither has been updated since 1977 and are currently out of print. While there is a great deal of published data on cryogenic material properties, it is often difficult to find and not in a form that is convenient to use. We have begun a new program to collect, compile, and correlate property information for materials used in cryogenics. The initial phase of this program has focused on picking simple models to use for thermal conductivity, thermal expansion, and specific heat. We have broken down the temperature scale into four ranges: a) less than 4 K, b) 4 K to77 K, c) 77 K to 300 K, and d) 300 K to the melting point. Initial materials that we have compiled include oxygen free copper, 6061-T6 aluminum, G-10 fiberglass epoxy, 718 Inconel, Kevlar, niobium titanium (NbTi), beryllium copper, polyamide (nylon), polyimide, 304 stainless steel, Teflon, and Ti-6Al-4V titanium alloy. Correlations are given for each material and property over some of the temperature range. We will continue to add new materials and increase the temperature range. We hope to offer these material properties as subroutines that can be called from your own code or from within commercial software packages. We will also identify where new measurements need to be made to give complete property prediction from 50 mK to the melting point.

INTRODUCTION

The explosive growth of cryogenics in the early 50’s led to much interest in material properties at low temperatures. Important fundamental theory and measurements of low temperature material properties were performed in the 50’s, 60’s, and 70’s. The results of this large amount of work has become fragmented and dispersed in many different publications, most of which are out of print and difficult to find. Old time engineers often have a file filled with old graphs; young engineers often don’t know how to find this information. Since most of the work was performed before the desktop computer became available, when data can be found, it is published in simple tables or graphically, making the information difficult to accurately determine and use.

NIST has begun a program to gather cryogenic material property data and make it available in a form that is useful to engineers. Initially we tried to use models based upon fundamental physics but it soon became apparent that the models could not accurately predict properties over

Table 1A . Coefficients for thermal conductivity for metals.

Coeff.

6061 -T6 Aluminum 304 SS 718 Inconel Beryllium copper Ti-6Al-4V a

0.07918 -1.4087 -8.28921 -0.50015 -5107.8774 b

1.09570 1.3982 39.4470 1.93190 19240.422 c

-0.07277 0.2543 -83.4353 -1.69540 -30789.064 d

0.08084 -0.6260 98.1690 0.71218 27134.756 e

0.02803 0.2334 -67.2088 1.27880 -14226.379 f

-0.09464 0.4256 26.7082 -1.61450 4438.2154 g

0.04179 -0.4658 -5.72050 0.68722 -763.07767 h

-0.00571 0.1650 0.51115 -0.10501 55.796592 I

0 -0.0199 0 0 0 data range 4-300 K 4-300 K 4-300 K 4-300 K 20-300 K

a large temperature range and over different materials. Our current approach is to choose a few simple types of equations such as polynomial or logarithmic polynomials and determine the coefficients of different materials and properties. This will allow engineers to use the equations to predict material properties in a variety of ways including commercial software packages or their own code. Integrated and average values can easily be determined from the equations. These equations are not meant to provide any physical insight into the property or to provide ‘standard’ values but are for working engineers that require accurate values.

MATERIALS

Initial materials that we have compiled include oxygen free copper, 6061-T6 aluminum, G-10CR fiberglass epoxy, 718 Inconel, Kevlar 49, niobium titanium (NbTi), beryllium copper, polyamide (nylon), polyimide, 304 stainless steel, Teflon, and Ti-6Al-4V titanium alloy. These were chosen as some of the most common materials used in cryogenic systems in a variety of fields.

MATERIAL PROPERTIES

Thermal Conductivity

Widely divergent values of thermal conductivity for the same material are often reported in the literature. For comparatively pure materials (like copper), the differences are due mainly to slight material differences that have large effects on transport properties, such as thermal conductivity, at cryogenic temperatures. At 10 K, the thermal conductivity of commercial oxygen free copper for two samples can be different by more then a factor of 20 while the same samples at room temperature would be within 4%. It is also not uncommon for some experimental results to have uncertainties as high as 50%. Part of our program is to critically evaluate the literature to determine the best property values. Data references used to generate predictive equations will be reported.

The general form of the equation for thermal conductivity, k , is

log()log (log )(log )(log )(log )(log )(log )(log ),k a b T c T d T e T f T g T h T i T =+++++

+++2345678 (1)

where a , b , c , d, e , f , g , h , and i are the fitted coefficients, and T is the temperature. These are common logarithms. While this may seem like an excessive number of terms to use, it was determined that in order to fit the data over the large temperature range, we required a large number of terms. It should also be noted that all the digits provided for the coefficients should be used, any truncation can lead to significant errors. Tables 1A and 1B show the coefficients for a variety of metals and non-metals. Equation 2 is the thermal conductivity for an average sample of oxygen free copper. It should be noted that thermal conductivity for oxygen free copper can

Table 1B . Coefficients for thermal conductivity for non-metals.

Coeff. Teflon Polyamide (nylon) Polyimide (Kapton) G10 CR (norm) G10 CR

(warp)

a

2.7380 -2.6135 5.73101 -4.1236 -2.64827 b

-30.677 2.3239 -39.5199 13.788 8.80228 c

89.430 -4.7586 79.9313 -26.068 -24.8998 d

-136.99 7.1602 -83.8572 26.272 41.1625 e

124.69 -4.9155 50.9157 -14.663 -39.8754 f

-69.556 1.6324 -17.9835 4.4954 23.1778 g

23.320 -0.2507 3.42413 -0.6905 -7.95635 h

-4.3135 0.0131 -0.27133 0.0397 1.48806 I

0.33829 0 0 0 -0.11701 data range 4-300 K

4-300 K 4-300 K 10-300 K 12-300 K Figure 1. Thermal conductivity of various materials.

vary widely depending upon the residual resistivity ratio, RRR, and this equation should be used with caution. The thermal conductivities are displayed graphically in Figure 1.

log .............k T T T T T T T T =?+?+?+?+22154088068029505004831000032071047461013871002043000012810515205152

(2) Specific Heat

The specific heat is the amount of heat energy per unit mass required to cause a unit increase in the temperature of a material, the ratio of the change in energy to the change in temperature. Specific heats are strong functions of temperature, especially below 200 K. Models for specific heat began in the 1871 with Boltzmann and were further refined by Einstein and Debye in the early part of the 20th century. While there are many variations of these first models, they generally only provide accurate results for materials with perfect crystal lattice structures. The

Table 2. Coefficients for specific heat. Coeff. OFCH

copper 6061 -T6 Aluminum 304 SS G-10 Teflon a

-1.91844 46.6467 22.0061 -2.4083 31.8825 b

-0.15973 -314.292 -127.5528 7.6006 -166.519 c

8.61013 866.662 303.6470 -8.2982 352.019 d

-18.99640 -1298.30 -381.0098 7.3301 259.981 e

21.96610 1162.27 274.0328 -4.2386 -104.614 f

-12.73280 -637.795 -112.9212 1.4294 24.9927 g

3.54322 210.351 2

4.7593 -0.24396 -3.20792 h

-0.37970 -38.3094 -2.239153 0.015236 0.165032 I

0 2.96344 0 0 0 data range 3-300 K 3-300 K 3-300 K 3-300 K 3-300 K

Figure 2. Specific heat of various materials.

specific heat of many of the engineering materials of interest here is not described well by these simple models. The general form of the equation is the same as Equation 1. Table 2 shows the coefficients for the specific heat. Figure 2 graphically shows the specific heats.

Thermal Expansion

From an atomic perspective, thermal expansion is caused by an increase in the average distance between the atoms. This results from the asymmetric curvature of the potential energy versus interatomic distance. The anisotropy results from the differences in the coulomb attraction and the interatomic repulsive forces.

Different metals and alloys with different heat treatments, grain sizes, or rolling directions introduce only small differences in thermal expansion. Thus, a generalization can be made that literature values for thermal expansion are probably good for a like material to within 5%. This is because the thermal expansion depends explicitly on the nature of the atomic bond, and only those changes that alter a large number of the bonds can affect its value. In general, large

Table 3A . Integrated Linear Thermal Expansion Coefficients for Metals.

Coeff.

6061 -T6 Aluminum 304 SS 718 Inconel Beryllium copper Ti-6Al-4V NbTi a

-4.1272E+02 -2.9546E+02-2.366E+02-3.132E+02-1.711E+02 -1.862E+02b

-3.0640E-01 -4.0518E-01-2.218E-01-4.647E-01-2.171E-01 -2.568E-01 c

8.7960E-03 9.4014E-03 5.601E-03 1.083E-02 4.841E-03 8.334E-03 d

-1.0055E-05 -2.1098E-05-7.164E-06-2.893E-05-7.202E-06 -2.951E-05 e

0 1.8780E-080 3.351E-080 3.908E-08 data range 4-300 K 4-300 K 4-300 K 4-300 K 4-300 K 4-300 K

Table 3B. Integrated Linear Thermal Expansion Coefficients for Non-metals.

Coeff. Teflon Polyamide G10 CR (norm) G10 CR

(warp)

a

-2.165E+03 -1.389E+03-7.180E+02-2.469E+02 b

3.278E+00 -1.561E-01 3.741E-01 2.064E-01 c

-8.218E-03 2.988E-02 8.183E-03 3.072E-03 d

7.244E-05 -7.948E-05-3.948E-06-3.226E-06 e

0 1.181E-07 0 0 data range 4-300 K 4-300 K 4-300 K 4-300 K

changes in composition (10 to 20%) are necessary to produce significant changes in the thermal expansion (~5%), and different heat treatments or conditions do not produce significant changes unless phase changes are involved.8

Most of the literature reports the integrated linear thermal expansion as a percent change in length from some original length generally measured at 293 K,

()/.L L L T ?293293 (3) Where L T is the length at some temperature T and L 293 is the length at 293 K. While this is a practical way of measuring thermal expansion, the more fundamental property is the coefficient of linear thermal expansion, α,

α()().T L dL T dT

=1 (4) The coefficient of linear thermal expansion is much less reported in the literature. In principal, we can simply take the derivative of the integrated linear thermal expansion that results in the coefficient of linear thermal expansion. While we have had success with this method over limited temperature ranges, we have not yet determined an equation form for the integrated expansion value that results in a good approximation of coefficient of linear thermal expansion. For the time being, we will report the integrated linear thermal expansion as a change in length and provide the coefficient of linear thermal expansion when it is directly reported in the literature. The general form of the equation for integrated linear thermal expansion is L L L a bT cT dT eT T ?=++++??293293

234510(). (5) Tables 3A and 3B provide the coefficients for the various materials while Figure 3 plots the integrated linear thermal expansions.

FUTURE PLANS

We plan to continually add new materials, properties, and to expand the useful temperature range of the predictive equations for engineering use. We will report results in the literature but will also update our website on a continual basis. The initial phase of the program was a learning

Figure 3. Integrated linear thermal expansion of various materials.

experience on how to handle the information in the literature as well as for the development of a standard set of basic equation types used to fit experimental data. By using just a few types of equations, we hope to make the information easier to use. We shall now focus on developing large numbers of equations for a variety of materials and properties. Please check our web site at https://www.360docs.net/doc/e08113286.html,/div838/cryogenics.html for updated information.

REFERENCES

1. Berman, R., Foster, E.L., and Rosenberg, H.M., "The Thermal Conductivity of Some

Technical Materials at Low Temperature." Britain Journal of Applied Physics, 1955. 6: p.

181-182.

2. Child, G., Ericks, L.J., and Powell, R.L., Thermal Conductivity of Solids at Room

Temperatures and Below. 1973, National Bureau of Standards: Boulder, CO.

3. Corruccini, R.J. and Gniewek, J.J., Thermal Expansion of Technical Solids at Low

Temperatures. 1961, National Bureau of Standards: Boulder, CO.

4. Cryogenic Division, Handbook on Materials for Superconducting Machinery. Mechanical,

thermal, electrical and magnetic properties of structure materials. 1974, National Bureau of Standards: Boulder, CO.

5. Cryogenic Division, LNG Materials and Fluids. 1977, National Bureau of Standards:

Boulder, CO.

6. Johnson, V.J., WADD Technical Report. Part II: Properties of Solids. A Compendium of

The Properties of Materials at Low Temperature (phase I). 1960, National Bureau of Standard: Boulder, CO.

7. Powells, R.W., Schawartz, D., and Johnston, H.L., The Thermal Conductivity of Metals and

Alloys at Low Temperature. 1951, Ohio State University.

8. Reed, R.P. and Clark, A.F., Materials at Low Temperature. 1983, Boulder, CO: American

Society for Metals.

9. Rule, D.L., Smith, D.R., and Sparks, L.L., Thermal Conductivity of a Polyimide Film

Between 4.2 and 300K, With and Without Alumina Particles as Filler. 1990, National Institute of Standards and Technology: Boulder, CO.

10. Simon, N.J., Drexter, E.S., and Reed, R.P., Properties of Copper Alloys at Cryogenic

Temperature. 1992, National Institute of Standards and Technology: Boulder, CO.

11. Touloukian, Y.S., Recommended Values of The Thermophysical Properties of Eight Alloys,

Major Constituents and Their Oxides. 1965, Purdue University.

12. Veres, H.M., Thermal Properties Database for Materials at Cryogenic Temperatures. Vol. 1.

13. Ziegler, W.T., Mullins, J.C., and Hwa, S.C.O., "Specific Heat and Thermal Conductivity of

Four Commercial Titanium Alloys from 20-300K," Advances in Cryogenic Engineering Vol. 8, pp. 268-277.

物性材料表

特性Feature 耐高温、耐冲击、高流动性、尺寸稳定。High temperature resistance, impact resistance, high liquidity, dimension stability. 用途Use 电子、电器零件、汽车部件等。Electronic, electrical parts, auto parts, etc. 注塑条件Injection conditions 预干燥温度Pre-drying temperature 预干燥时间Pre-drying time 进料区温度Feed zone temperature 压缩区温度Compression zone temperature 熔融区温度Melting zone temperature 喷嘴温度Nozzle Temperature 模具温度Mold 注射压力Injection pressure 物理机械性能Physical and mechanical properties 项目Project 单位unit 试验方法Test method 数值Value 密度Density 熔点Melting point 成型收缩率Mold Shrinkage 吸水率（24小时，23℃）Water Absorption (24 hours, 23 ℃) 熔融指数Melt Index 阻燃等级Flame Rating 拉伸断裂强度Tensile Strength 拉伸模量Tensile modulus 断裂伸长率Elongation at break 弯曲强度Bending 弯曲模量Bending modulus 悬臂梁（无缺口）冲击强度Izod (unnotched) impact strength 悬臂梁缺口冲击强度Izod notched impact strength 洛氏硬度Rockwell hardness 热变形温度（0.45MPa）Heat Deflection Temperature（0.45MPa） Dielectric Strength 绝缘破坏强度 Arc resistance 耐电弧性 Dielectric Constant 介电常数 Dielectric Losses 介电损耗 Characteristics 特性 平衡吸湿量Moisture Absorption at Equilibrium 线性成型收缩率，横向Linear Mould Shrinkage, Transverse 断裂伸长率Elongation at Break 屈服伸长率Elongation at Yield

PA10T材料物性表

P ROVISIONAL D ATA S HEET G RIVORY HT G RIVORY XE 4027 BLACK 9916 Product description Grivory XE 4027 black 9916 is a 30% glass-fibre reinforced flame retardant (UL 94 V-0) engineering thermoplastic material based on a semicrystalline, partially aromatic co-polyamide. Grivory XE 4027 black 9916 is free of halogens and red phosphorus. RoHS: Grivory XE 4027 black 9916 is in compliance with RoHS (2002/95/EC, Re-striction of Hazardous Substances). WEEE:Parts produced from Grivory XE 4027 black 9916 are not subject to "selec-tive treatment" according the Directive 2002/96/EC on Waste Electrical and Elec-tronic Equipment. ISO polymer designation: PA 10T/X ASTM designation: PPA, polyphthalamide The main distinguishing features of Grivory HT-PPA, when compared to other poly-amides, are its good performance at high temperatures providing parts which are stiffer, stronger, have better heat distortion and dimensional stability as well as excel-lent chemical resistance and low moisture absorption. Grivory XE 4027 black 9916 is especially suitable for injection moulded components in electrical and electronic applications which require a flame class acc. UL 94 V-0. The material is suitable for lead-free SMT reflow soldering acc. i.e. JEDEC J-STD-020C (peak temperature 260°C). Compo-nents conforming to JEDEC MSL1 are achievable.

Sabic DX10311原料物性表

L NP* Thermocomp* Compound DX10311A sia Pacific: COMMERCIAL DX10311 is 30% glass fiber reinforced, impact modified polycarbonate resin. High flow and good ductility. T YPICAL PROPERTIES 1 TYPICAL VALUE UNIT STANDARD M ECHANICAL T ensile Stress, brk, Type I, 5 mm/min 117M Pa A STM D 638T ensile Strain, brk, Type I, 5 mm/min 2.6%A STM D 638T ensile Modulus, 5 mm/min 8330M Pa A STM D 638F lexural Stress 190M Pa A STM D 790F lexural Modulus 7670M Pa A STM D 790T ensile Stress, break, 5 mm/min 119M Pa I SO 527T ensile Strain, break, 5 mm/min 2.7%I SO 527T ensile Modulus, 1 mm/min 8260M Pa I SO 527F lexural Stress, yield, 2 mm/min 182M Pa I SO 178F lexural Stress, break, 2 mm/min 181M Pa I SO 178F lexural Modulus, 2 mm/min 7720M Pa I SO 178I MPACT Charpy Impact, unnotched, 23°C 57k J/m2I SO 179/2C Izod Impact, unnotched, 23°C 752J /m A STM D 4812 Izod Impact, notched, 23°C 196J /m A STM D 256 Charpy Impact, notched, 23°C 20k J/m2I SO 179/2C T HERMAL H DT, 0.45 MPa, 3.2 mm, unannealed 128°C A STM D 648 CTE, -40°C to 40°C, flow 1.9E-051/°C A STM E 831 CTE, -40°C to 40°C, xflow 6.4E-051/°C A STM E 831P HYSICAL S pecific Gravity 1.42-A STM D 792M old Shrinkage, flow, 3.2 mm (5)0.1 - 0.3%S ABIC Method M old Shrinkage, xflow, 3.2 mm (5) 0.2 - 0.4% S ABIC Method Melt Volume Rate, MVR at 300°C/5.0 kg 37 c m3/10 min I SO 1133 1) 2) PLEASE CONTACT YOUR LOCAL SALES OFFICE FOR AVAILABILITY IN YOUR AREA DISCLAIMER : THE MATERIALS AND PRODUCTS OF THE BUSINESSES MAKING UP THE SABIC INNOVATIVE PLASTICS Source, GMD, Last Update: COMPANY, ITS SUBSIDIARIES AND AFFILIATES ("SABIC IP"), ARE SOLD SUBJECT TO SABIC IP' S STANDARD CONDITIONS OF SALE, WHICH ARE INCLUDED IN THE APPLICABLE DISTRIBUTOR OR OTHER SALES AGREEMENT, PRINTED ON THE BACK OF ORDER ACKNOWLEDGMENTS AND INVOICES, AND AVAILABLE UPON REQUEST. ALTHOUGH ANY INFORMATION, RECOMMENDATIONS, OR ADVICE CONTAINED HEREIN IS GIVEN IN GOOD FAITH, SABIC IP MAKES NO WARRANTY OR GUARANTEE, EXPRESS OR IMPLIED, (I) THAT THE RESULTS DESCRIBED HEREIN WILL BE OBTAINED UNDER END-USE CONDITIONS, OR (II) AS TO THE EFFECTIVENESS OR SAFETY OF ANY DESIGN INCORPORATING SABIC IP MATERIALS, PRODUCTS, RECOMMENDATIONS OR ADVICE. EXCEPT AS PROVIDED IN SABIC IP' S STANDARD CONDITIONS OF SALE, SABIC IP AND ITS REPRESENTATIVES SHALL IN NO EVENT BE RESPONSIBLE FOR ANY LOSS RESULTING FROM ANY USE OF ITS MATERIALS OR PRODUCTS DESCRIBED HEREIN.Each user bears full responsibility for making its own determination as to the suitability of SABIC IP' s materials, products, recommendations, or advice for its own particular use. Each user must identify and perform all tests and analyses necessary to assure that its finished parts incorporating SABIC IP materials or products will be safe and suitable for use under end-use conditions. Nothing in this or any other document, nor any oral recommendation or advice, shall be deemed to alter, vary, supersede, or waive any provision of SABIC IP' s Standard Conditions of Sale or this Disclaimer, unless any such modification is specifically agreed to in a writing signed by SABIC IP. No statement contained herein concerning a possible or suggested use of any material, product or design is intended, or should be construed, to grant any license under any patent or other intellectual property right of SABIC Innovative Plastics Company or any of its subsidiaries or affiliates covering such use or design, or as a recommendation for the use of such material, product or design in the infringement of any patent or other intellectual property right * LNP is a trademark of the SABIC Innovative Plastics Company * Thermocomp is a trademark of the SABIC Innovative Plastics Company ? 1997-2011 SABIC Innovative Plastics Company.All rights reserved T ypical values only. Variations within normal tolerances are possible for variose colours.All values are measured at least after 48 hours s torage at 230C/50% relative humidity. All properties, except the melt volume rate are measured on injection m oulded samples.All samples are prepared according to ISO 294. O nly typical data for material selection purpose.Not to be used for p art or tool design. 3) T his rating is not intended to reflect hazards presented by this or any o ther material under actual fire conditions.4) O wn measurement according to UL. 5) Measurements made from laboratory test coupon. Actual shrinkage may vary outside of range due to differences in processing conditions, equipment, part geometry and tool design. It is recommended that mold shrinkage studies be performed with surrogate or legacy tooling prior to cutting tools for new molded article.

锂电材料物性对比

电池材料厂家技术标准积累 深圳市贝特瑞 MSG-S(518) 负极石墨粒径：D10=9.764；D50=17.136um；D90=28.189；水分:0.039;碳含量:99.952;TAP密度;1.036 比表面 积:2.784；首次容量/效率:363.51/94.18 深圳市贝特瑞 518 负极石墨粒径：D10=9.862；D50=16.888um； D90=28.374；水分:0.04%; 碳含量:99.962; TAP密度;1.042% 比表面积:2.625；首次容量/效率:352.3/92.5% 深圳市贝特瑞 AG 负极石墨粒径：D10=7.137；D50=18.058um； D90=37.495；水分：0.035;碳含量：99.676;TAP密度：1.001 首次容量/效率:320.83/90.42% 深圳市贝特瑞 AG 负极石墨粒径：D10=7.53；D50=17.779um； D90=39.648；水分：0.041;碳含量：99.743;TAP密度：1.002 ，首次容量/效率:326.51/90.67% 深圳市贝特瑞 SAG-23 负极石墨粒径：D10=8.318；D50=21.097um； D90=47.119；水分：0.04；碳含量：99.925；TAP密度：1.021 ，比表面积:4.605；首次容量/效率:332.11/92.08 深圳市贝特瑞 818 负极石墨粒径：D10=11.453；D50=18.226um； D90=28.762；水分：0.036；碳含量：99.964;TAP密度：1.121 比表面积:1.947;首次容量/效率:364.63/95.29% 深圳市贝特瑞 818 负极石墨粒径：D10=10.859；D50=18.033um；

材料物性表

EXTRUSION APPLICATION

Introduction Responsible for a long line of accomplishments in outstanding engineering plastics, UBE NYLON products have won the trust and respect of users the world over. UBE NYLON – NYLON 6, NYLON COPOLYMERS – is in wide use throughout industry with their unique properties utilized to their fullest potential. UBE NYLON 6 has a number of excellent properties as follows: Excellent in impact strength and rigidity Having a smaller friction coefficient, thus excellent in abrasion resistance Excellent in resistance to oils, solvents and chemicals Superior in heat resistance Appropriate to mass production, contributing to cost reduction Summary 1. Introduction 2. Nomenclature 3. Monofilament Applications 4. Film Applications 5. TERPALEX Polyamide 6/66/12 Copolymer Nomenclature The first 2 digits in the code indicate the type of Polyamide. The third and fourth digits indicate the molecular weight level for 1000 series. In case of copolymer, the third digit shows the viscosity level. The co-polymerization ratio can be roughly calculated from the fourth digit multiplying by 5. “T” means the basic grade for monofilament application and the grade contain some additives for maintain good process stability and high trans-parency. In case of “MT”, means monomer con-taining grade offering good flexibility and softness. 10: Polyamide 6 homopolymer 50: Polyamide 6/66 copolymer 70: Polyamide 6/12 copolymer Ex. 1022FDX04: : c.a. 22 x 1,000 = 22,000 Ex. 5034MTX1: : level = 3 (high viscosity) : c.a. 80/20(4 x 5 = 20et%) : monomer-contain type 2 Introduction

常用材料的热物性参数

表1 各种金属的热物性值 温度 C 比热 cal/(g·C) 导热系数 cal/(cm·s· C) 密度(g/cm3)液相 线、固相线温度 (C) =7.88(20C) =7.3(1500C) =7.0(1600C) =7.86(15C) =7.86(15C) =7.85(15C) =7.85(15C) =7.83(15C)

续表1 各种金属的热物性值 温度 C 比热 cal/(g·C) 导热系数 cal/(cm·s· C) 密度(g/cm3)液相 线、固相线温度 (C) =7.73(15C) Ts=1488 T L=1497 =7.84(15C) T S=1420 T L=1520 =7.7(15C) 13.1Cr,0.5Ni T S=1399 T L=1454 =7.0(15C) 比热相对于 普通铸铁

=7.1(15C) 温度 C 比热 cal/(g·C) 导热系数 cal/(cm·s· C) 密度(g/cm3)液相 线、固相线温度 (C) =7.5~7.8(15C) =8.92 T S=T L=1083

s=2.70(15C) T S=T M=660.2 温度 C 比热 cal/(g·C) 导热系数 cal/(cm·s· C) 密度(g/cm3)液相 线、固相线温度 (C) s=1.74 T L=T S=651 s=6.09 T S=1395 T L=1427

表2 铸型的热物性计算公式

硅砂，干型，呋喃铸型600C以下 0.385<<0.494 0.0058

材料物性表

Product Data Sheet CHARACTERISTICS TEST METHOD Physical Properties Specific Gravity ASTM D792 1.20 1.20 Mould Shrinkage ASTM D9550.1-0.3%0.001-0.003in/in Mechanical Properties Tensile Strength ASTM D63890MPa 13050psi Flexural Strength ASTM D790125MPa 18125psi Flexural Modulus ASTM D7906500MPa 943ksi Notched Izod Impact Strength (3.2mm) ASTM D256 85 J/m 1.6 ft-lb/in Thermal Properties Heat Deflection Temperature @ 1.82MPa (264 psi) ASTM D648145°C 293°F Electrical Properties Surface Resistivity ASTM D2571E15ohms 1E15ohms Description: Glass Fiber Reinforced Polypropylene PPR 40G NC702 Product Code: 5218702Internal Code: NATURAL Colour: Maxxam TM NOMINAL VALUE (SI)NOMINAL VALUE (ENGLISH)Flammability Properties Flame Rating @ 0.8mm Internal HB HB Processing Conditions PP Barrel Temperature 200-240 °C 392-464°F Mould Temperature 30-60 °C 86-140°F Drying Temperature 80-85 °C 176-185°F Drying Time 2-3 Hour 2-3 Hour Injection Pressure Hold Pressure Screw Speed Back Pressure Rev #: 0, Revision Date: 6/8/2010 PRINTED IN SHENZHEN LHM 33587 Walker Road,Avon Lake,Ohio 44012, USA, Tel 1-440-930 1000 WHEN YOU HAVE QUESTION WITH ENGINEERING PLASTICS, WE COMPOUND THE ANSWER. No.1, Qihang Industrial Park,Haoxiang Road, Shajing Town, Baoan,Shenzhen, P.R.China,Tel:86-755-29692888MODERATE MED-HIGH MED-HIGH THIS IS NOT A PRODUCT SPECIFICATION LOW THE INFORMATION PRESENTED HEREIN IS PRESENTED IN GOOD FAITH AND TO THE BEST OF OUR KNOWLEDGE IS TRUE AND ACCURATE. IT IS INTENDED AS A GUIDE AND IS OFFERED FOR USE AT YOUR DISCRETION AND RISK. POLYONE DOES NOT GUARANTEE RESULT AND DISCLAIM ANY LIABILITY INCURRED IN CONNECTION WITH THE USE OF THE PRODUCTS DESCRIBED OR THE INFORMATION PRESENTED Tel: 86-755-29692888

物性表

Safety Data Sheet complies with:directive 91/155/EEC revision:2.0 ISO 11014-1:Safety data sheet for chemical products. revision date:02/02/1998date of issue: 26/02/1998 p 1. Product and company identification Product name:Stanyl ?Product code:TE250F3 Manufacturer: DSM Engineering Plastics P.O. Box 43,6130 AA Sittard The Netherlands Emergency number: The Netherlands +31 (0)46 4 76 55 55 2. Composition/Information on ingredients This chemical product is a preparation Chemical nature:(poly)amide PA 46CAS number:50327-22-5Components contributing to the hazard: The material contains Sb 2O 3 as a synergist with an average content of max. 7%. Sb 2O 3 is classified as a harmful (Xn) substance with a risk phrase R40 carcinogen class 3. However, the Sb 2O 3 is embedded in an impervious matrix of polymer and is therefore less biological available than the free Sb 2O 3 (see also Section 15). 3. Hazards identification Most important hazards:Hazard warning not required Specific hazards: Vapour and fumes released at elevated processing temperatures may be irritant for the eyes, the nose, the throat and the respiratory tract and in case of overexposure may cause nausea and headache. The material is not classified as being a dangerous preparation according to the EEC-Directive 88/379 and the subsequent amendments. See also Section 15.4. First-Aid measures Inhalation: When fumes of molten material have been inhaled;- Move person to fresh air as quickly as possible - rest in half upright position - loosen clothing - keep warm In case of respiratory problems move person to first aid station for medical treatment.Skin contact: Any molten material on the skin/burns should be cooled (off) as quickly as possible by means of cold water.Cover the wound with sterile cloth and move person to first aid station or hospital for medical treatment.Attention: never pull off the molten material from the wound.Eye contact: Any material entering the eye should be flushed out with copious volumes of water.Ingestion: No danger of toxicity, this material is biologically inactive (see also Section 11). 5. Fire-fighting measures Extinguishing media: Water, water/foam, CO 2, ABC fire extinguisher powder.Specific Hazards: Treat the material as a solid that can burn. Moulded parts or solid granules generally burn slowly with flaming drips.

常用塑胶原料之物性1

塑料原料之物性说明 一流动特性(FLOW PROPERTIES) 热塑性塑料成型过程一般需经历加热塑化, 流动成型和冷却固化三个基本步骤.所谓加热塑化就是经过加热使固体高聚物变成粘性流体; 流动成型是借助注射机或挤塑机的柱塞或螺杆的移动,以很高的压力将粘性流体注入温度较低的闭合模具内,或以很高的压力将粘性流体从所要求形状的口模挤出,得到连续的型材;冷却固化是用冷却的方法使制品从粘流态变成玻璃态.几乎所有高聚物都是利用其粘流态下的流动行为进行加工成型的.表征流动特性的物理量如下: 1.熔融指数值(MELT INDEX) 熔融指数是评价热塑性聚合物特别是聚烯烃的挤压性的一种简单而实用的方法,其定义为: 在一定温度下, 熔融状态的高聚物在一定负荷下, 十分锺内从规定直径和长度的标准毛细管中流出的重量.其一般在熔融指数仪中测定. 可挤压性是指聚合物通过挤压作用形变时获得形状和保持形状的能力, 研究聚合物的挤出性质能对制品的材料和加工工艺作出正确的选择和控制,通常条件下,聚合物在固体状态不能通过挤压而成型,只有当聚合物处于粘流态时才能通过挤压获得宏观而有用的形变.挤压过程中,聚合物熔体主要受到剪切作用,故可挤压性主要取决于熔体的剪切粘度和拉伸粘度.大多数聚物熔体的粘度随剪切力或剪切速率增大而降低.. 熔融指数仪测定在给定剪切力下聚合物的流动度,用定温下10分锺内聚合物从出料孔挤出的重量(克)来表示,其数值就称为熔融指数. 所以流动度,即熔融指数实际上反映了聚合物分子量的大小,分子量较高的聚合物更易于缠结,分子体积更大,故有较大的流动阴力,表现出较高的粘度和低的流动度,亦即熔融指数低. 由于荷重小(1.2kgf)通测定的MI值不能说明注射或挤出成型时聚合物的实际流动性能.但用[MI]值能方便地表示聚合物流动性的高低. 2. 粘度VISCOSITY ( Psi *S) 粘度是表征流动性的一种性能, 一般粘度越大, 流动性越差. 1)剪切粘度 对应于剪切流动,即速度梯度的方向与流动方向相垂直. 粘度对剪切速率具有依赖性. 测量方法: 一般由奥氏粘度计和乌氏粘度计进行测量. 影响剪切粘度的因素如下: a)聚合物本身结构 粘度随分子量的增加而提高. b)温度 随温度升高, 粘度呈指数函数的方式降低. c)剪切速率 剪切速率增大, 粘度减小. d)剪切应力. 剪切应力增大, 粘度减小. e)压力 压力增大, 粘度增大.

PVC物性表

物质安全资料表 一．物品与厂商资料：物品名称：ＰＶＣ塑胶物品编号：无资料 制造商或供应商名称：XXXXXXX塑胶有限公司联系电话：0769-XXXXXXXx 二．成分辨识资料 成分名称ＰＶＣ粉45-60可塑剂18-30填充剂27-30安定剂 1.5-2.0滑　剂 0.5-1.0 三.危害辨识资料: 四.急救措施 不同暴露途径之急救方法:.吸入:未有资料 .皮肤接触:粉尘与颗粒触到皮肤用清洁剂与清水清洗,严重时送医治..食入:用手按喉吐出,严重时送医院治疗.最重要症状及危害效应:燃烧时产生氯化物对急救人员之防护:无资料对医师之提示:无资料五.灭火措施 适用灭火剂:二氧化碳 灭火时可能遭遇之特殊危害:防止口腔及眼睛长时间接触特殊灭火程序:无资料 消防人员之特殊防护设备:口罩和手套六.泄漏处理方法: 个人应注意事项:佩带口罩 手套环境注意事项:回收及收取飞散之物清理方法:设有良好的通风排气装置七.安全处置与储存方法: 处置:使用时不要品尝胶料味道,保持通风使空气循环 储存:1.储于阴凉、通风良好的的地区，远离热源、火花、火焰2.避免阳光直接照射，以免老化 物品危害分类:无含量(%)主要物质成分ＣＡＳ　ＮＯ．（化学文摘社登记号码） 主要症状:呕吐 ９００２-８６-２２６７６１-４０-０００４７１-３４-１００５５７-０５-１ 最重要危害效应健康危害效应:无 环境影响:环保产品 低铅低镉 物理性及化学性危害:燃烧时产生氯化物及轻微气味和粉尘 特殊危害:无

3.于其他可燃物隔离八.暴露预防措施：工程控制：无资料 控制参数：八小时日时平均容许浓度/短时间量平均容许浓度/最高容许浓度.呼吸防护：佩带口罩.手部防护：清水清洗 .眼睛防护：清水清洗，严重时送医院治疗 .皮肤及身体防护：清水清洗，严重时送医院治疗九.物理及化学性质十.安全性及反应性：安定性：安定 特殊状况下可能之危害反应：不会发生应避免之物质：强氧化剂、强酸、强碱危害分解物：氯化物十一.毒性资料：急毒性：无局部效应：无致敏感性：无 慢毒性或长期毒性：无资料特殊效应：无资料十二.生态资料： 不能弃于水域、林域地带，避免鸟鱼摄取十四.运输资料 国际运输规定：无资料联合国编号：无 国内运输规定：无资料特殊运输方法及注意事项： 避免同酸性物质一起运输，如发生意外而泄漏要立即收回十五.法规资料： 相关法规：消防法 卫生法十六.其他资料：参考文献 制表单位制表人 名称：XXXXXXXXXXXXX塑胶有限公司 地址： 职称： 姓名：熔点：130℃保存期：六个月蒸汽密度：无资料水中溶解度：不溶解 密度：1.3-1.5克每立方厘米物质状态：固体颜色：多色成型参考温度：170~180℃PH值：无 自然温度：常温蒸汽压：无资料、 形状：颗粒状气味：稍有异味

各种塑料基本物性表

塑膠原材料物性表 材料名稱密度收縮率成本USD/kg燃燒狀態料管溫度射出壓力 (Kg/cm2)模溫 (C°)用途ABS (BK) 1.42~2.4 ABS (HB COLOR) 1.05 1.42~1.75/450 ABS (HB GF10) 1.2 1.75~3.72/about 500 ABS (HB GF20) 1.220.002 2.19/60-80 ABS (HB GF30) 2.25~4.26/ ABS (Natural) 1.25~2.4/ ABS (PA/757BK) 1.53~1.75/ ABS (PA/765AB) 2.2/ ABS (V0 GF10) 1.2 3.86/about 500 ABS (V0) 1.05 1.42~2.11 ABS (透明) 1.96~2.06 ABS (Acrylonitrile Butadiene Styrene)丙烯睛-丁二烯-苯乙烯1.05~1.1 0.005 1.25~2.4 易燃, 暗黃,有黑煙. 軟 化.特有氣味. 硬, 脆. 金 屬聲 180~260450~210050~80 電器,日用品外殼,玩具,家具,運動用品,燈 飾,汽車配件 AS (GF20) 1.260.002210-28060-80 AS=SAN(Styrene-Acrylonitrile Copolymer)丙烯睛-苯乙烯1.06 0.004/190~280 700~2300 40~80 食具,日用品,透明裝飾面,主表面 EPS 發泡膠 Expanded PolyStyrene貨品包裝,絕緣板, 裝飾品 EVA 乙烯-醋酸乙烯共聚物. Ethlene-Vinyl Acetate Copolymer橡皮膠120~25030~50鞋底,吹氣玩具製品,包裝膠膜 HIPS (BW-4(H45))/ HIPS (HB) 高衝擊聚苯乙烯 High Impact PS/ 1.1~1.3/ HIPS (PA-765BK) 2.2耐沖擊.玩具,日用品,收音機殼,電視機殼. HIPS (V0)/ 1.55 PA +GF30 (V0)260~29050~90 PA 66 (HB)/250~31050~90噪音小,軟. 牙刷,線圈架, 拉絲,束帶,齒輪,電動玩具外殼,電器配件,運動用品 PC(GE10G15) 5.508/ PC(GF40) 1.820.15%270-31080-120 PC(HB) 3.63 PC(L-1250YN) 1.2 3.7/ PC(N) 聚碳酸脂. 防彈膠 Polycarbonate 1.2 0.60% 4.2~4.75 稍難燃, 黃色焰,黑煙. 軟化. 特有味 260~300 (330劣化) 700~2100 85~120 咖啡壺,電動工具外殼,安全頭盔,透明片, 防硬玻璃,電器零件 PC(透明) 4.0~4.2 PC+ABS 2.32~2.98 PC+ABS (FR2000, V0) 4.485215~240about 75060~80 PC+ABS (KU2-1468,V0)240~280about 75060~90 材料名稱密度收縮率成本USD/kg燃燒狀態料管溫度射出壓力 (Kg/cm2)模溫 (C°)用途 PE 聚乙烯1.14 0.45% 易燃, 尖端黃,下端藍. 邊滴邊燃. 石腊燃燒味170-25040-60 PE (Polyethlene)0.95 3.50%150-23020-40包裝膠袋,膠瓶,水桶,電線,大貨桶,玩具PE(High Density PE) 高密160~310700~140025~70包裝膠袋,膠瓶,膠花,電線,大貨桶,玩具PE(Low Density PE) 低密150~310600~140025~70包裝膠袋,膠瓶,水桶,電線,大貨桶

物性表

DuPont ? Zytel ? nylon resin Zytel ? 101L NC010 Value DAM 50%RH Identification Resin Identification ISO 1043PA66 Part Marking Code ISO 11469>PA66< Mechanical Yield Stress ISO 527MPa (kpsi) 82 (11.9)55 (8.0) Strain at Break ISO 527% 50mm/min 45 Nominal Strain at Break ISO 527%25>100 Yield Strain ISO 527% 4.525 Tensile Modulus ISO 527MPa (kpsi)3100 (450) 1400 (200) Tensile Creep Modulus ISO 899 MPa (kpsi) 1h 1400 (200) 1000h 820 (119) Poisson's Ratio 0.41 Flexural Modulus ISO 178MPa (kpsi)2800 (410) 1200 (174) Notched Charpy Impact Strength ISO 179/1eA kJ/m 2 -30°C (-22°F) 4.53 23°C (73°F) 5.515 Unnotched Charpy Impact Strength ISO 179/1eU kJ/m 2 -30°C (-22°F)400NB 23°C (73°F) NB NB Contact DuPont for Material Safety Data Sheet, general guides and/or additional information about ventilation, handling, purging, drying, etc.ISO Mechanical properties measured at 4.0mm, ISO Electrical properties measured at 2.0mm, and all ASTM properties measured at 3.2mm. Test temperatures are 23°C unless otherwise stated. The DuPont Oval Logo, DuPont?, The miracles of science? and Zytel? are trademarks or registered trademarks of DuPont Company. Copyright? 2005. 050630/050630 The information provided in this data sheet corresponds to our knowledge on the subject at the date of its publication. This information may be subject to revision as new knowledge and experience becomes available. The data provided fall within the normal range of product properties and relate only to the specific material designated; these data may not be valid for such material used in combination with any other materials, additives or pigments or in any process, unless expressly indicated otherwise. The data provided should not be used to establish specification limits or used alone as the basis of design; they are not intended to substitute for any testing you may need to conduct to determine for yourself the suitability of a specific material for your particular purposes. Since DuPont cannot anticipate all variations in actual end-use conditions DuPont makes no warranties and assumes no liability in connection with any use of this information. Nothing in this publication is to be considered as a license to operate under or a recommendation to infringe any patent rights. DuPont advises you to seek independent counsel for a freedom to practice opinion on the intended application or end-use of our products. Caution: Do not use this product in medical applications involving permanent implantation in the human body. For other medical applications see "DuPont Medical Caution Statement", H-50102. https://www.360docs.net/doc/e08113286.html, Zytel ? 101L NC010 is a lubricated polyamide 66 resin for injection molding. Property Test Method Units