复合材料注塑成型中英文对照外文翻译文献
复合材料注塑成型中英文对照外文翻译文献(文档含英文原文和中文翻译)
An experimental study of the water-assisted injection molding ofglass fiber filled poly-butylene-terephthalate
(PBT) composites
Abstract:The purpose of this report was to experimentally study the water-assisted injection molding process of poly-butylene-terephthalate(PBT) composites. Experiments were carried out on an 80-ton injection-molding machine equipped with a lab scale water injection system,which included a water pump, a pressure accumulator, a water injection pin, a water tank equipped with a temperature regulator,and a control circuit. The materials included virgin PBT and a 15% glass fiber filled PBT composite, and a plate cavity with a rib across center was used. Various processing variables were examined in terms of their influence on the length of water penetration in molded parts, and mechanical property tests were performed on these parts. X-ray diffraction (XRD) was also used to identify the material and
structural parameters. Finally, a comparison was made between water-assisted and gas-assisted injection molded parts. It was found that the melt fill pressure, melt temperature, and short shot size were the dominant parameters affecting water penetration behavior.Material at the mold-side exhibited a higher degree of crystallinity than that at the water-side. Parts molded by gas also showed a higher degree of crystallinity than those molded by water. Furthermore, the glass fibers near the surface of molded parts were found to be oriented mostly in the flow direction, but oriented substantially more perpendicular to the flow direction with increasing distance from the skin surface.
Keywords: Water assisted injection molding; Glass fiber reinforced poly-butylene-terephthalate (PBT) composites; Processing parameters; B. Mechanical properties; Crystallinity; A. Polymer matrix composites;
1. Introduction
Water-assisted injection molding technology [1] has proved itself a breakthrough in the manufacture of plastic parts due to its light weight, faster cycle time, and relatively lower resin cost per part. In the water-assisted injection molding process, the mold cavity is partially filled with the polymer melt followed by the injection of water into the core of the polymer melt. A schematic diagram of the water-assisted injection molding process is illustrated in Fig. 1.Water-assisted injection molding can produce parts incorporating both thick and thin sections with less shrink-age and warpage and with a better surface finish, but with a shorter cycle time. The water-assisted injection molding process can also enable greater freedom of design, material savings, weight reduction, and cost savings in terms of tooling and press capacity requirements [2–4]. Typical applications include rods and tubes, and large sheet-like structural parts with a built-in water channel network. On the other hand, despite the advantages associated with the process,the molding window and process control are more critical and difficult since additional processing parameters are involved. Water may also corrode the steel mold, and some materials including thermoplastic composites are difficult to mold successfully. The removal of water after molding is also a challenge for this novel technology. Table 1 lists the advantages and limitations of water-assisted injection molding technology.
Fig. 1. Schematic diagram of water-assisted injection molding process.
Water assisted injection molding has advantages over its better known competitor process, gas assisted injection molding [5], because it incorporates a shorter cycle time to successfully mold a part due to the higher cooling capacity of water during the molding process. The incompressibility,
low cost, and ease of recycling the water makes it an ideal medium for the process. Since water does not dissolve and diffuse into the polymer melts during the molding process, the internal foaming phenomenon [6] that usually occurs in gas-assisted injection molded parts can be eliminated.In addition, water assisted injection molding provides a better capability of molding larger parts with a small residual wall thickness. Table 2 lists a comparison of water and gas assisted injection molding.With increasing demands for materials with improved performance, which may be characterized by the criteria of lower weight, higher strength, and a faster and cheaper production cycle time, the engineering of plastics is a process that cannot be ignored. These plastics include thermoplastic and thermoset polymers. In general, thermoplastic polymers have an advantage over thermoset polymers in popular materials in structural applications.Poly-butylene-terephthalate (PBT) is one of the most frequently used engineering thermoplastic materials, whichis formed by polymerizing 1.4 butylene glycol and DMT together. Fiber-reinforced composite materials have been adapted to improve the mechanical properties of neat plastic materials. Today, short glass fiber reinforced PBT is widely used in electronic, communication and automobile applications. Therefore, the investigation of the processing of fiber-reinforced PBT is becoming increasingly important[7–10].This report was made to experimentally study the waterassisted injection molding process of poly-butylene-terephthalate (PBT) materials. Experiments were carried out on an 80-ton injection-molding machine equipped with a lab scale water injection system, which included a water pump, a pressure accumulator, a water injection pin, a water tank equipped with a temperature regulator, and a control circuit. The materials included a virgin PBT and a 15% glass fiber filled PBT composite, and a plate cavity with a rib across center was used. Various processing variables were examined in terms of their influence on the length of water penetration in molded parts, which included melt temperature, mold temperature, melt filling speed, short-shot size, water pressure, water temperature,water hold and water injection delay time. Mechanical property tests were also performed on these molded parts,and XRD was used to identify the material and structural parameters. Finally, a comparison was made betweenwater-assisted and gas-assisted injection molded parts.
Table 1
2. Experimental procedure
2.1. Materials
The materials used included a virgin PBT (Grade 1111FB, Nan-Ya Plastic, Taiwan) and a 15% glass fiber filled PBT composite (Grade 1210G3, Nan-Ya Plastic, Taiwan).Table 3 lists the characteristics of the composite materials.
2.2. Water injection unit
A lab scale water injection unit, which included a water pump, a pressure accumulator, a water injection pin, a water tank equipped with a temperature regulator, and a control circuit, was used for all experiments [3]. An orifice-type water injection pin with two orifices (0.3 mm in diameter) on the sides was used to mold the parts. During the experiments, the control circuit of the water injection unit received a signal from the molding machine and controlled the time and pressure of the injected water. Before injection into the mold cavity, the water was stored in a tank with a temperature regulator for 30 min to sustain an isothermal water temperature.
2.3. Molding machine and molds
Water-assisted injection molding experiments were conducted on an 80-ton conventional injection-molding machine with a highest injection rate of 109 cm3/s. A plate cavity with a trapezoidal water channel across the center was used in this study. Fig. 2 shows the dimensions of
the cavity. The temperature of the mold was regulated by a water-circulating mold temperature control unit. Various processing variables were examined in terms of their influence on the length of water penetration in water channels of molded parts: melt temperature, mold temperature, melt
fill pressure, water temperature and pressure, water injection delay time and hold time, and short shot size of the polymer melt. Table 4 lists these processing variables as well as the values used in the experiments.
2.4. Gas injection unit
In order to make a comparison of water and gas-assisted injection molded parts, a commercially available gas injection unit (Gas Injection PPC-1000) was used for the gas assisted injection molding experiments. Details of the gas injection unit setup can be found in the Refs. [11–15].The processing conditions used for gas-assisted injection molding were the same as that of water-assisted injection molding (terms in bold in Table 4), with the exception of gas temperature which was set at 25 C.
2.5. XRD
In order to analyze the crystal structure within the water-assisted injection-molded parts, wide-angle X-ray diffraction (XRD) with 2D detector analyses in transmission mode were performed with Cu Ka radiation at 40 kV and 40 mA. More specifically, the measurements were performed on the mold-side and
water-side layers of the water-assisted injection-molded parts, with the 2h angle ranging from 7 to 40 . The samples required for these analyses were taken from the center portion of these molded parts. To obtain the desired thickness for the XRD samples, the excess was removed by polishing the
Table 3
samples on a rotating wheel on a rotating wheel, first with wet silicon carbide papers, then with 300-grade silicon carbide paper, followed by 600- and 1200-grade paper for
a better surface smoothness.
2.6. Mechanical properties
Tensile strength and bending strength were measured on a tensile tester. Tensile tests were performed on specimens obtained from the water-assisted injection molded parts (see Fig. 3) to evaluate the effect of water temperature on the tensile properties. The dimensions of specimens for
the experiments were 30 mm · 10 mm · 1 mm. Tensile tests were performed in a LLOYD tensiometer according to the ASTM D638M test. A 2.5 kN load cell was used and the crosshead speed was 50 mm/min.
Bending tests were also performed at room temperature on water-assisted injection molded parts. The bending specimens were obtained with a die cutter from parts (Fig. 3) subjected to various water temperatures.The dimensions of the specimens were 20 mm · 10 mm · 1 mm. Bending tests were performed in a micro tensile tester according to the ASTM D256 test. A 200 N load cell was used and the crosshead speed was 50 mm/min.
2.7. Microscopic observation
The fiber orientation in molded specimens was observed under a scanning electron microscope (Jeol Model 5410).Specimens for observation were cut from parts molded by water-assisted injection molding across the thickness (Fig. 3). They were observed on the cross-section perpendicular to the flow direction. All specimen surfaces were gold sputtered before observation.
3. Results and discussion
All experiments were conducted on an 80-ton conventional injection-molding
machine, with a highest injection rate of 109 cm3/s. A plate cavity with a trapezoidal water channel across the center was used for all experiments
Table 4
Fig. 3. Schematically, the positioning of the samples cut from the molded parts for tensile and bending tests and microscopic observations.
3.1. Fingerings in molded parts
All molded parts exhibited the water fingering phenomenon at the channel to plate transition areas. In addition,molded glass fiber filled composites showed more severe water fingerings than those of non-filled materials, as shown photographically in Fig. 4. Fingerings usually form when a less dense, less viscous fluid penetrates a denser,more viscous fluid immiscible with it. Consider a sharp two phase interface or zone where density and viscosity change rapidly. The pressure force (P2 P1) on the displaced fluid as a result of a virtual displacement dx of the interface can be described by [16], where U is the characteristic velocity and K is the permeability.If the net pressure force is positive, then any small displacement will be amplified and lead to an instability
and part fingerings. For the displacement of a dense, viscous fluid (the polymer melt) by a lighter, less viscous one (water), we can have Dl = l1 l2 > 0, and U > 0 [16].In this case, instability and the relevant fingering result when a more viscous
fluid is displaced by a less viscous one, since the less viscous fluid has the greater mobility.The results in this study suggest that glass fiber filled composites exhibit a higher tendency for part fingerings. This might be due to the fact that the viscosity difference Dl between water and the filled composites is larger than the difference between water and the non-filled materials. Waterassisted injection molded composites thus exhibit more severe part fingerings.
Fig. 4. Photograph of water-assisted injection molded PBT composite part.
3.2. Effects of processing parameters on water penetration
Various processing variables were studied in terms of their influence on the water penetration behavior. Table 4 lists these processing variables as well as the values used in the experiments. To mold the parts, one central processing condition was chosen as a reference (bold term in Table
By changing one of the parameters in each test, we were able to better understand the effect of each parameter on the water penetration behavior of water assisted injection molded composites. After molding, the length of water penetration was measured. Figs. 5–10 show the effects of these processing parameters on the length of water penetration in molded parts, including melt fill pressure, melt temperature, mold temperature, short shot size, water temperature, and water pressure.The experimental results in this study suggest that water penetrates further in virgin PBT than in glass fiber filled PBT composites. This is due to the fact that with the reinforcing glass fibers the composite materials have less volumetric shrinkage during the cooling process. Therefore,they mold parts with a shorter water penetration length.The length of water penetration decreases with the melt fill pressure (Fig. 5). This can be explained by the fact that increasing the melt fill pressure increases the flow resistance inside the mold cavity. It is then more difficult for the water to penetrate into the core of the materials. The length of water penetration decreases accordingly [3].The melt temperature was also found to reduce the water penetration in molded PBT composite parts (Fig. 6). This might be due to the fact that increasing the melt temperature decreases viscosity of the polymer melt.A lower viscosity of the materials helps the water to pack
the water channel and increase its void area, instead of penetrating further into the
parts [4]. The hollow core ratio at the beginning of the water channel increases and the length of water penetration may thus decrease.Increasing the mold temperature decreases somewhat the length of water penetration in molded parts (Fig. 7).This is due to the fact that increasing the mold temperature decreases the cooling rate as well as the viscosity of the materials. The water then packs the channel and increases its void area near the beginning of the water channel,instead of penetrating further into the parts [3]. Molded parts thus have a shorter water penetration length.Increasing the short shot size decreases the length of water penetration (Fig. 8). In water-assisted injection molding, the mold cavity is partially filled with the polymer melt followed by the injection of water into the core of the polymer melt [4]. Increasing the short shot size of the polymer melt will therefore decrease the length of water penetration in molded parts.For the processing parameters used in the experiments,increasing the water temperature (Fig. 9) or the water pressure(Fig. 10) increases the length of water penetration in molded parts. Increasing the water temperature decreases the cooling rate of the materials and keeps the polymer melt hot for a longer time; the viscosity of the materials decreases accordingly. This will help the water penetrate
further into the core of the parts [3]. Increasing the water pressure also helps the water penetrate into the materials.The length of water penetration thus increases.Finally, the deflection of molded parts, subjected to various processing parameters, was also measured by a profilemeter.The maximum measured deflection is considered as the part warpage. The result in Fig. 11 suggests that the part warpage decreases with the length of water penetration.This is due to the fact that the longer the water penetration,the more the water pressure can pack the polymeric materials against the mold wall. The shrinkage as well as the relevant part warpage decreases accordingly.
Fig. 5. Effects of melt fill pressure on the length of water penetration in molded parts.
Fig. 6. Effects of melt temperature on the length of water penetration in molded parts.
Fig. 9. Effects of water temperature on the length of water penetration in molded
parts.
Fig. 7. Effects of mold temperature on the length of water penetration in molded parts.
Fig. 8. Effects of short shot size on the length of water penetration inmolded parts.
Fig. 10. Effects of water pressure on the length of water penetration inmolded parts.
3.3. Crystallinity of molded parts
PBT is a semi-crystalline thermoplastic polyester with a high crystallization rate. In the water-assisted injection molding process, crystallization occurs under non-isothermal conditions in which the cooling rate varies with cooling time. Here the effects of various processing parameters
(including melt temperature, mold temperature, and water temperature) on the level of crystallinity in molded parts were studied. Measurements were conducted on
a wideangle X-ray diffraction (XRD) with 2D detector analyses(as described in Section 2). The measured results in Fig. 12 showed that all materials at the mold-side lay erexhibited a higher degree of crystallinity than those at the water-side layer. The result indicates that the water has a better cooling capacity than the mold during the cooling process. This matches our earlier finding [17] by measuring the in-mold temperature distribution. In addition, the experimental result in Fig. 12c also suggests that the crystallinity of the molded materials generally increases with the water temperature. This is due to the fact that increasing the water temperature decreases the cooling rate of the materials during the cooling process. Molded parts thus exhibited a higher level of crystallinity.On the other hand, to make a comparison of the crysallinity of parts molded by gas and water, gas-assisted injection molding experiments were carried out on the same injection molding machine as that used with water, but equipped with a high-pressure nitrogen gas injection unit [11–15]. The measured results in Fig. 13 suggests that gas-assisted injection molded parts have a higher degree of crystallinity than water-assisted injection mold parts.This is due to the fact that water has a higher cooling capacity and cools down the parts faster than gas. Parts molded by water thus exhibited a lower level of crystallinity than those molded by gas.
Fig. 11. Measured warpage of molded parts decreases with the length of water
penetration.
3.4. Mechanical properties
Tensile tests were performed on specimens obtained from the water-assisted injection molded parts to examine the effect of water temperature on the tensile properties.Fig. 14 showed the measured decrease subjected to various water temperatures. As can be observed, both yield strength and the elongational strain at break of water assisted molded PBT materials decrease with the water temperature. On the other hand, bending tests were also performed at room temperature on water-assisted injection molded parts. The measured result in Fig. 15 suggests that the bending strength of molded parts decreases with the water temperature.Increasing the water temperature generally decreases the cooling rate and molds parts with higher level of crystallin-content of free volume and therefore an increasing level of stiffness. However, the experimental results here suggest that the quantitative contribution of crystallinity to PBT’s mechanical properties is negligible, while there is a more important quantitative increase of tensile and bending strength for the PBT materials.
复合材料与工程专业毕业设计外文文献翻译
毕业设计外文资料翻译 题目POLISHING OF CERAMIC TILES 抛光瓷砖 学院材料科学与工程 专业复合材料与工程 班级复材0802 学生 学号20080103114 指导教师 二〇一二年三月二十八日
MATERIALS AND MANUFACTURING PROCESSES, 17(3), 401–413 (2002) POLISHING OF CERAMIC TILES C. Y. Wang,* X. Wei, and H. Yuan Institute of Manufacturing Technology, Guangdong University ofTechnology, Guangzhou 510090, P.R. China ABSTRACT Grinding and polishing are important steps in the production of decorative vitreous ceramic tiles. Different combinations of finishing wheels and polishing wheels are tested to optimize their selection. The results show that the surface glossiness depends not only on the surface quality before machining, but also on the characteristics of the ceramic tiles as well as the performance of grinding and polishing wheels. The performance of the polishing wheel is the key for a good final surface quality. The surface glossiness after finishing must be above 208 in order to get higher polishing quality because finishing will limit the maximum surface glossiness by polishing. The optimized combination of grinding and polishing wheels for all the steps will achieve shorter machining times and better surface quality. No obvious relationships are found between the hardness of ceramic tiles and surface quality or the wear of grinding wheels; therefore, the hardness of the ceramic tile cannot be used for evaluating its machinability. Key Words: Ceramic tiles; Grinding wheel; Polishing wheel
建筑结构设计中英文对照外文翻译文献
中英文对照外文翻译 (文档含英文原文和中文翻译) Create and comprehensive technology in the structure global design of the building The 21st century will be the era that many kinds of disciplines technology coexists , it will form the enormous motive force of promoting the development of building , the building is more and more important too in global design, the architect must seize the opportunity , give full play to the architect's leading role, preside over every building engineering design well. Building there is the global design concept not new of architectural design,characteristic of it for in an all-round way each element not correlated with building- there aren't external environment condition, building , technical equipment,etc. work in coordination with, and create the premium building with the comprehensive new technology to combine together. The premium building is created, must consider sustainable development , namely future requirement , in other words, how save natural resources as much as possible, how about protect the environment that the mankind depends on for existence, how construct through high-quality between architectural design and building, in order to reduce building equipment use quantity and
中英文参考文献格式
中文参考文献格式 参考文献(即引文出处)的类型以单字母方式标识: M——专著,C——论文集,N——报纸文章,J——期刊文章,D——学位论文,R——报告,S——标准,P——专利;对于不属于上述的文献类型,采用字母“Z”标识。 参考文献一律置于文末。其格式为: (一)专著 示例 [1] 张志建.严复思想研究[M]. 桂林:广西师范大学出版社,1989. [2] 马克思恩格斯全集:第1卷[M]. 北京:人民出版社,1956. [3] [英]蔼理士.性心理学[M]. 潘光旦译注.北京:商务印书馆,1997. (二)论文集 示例 [1] 伍蠡甫.西方文论选[C]. 上海:上海译文出版社,1979. [2] 别林斯基.论俄国中篇小说和果戈里君的中篇小说[A]. 伍蠡甫.西方文论选:下册[C]. 上海:上海译文出版社,1979. 凡引专著的页码,加圆括号置于文中序号之后。 (三)报纸文章 示例 [1] 李大伦.经济全球化的重要性[N]. 光明日报,1998-12-27,(3) (四)期刊文章 示例 [1] 郭英德.元明文学史观散论[J]. 北京师范大学学报(社会科学版),1995(3). (五)学位论文 示例 [1] 刘伟.汉字不同视觉识别方式的理论和实证研究[D]. 北京:北京师范大学心理系,1998. (六)报告 示例 [1] 白秀水,刘敢,任保平. 西安金融、人才、技术三大要素市场培育与发展研究[R]. 西安:陕西师范大学西北经济发展研究中心,1998. (七)、对论文正文中某一特定内容的进一步解释或补充说明性的注释,置于本页地脚,前面用圈码标识。 参考文献的类型 根据GB3469-83《文献类型与文献载体代码》规定,以单字母标识: M——专著(含古籍中的史、志论著) C——论文集 N——报纸文章 J——期刊文章 D——学位论文 R——研究报告 S——标准 P——专利 A——专著、论文集中的析出文献 Z——其他未说明的文献类型 电子文献类型以双字母作为标识: DB——数据库 CP——计算机程序 EB——电子公告
中英文论文对照格式
英文论文APA格式 英文论文一些格式要求与国内期刊有所不同。从学术的角度讲,它更加严谨和科学,并且方便电子系统检索和存档。 版面格式
表格 表格的题目格式与正文相同,靠左边,位于表格的上部。题目前加Table后跟数字,表示此文的第几个表格。 表格主体居中,边框粗细采用0.5磅;表格内文字采用Times New Roman,10磅。 举例: Table 1. The capitals, assets and revenue in listed banks
图表和图片 图表和图片的题目格式与正文相同,位于图表和图片的下部。题目前加Figure 后跟数字,表示此文的第几个图表。图表及题目都居中。只允许使用黑白图片和表格。 举例: Figure 1. The Trend of Economic Development 注:Figure与Table都不要缩写。 引用格式与参考文献 1. 在论文中的引用采取插入作者、年份和页数方式,如"Doe (2001, p.10) reported that …" or "This在论文中的引用采取作者和年份插入方式,如"Doe (2001, p.10) reported that …" or "This problem has been studied previously (Smith, 1958, pp.20-25)。文中插入的引用应该与文末参考文献相对应。 举例:Frankly speaking, it is just a simulating one made by the government, or a fake competition, directly speaking. (Gao, 2003, p.220). 2. 在文末参考文献中,姓前名后,姓与名之间以逗号分隔;如有两个作者,以and连接;如有三个或三个以上作者,前面的作者以逗号分隔,最后一个作者以and连接。 3. 参考文献中各项目以“点”分隔,最后以“点”结束。 4. 文末参考文献请按照以下格式:
外文翻译
改善木粉/聚丙烯(PP)复合材料中木粉和聚丙烯间的界面支持CHENG ZHANG, KAICHANG LI 和JOHN SIMONSEN 美国俄勒冈州大学木材自然科学工程系Corvallis 2004年九月一日发表. 摘要 乙烯基N-甲酰胺接枝聚丙烯(VFPP)通过自由基接枝反应已经成功合成了。聚合物亚甲基联苯二异氰酸酯(PMDI)和VFPP都能够通过有效地相容来促进木粉/聚丙烯复合物的强度和硬度。当PMDI和VFPP一起作为一个完整的相容剂系统时,更能增强木粉/聚丙烯复合物的断裂模量和弹性模量。这种新的PMDI-VFPP相容剂系统在增强木粉/聚丙烯复合物强度和硬度方面可以比得上顺丁烯酐接枝聚丙烯。用电子显微方法研究木粉/聚丙烯复合物的表面断裂情况显示这种新型的P12MDI-VFPP相容剂系统能更好地改良木粉和聚丙烯间的界面支持。这种PMDI-VFPP相容剂系统同样可以很大程度地降低木粉/聚丙烯复合物的吸水率。在这个PMDI-VFPP相容剂系统中,PMDI的作用被认为是木粉粘合剂范畴而VFPP的作用则是在PP粘合剂的范畴。PMDI跟VFPP里的氨基团反应,因此在PMDI和VFPP之间形成了共价键。 关键词:界面支持,木粉,聚丙烯,木/塑复合物,相容剂
目录 1.绪论 (1) 2.实验 (2) 2.1.原料和分析工具 (2) 2.2乙烯基N-甲酰胺接枝聚丙烯的合成 (2) 2.3 木/PP复合材料混和过程 (2) 2.4 木粉/PP制品的模压 (3) 2.5 木粉/PP复合材料的弯曲测试 (3) 2.6 木粉/PP复合材料的吸水率 (4) 3. 结论 (5) 4. 讨论 (10) 5.小结 (11) 致谢 (12) 参考文献 (13)
土木工程外文文献翻译
专业资料 学院: 专业:土木工程 姓名: 学号: 外文出处:Structural Systems to resist (用外文写) Lateral loads 附件:1.外文资料翻译译文;2.外文原文。
附件1:外文资料翻译译文 抗侧向荷载的结构体系 常用的结构体系 若已测出荷载量达数千万磅重,那么在高层建筑设计中就没有多少可以进行极其复杂的构思余地了。确实,较好的高层建筑普遍具有构思简单、表现明晰的特点。 这并不是说没有进行宏观构思的余地。实际上,正是因为有了这种宏观的构思,新奇的高层建筑体系才得以发展,可能更重要的是:几年以前才出现的一些新概念在今天的技术中已经变得平常了。 如果忽略一些与建筑材料密切相关的概念不谈,高层建筑里最为常用的结构体系便可分为如下几类: 1.抗弯矩框架。 2.支撑框架,包括偏心支撑框架。 3.剪力墙,包括钢板剪力墙。 4.筒中框架。 5.筒中筒结构。 6.核心交互结构。 7. 框格体系或束筒体系。 特别是由于最近趋向于更复杂的建筑形式,同时也需要增加刚度以抵抗几力和地震力,大多数高层建筑都具有由框架、支撑构架、剪力墙和相关体系相结合而构成的体系。而且,就较高的建筑物而言,大多数都是由交互式构件组成三维陈列。 将这些构件结合起来的方法正是高层建筑设计方法的本质。其结合方式需要在考虑环境、功能和费用后再发展,以便提供促使建筑发展达到新高度的有效结构。这并
不是说富于想象力的结构设计就能够创造出伟大建筑。正相反,有许多例优美的建筑仅得到结构工程师适当的支持就被创造出来了,然而,如果没有天赋甚厚的建筑师的创造力的指导,那么,得以发展的就只能是好的结构,并非是伟大的建筑。无论如何,要想创造出高层建筑真正非凡的设计,两者都需要最好的。 虽然在文献中通常可以见到有关这七种体系的全面性讨论,但是在这里还值得进一步讨论。设计方法的本质贯穿于整个讨论。设计方法的本质贯穿于整个讨论中。 抗弯矩框架 抗弯矩框架也许是低,中高度的建筑中常用的体系,它具有线性水平构件和垂直构件在接头处基本刚接之特点。这种框架用作独立的体系,或者和其他体系结合起来使用,以便提供所需要水平荷载抵抗力。对于较高的高层建筑,可能会发现该本系不宜作为独立体系,这是因为在侧向力的作用下难以调动足够的刚度。 我们可以利用STRESS,STRUDL 或者其他大量合适的计算机程序进行结构分析。所谓的门架法分析或悬臂法分析在当今的技术中无一席之地,由于柱梁节点固有柔性,并且由于初步设计应该力求突出体系的弱点,所以在初析中使用框架的中心距尺寸设计是司空惯的。当然,在设计的后期阶段,实际地评价结点的变形很有必要。 支撑框架 支撑框架实际上刚度比抗弯矩框架强,在高层建筑中也得到更广泛的应用。这种体系以其结点处铰接或则接的线性水平构件、垂直构件和斜撑构件而具特色,它通常与其他体系共同用于较高的建筑,并且作为一种独立的体系用在低、中高度的建筑中。
中英文论文参考文献标准格式 超详细
超详细中英文论文参考文献标准格式 1、参考文献和注释。按论文中所引用文献或注释编号的顺序列在论文正文之后,参考文献之前。图表或数据必须注明来源和出处。 (参考文献是期刊时,书写格式为: [编号]、作者、文章题目、期刊名(外文可缩写)、年份、卷号、期数、页码。参考文献是图书时,书写格式为: [编号]、作者、书名、出版单位、年份、版次、页码。) 2、附录。包括放在正文内过份冗长的公式推导,以备他人阅读方便所需的辅助性数学工具、重复性数据图表、论文使用的符号意义、单位缩写、程序全文及有关说明等。 参考文献(即引文出处)的类型以单字母方式标识,具体如下: [M]--专著,著作 [C]--论文集(一般指会议发表的论文续集,及一些专题论文集,如《***大学研究生学术论文集》[N]-- 报纸文章 [J]--期刊文章:发表在期刊上的论文,尽管有时我们看到的是从网上下载的(如知网),但它也是发表在期刊上的,你看到的电子期刊仅是其电子版 [D]--学位论文:不区分硕士还是博士论文 [R]--报告:一般在标题中会有"关于****的报告"字样 [S]-- 标准 [P]--专利 [A]--文章:很少用,主要是不属于以上类型的文章 [Z]--对于不属于上述的文献类型,可用字母"Z"标识,但这种情况非常少见 常用的电子文献及载体类型标识: [DB/OL] --联机网上数据(database online) [DB/MT] --磁带数据库(database on magnetic tape) [M/CD] --光盘图书(monograph on CDROM) [CP/DK] --磁盘软件(computer program on disk) [J/OL] --网上期刊(serial online) [EB/OL] --网上电子公告(electronic bulletin board online) 很显然,标识的就是该资源的英文缩写,/前面表示类型,/后面表示资源的载体,如OL表示在线资源 二、参考文献的格式及举例 1.期刊类 【格式】[序号]作者.篇名[J].刊名,出版年份,卷号(期号)起止页码. 【举例】 [1] 周融,任志国,杨尚雷,厉星星.对新形势下毕业设计管理工作的思考与实践[J].电气电子教学学报,2003(6):107-109. [2] 夏鲁惠.高等学校毕业设计(论文)教学情况调研报告[J].高等理科教育,2004(1):46-52. [3] Heider, E.R.& D.C.Oliver. The structure of color space in naming and memory of two languages [J]. Foreign Language Teaching and Research, 1999, (3): 62 67. 2.专著类
建设部文献中英文对照
贯彻落实科学发展观大力发展节能与绿色建筑 (2005年2月23日) 中华人民共和国建设部 节能建筑是按节能设计标准进行设计和建造、使其在使用过程中降低能耗的建筑。 绿色建筑是指为人们提供健康、舒适、安全的居住、工作和活动的空间,同时在建筑全生命周期(物料生产,建筑规划、设计、施工、运营维护及拆除过程)中实现高效率地利用资源(能源、土地、水资源、材料)、最低限度地影响环境的建筑物。绿色建筑也有人称之为生态建筑、可持续建筑。 一、发展节能与绿色建筑的重要意义 建筑作为人工环境,是满足人类物质和精神生活需要的重要组成部分。然而,人类对感官享受的过度追求,以及不加节制的开发与建设,使现代建筑不仅疏离了人与自然的天然联系和交流,也给环境和资源带来了沉重的负担。据统计,人类从自然界所获得的50%以上的物质原料用来建造各类建筑及其附属设施,这些建筑在建造与使用过程中又消耗了全球能源的50%左右;在环境总体污染中,与建筑有关的空气污染、光污染、电磁污染等就占了34%;建筑垃圾则占人类活动产生垃圾总量的40%;在发展中国家,剧增的建筑量还造成侵占土地、破坏生态环境等现象日益严重。中国正处于工业化和城镇化快速发展阶段,要在未来15年保持GDP年均增长7%以上,将面临巨大的资源约束瓶颈和环境恶化压力。严峻的事实告诉我们,中国要走可持续发展道路,发展节能与绿色建筑刻不容缓。 绿色建筑通过科学的整体设计,集成绿色配置、自然通风、自然采光、低能耗围护结构、新能源利用、中水回用、绿色建材和智能控制等高新技术,具有选址规划合理、资源利用高效循环、节能措施综合有效、建筑环境健康舒适、废物排放减量无害、建筑功能灵活适宜等六大特点。它不仅可以满足人们的生理和心理需求,而且能源和资源的消耗最为经济合理,对环境的影响最小。 胡锦涛同志指出:要大力发展节能省地型住宅,全面推广节能技术,制定并强制执行节能、节材、节水标准,按照减量化、再利用、资源化的原则,搞好资源综合利用,实现经济社会的可持续发展。温家宝和曾培炎同志也多次指出,建筑节能不仅是经济问题,而且是重要的战略问题。 发展节能与绿色建筑是建设领域贯彻“三个代表”重要思想和十六大精神,认真落实以人为本,全面、协调、可持续的科学发展观,统筹经济社会发展、人与
碳纤维复合材料英文文献
Journal of Materials Processing Technology168(2005) 262–269 Process optimisation for a squeeze cast magnesium alloy metal matrix composite M.S.Yong a,?,A.J.Clegg b a Singapore Institute of Manufacturing Technology,71Nanyang Drive,Singapore638075,Singapore b Wolfson School of Mechanical and Manufacturing Engineering,Loughborough University,Loughborough,Leicestershire LE113TU,UK Received5January2004;received in revised form5January2004;accepted27January2005 Abstract The paper reports the in?uence of process variables on a zirconium-free(RZ5DF)magnesium alloy metal matrix composite(MMC) containing14vol.%Saf?l?bres.The squeeze casting process was used to produce the composites and the process variables evaluated were applied pressure,from0.1MPa to120MPa,and preform temperature from250?C to750?C.The principal?ndings from this research were that a minimum applied pressure of60MPa is necessary to eliminate porosity and that applied pressures greater than100MPa cause?bre clustering and breakage.The optimum applied pressure was established to be80MPa.It was also established that to ensure successful preform in?ltration a preform temperature of600?C or above was necessary.For the optimum combination of a preform preheat temperature of600?C and an applied pressure of80MPa,an UTS of259MPa was obtained for the composite.This represented an increase of30%compared to the UTS for the squeeze cast base alloy. ?2005Elsevier B.V.All rights reserved. Keywords:Magnesium alloys;Squeeze casting;Metal matrix composites;Mechanical properties 1.Introduction Metal matrix composite(MMC)components can be man-ufactured by several methods.The metal casting route is espe-cially attractive in terms of its ability to produce complex near net shapes.However,castings produced by conventional cast-ing processes may contain gas and/or shrinkage porosity.The tendency for porosity formation will be exacerbated when?-bres are introduced because they tend to restrict the?ow of molten metal and cause even greater gas entrapment within the casting.It is pointless to use?bres to reinforce a casting if defects are present,since the addition of?bres will not com-pensate for poor metallurgical integrity.In order to ful?l the potential of?bre reinforcement and produce pore free cast-ings the squeeze casting process can be selected.The unique feature of this process is that metal is pressurised throughout solidi?cation.This prevents the formation of gas and shrink-age porosity and produces a metallurgically sound casting.?Corresponding author. E-mail address:msyong@https://www.360docs.net/doc/f313612601.html,.sg(M.S.Yong).Selection of this process is also based on its suitability for mass production,ease of fabrication and its consistency in producing high quality composite parts. With the development of MMCs,magnesium alloys can better meet the various demands of diverse applications.The addition of reinforcement to magnesium alloy produces su-perior mechanical properties[1–3]and good thermal stability [4,5].Of the various composite types,the discontinuous and randomly oriented?bre-reinforced composites provide the best“value to strength ratio”. Despite the potential advantage of using magnesium MMC for lightweight and high strength applications,little is known about the in?uence of squeeze in?ltration parame-ters.Key parameters,such as applied pressure and preform temperature must be optimised,especially for the squeeze in?ltration of a magnesium–zinc MMC.These process pa-rameters were researched and the results are presented in this paper.However,it was?rst necessary to select appropriate ?bres and binders since their selection is fundamental to the success of the MMC.The main criterion determining the se-lection of?bre type is compatibility with the matrix.Two 0924-0136/$–see front matter?2005Elsevier B.V.All rights reserved. doi:10.1016/j.jmatprotec.2005.01.012
框架结构设计外文翻译
毕业设计(论文)外文资料翻译 系:机械工程系 专业:土木工程 姓名: 学号: 外文出处:Design of prestressed (用外文写) concrete structures 附件: 1.外文资料翻译译文;2.外文原文。
附件1:外文资料翻译译文 8-2简支梁布局 一个简单的预应力混凝土梁由两个危险截面控制:最大弯矩截面和端截面。这两部分设计好之后,中间截面一定要单独检查,必要时其他部位也要单独调查。最大弯矩截面在以下两种荷载阶段为控制情况,即传递时梁受最小弯矩M G的初始阶段和最大设计弯矩M T时的工作荷载阶段。而端截面则由抗剪强度、支承垫板、锚头间距和千斤顶净空所需要的面积来决定。所有的中间截面是由一个或多个上述要求,根它们与上述两种危险截面的距离来控制。对于后张构件的一种常见的布置方式是在最大弯矩截面采用诸如I形或T形的截面,而在接近梁端处逐渐过渡到简单的矩形截面。这就是人们通常所说的后张构件的端块。对于用长线法生产的先张构件,为了便于生产,全部只用一种等截面,其截面形状则可以为I形、双T形或空心的。在第5 、 6 和7章节中已经阐明了个别截面的设计,下面论述简支梁钢索的总布置。 梁的布置可以用变化混凝土和钢筋的办法来调整。混凝土的截面在高度、宽度、形状和梁底面或者顶面的曲率方面都可以有变化。而钢筋只在面积方面有所变化,不过在相对于混凝土重心轴线的位置方面却多半可以有变化。通过调整这些变化因素,布置方案可能有许多组合,以适应不同的荷载情况。这一点是与钢筋混凝土梁是完全不同的,在钢筋混凝土梁的通常布置中,不是一个统一的矩形截面便是一个统一的T形,而钢筋的位置总是布置得尽量靠底面纤维。 首先考虑先张梁,如图 8-7,这里最好采用直线钢索,因为它们在两个台座之间加力比较容易。我们先从图(a)的等截面直梁的直线钢索开始讨论。这样的布置都很简单,但这样一来,就不是很经济的设计了,因为跨中和梁端的要求会产生冲突。通常发生在跨度中央的最大弯矩截面中的钢索,最好尽量放低,以便尽可能提供最大力臂而提供最大的内部抵制力矩。当跨度中央的梁自重弯矩M G相当大时,就可以把c.g.s布置在截面核心范围以下很远的地方,而不致在传递时在顶部纤维中引起拉应力。然而对于梁端截面却有一套完全不同的要求。由于在梁端没有外力矩,因为在最后的时刻,安排钢索要以c.g.s与 c.g.c在结束区段一致,如此同样地获得克服压力分配的方法。无论如何,如果张应力在最后不能承受,放置 c.g.s.
中英文参考文献格式
中英文参考文献格式! (細節也很重要啊。。)来源:李菲玥的日志 规范的参考文献格式 一、参考文献的类型 参考文献(即引文出处)的类型以单字母方式标识,具体如下: M——专著C——论文集N——报纸文章J——期刊文章 D——学位论文R——报告S——标准P——专利 A——文章 对于不属于上述的文献类型,采用字母“Z”标识。 常用的电子文献及载体类型标识: [DB/OL]——联机网上数据(database online) [DB/MT]——磁带数据库(database on magnetic tape) [M/CD]——光盘图书(monograph on CD ROM) [CP/DK]——磁盘软件(computer program on disk) [J/OL]——网上期刊(serial online) [EB/OL]——网上电子公告(electronic bulletin board online) 对于英文参考文献,还应注意以下两点: ①作者姓名采用“姓在前名在后”原则,具体格式是:姓,名字的首字母. 如:Malcolm R ichard Cowley 应为:Cowley, M.R.,如果有两位作者,第一位作者方式不变,&之后第二位作者名字的首字母放在前面,姓放在后面,如:Frank Norris 与Irving Gordon应为:Norri s, F. & I.Gordon.; ②书名、报刊名使用斜体字,如:Mastering English Literature,English Weekly。二、参考文献的格式及举例 1.期刊类 【格式】[序号]作者.篇名[J].刊名,出版年份,卷号(期号):起止页码. 【举例】 [1] 周融,任志国,杨尚雷,厉星星.对新形势下毕业设计管理工作的思考与实践[J].电气电子教学学报,2003(6):107-109.
医学文献中英文对照
动脉粥样硬化所导致的心脑血管疾病是目前发病率和死亡率较高的疾病之一。在动脉粥样硬化的形成过程中, 内皮细胞病变是其中极其重要的因素,最显著的变化是动脉内皮功能紊乱, 血管内皮细胞的损伤和功能改变是动脉粥样硬化发生的起始阶段。 Cardiovascular and cerebrovascular disease caused by atherosclerosis is one of diseases with higher mortality and morbidity at present . In the formation of atherosclerosis, the endothelial cell lesion is one of the most important factors, in which, the most significant change is endothelial dysfunction. In addition, the injuries and the changes of vascular endothelial cells are the initial factors of atherosclerosis. 许多因素会导致血管内皮细胞受损, 主要包括脂多糖(Lipopolysaccharides , LPS)、炎症介质、氧自由基等。其中脂多糖因其广泛的生物学作用, 越来越引起研究者的关注。LPS 是一种炎症刺激物, 是革兰阴性杆菌细胞壁的主要组成成分,其通过刺激血管内皮细胞,引起其相关细胞因子和炎性因子的表达紊乱,尤其是Ca2+ 和活性氧簇(Reactive Oxygen Species , ROS的合成和释放发生改变诱导细胞氧化应激内环境紊乱。大量研究表明, LPS 直接参与动脉粥样硬化的形成过程, 特别是动脉粥样硬化血管炎症的初始阶段, LPS可通过直接作用或间接影响的方式激活并损伤内皮细胞,从而引 起血管内皮细胞形态与功能的改变。 Many factors induce vascular endothelial cell damage, including lipopolysaccharides (LPS), inflammatory mediators and oxygen free
外文翻译-模具工业
模具工业是国民经济的基础工业,是国际上公认的关键工业,工业发达国家称之为“工业之母”。模具成型具有效率高,质量好,节省原材料,降低产品成本等优点。采用模具制造产品零件已成为当今工业的重要工艺手段。模具在机械,电子,轻工,纺织,航空,航天等工业领域里,已成为使用最广泛的工业化生产的主要工艺装备,它承担了这些工业领域中60%--80%产品零件,组件和部件的加工生产。“模具就是产品质量”,“模具就是经济效益”的观念已被越来越多的人所认识和接受。在中国,人们已经认识到模具在制造业中的重要基础地位,认识更新换代的速度,新产品的开发能力,进而决定企业的应变能力和市场竞争能力。在目前用薄钢板制造发动机罩盖的传统还是会持续相当一段时间,所以有必要在钢板的基础上通过利用计算机软件的功能分析零件的工艺性能(结构合理,受力,是否容易冲出破面、、、),发现现有零件的不足之处,讨论并确定改进这些不足之处,进而改善模具的设计,改良冲裁方式;最终实现产品的改良,改善产品的力学性能,外观,使用效果,和造价等等。冲压加工是通过模具来实现的,从模具角度来看,模具生产技术水平的高低,已成为衡量一个国家产品制造水平高低的重要标志,因为模具在很大程度上决定着产品的质量、效益和新产品的开发能力。“模具是工业生产的基础工艺装备”也已经取得了共识。据统计,在电子、汽车、电机、电器、仪器、仪表、家电和通信等产品中,60%~80%的零部件都要依靠模具成形。用模具生产制件所具备的高精度、高复杂程度、高一致性、高生产率和低消耗,是其他加工制造方法所不能比拟的。同时,冲压加工也创造了巨大的价值增值,模具是“效益放大器”,用模具生产的最终产品的价值,往往是模具自身价值的几十倍、上百倍。目前全世界模具年产值约为600亿美元,日、美等工业发达国家的模具工业产值已超过机床工业,从1997年开始,我国模具工业产值也超过了机床工业产值。其中冲压模具在所有模具(锻造模、压铸模、注塑模等)中,无论从数量、重量或者是从价值上都位居榜首。 由此可见,板料冲压加工及其模具制造技术对国民经济的发展已经并将继续作出重大的贡献。随着我国经济的发展,对这种生产技术的发展及专业技术人才的需求将与日俱增。因此,加强对板料冲压加工及其模具制造技术的研究,具有重要的意义。 现状和发展趋势:经过了100多年的发展,目前小型汽车发动机的罩壳的设计技术已经相当成熟的了,但是随着各式各样的小型发动机的开发,发动机的前后罩也做了很大的改进。现在,对小型汽车发动机的罩壳的改进主要表现在对其构造材料的改进;例如用树脂基复合材料替代传统的薄钢板,用 RTM制造发动机水箱、隔热罩、发动机罩等等,由于用复合材料来取代原有金属的发动机壳体类零件,重量会有所减轻,且成本也将大大降低,对制造商而言,这个改进创造了很大了利润空间,所以这方面的技术进步还会持续相当长一段时间。就目前而言,我国冲压模具还存在许多问题,其中模具生产周期、质量和数量仍旧是关键。与国际水平相比,一般来说,我国冲压模具生产周期要比国外先进水平长、寿命约
英文引用及参考文献格式要求
英文引用及参考文献格式要求 一、参考文献的类型 参考文献(即引文出处)的类型以单字母方式标识,具体如下: M——专著C——论文集N——报纸文章 J——期刊文章D——学位论文R——报告 对于不属于上述的文献类型,采用字母“Z”标识。 对于英文参考文献,还应注意以下两点: ①作者姓名采用“姓在前名在后”原则,具体格式是:姓,名字的首字母.如:MalcolmRichardCowley应为:Cowley,M.R.,如果有两位作者,第一位作者方式不变,&之后第二位作者名字的首字母放在前面,姓放在后面,如:FrankNorris与IrvingGordon应为:Norris,F.&I.Gordon.; ②书名、报刊名使用斜体字,如:MasteringEnglishLiterature,EnglishWeekly。 二、参考文献的格式及举例 1.期刊类 【格式】[序号]作者.篇名[J].刊名,出版年份,卷号(期号):起止页码. 【举例】 [1]王海粟.浅议会计信息披露模式[J].财政研究,2004,21(1):56-58. [2]夏鲁惠.高等学校毕业论文教学情况调研报告[J].高等理科教育,2004(1):46-52. [3]Heider,E.R.&D.C.Oliver.Thestructureofcolorspaceinnamingandmemo ryoftwolanguages[J].ForeignLanguageTeachingandResearch,1999,(3):62–6 7. 2.专著类 【格式】[序号]作者.书名[M].出版地:出版社,出版年份:起止页码. 【举例】[4]葛家澍,林志军.现代西方财务会计理论[M].厦门:厦门大学出版社,2001:42. [5]Gill,R.MasteringEnglishLiterature[M].London:Macmillan,1985:42-45. 3.报纸类 【格式】[序号]作者.篇名[N].报纸名,出版日期(版次). 【举例】 [6]李大伦.经济全球化的重要性[N].光明日报,1998-12-27(3). [7]French,W.BetweenSilences:AVoicefromChina[N].AtlanticWeekly,198 715(33). 4.论文集 【格式】[序号]作者.篇名[C].出版地:出版者,出版年份:起始页码. 【举例】 [8]伍蠡甫.西方文论选[C].上海:上海译文出版社,1979:12-17. [9]Spivak,G.“CantheSubalternSpeak?”[A].InC.Nelson&L.Grossberg(e ds.).VictoryinLimbo:Imigism[C].Urbana:UniversityofIllinoisPress,1988, pp.271-313.
平面设计中英文对照外文翻译文献
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设计,“其实质是使以信息,形成以思想,言论和感觉的经验”。 在唐朝( 618-906 )之间的第4和第7世纪的木块被切断打印纺织品和后重现佛典。阿藏印在868是已知最早的印刷书籍。 在19世纪后期欧洲,尤其是在英国,平面设计开始以独立的运动从美术中分离出来。蒙德里安称为父亲的图形设计。他是一个很好的艺术家,但是他在现代广告中利用现代电网系统在广告、印刷和网络布局网格。 于1849年,在大不列颠亨利科尔成为的主要力量之一在设计教育界,该国政府通告设计在杂志设计和制造的重要性。他组织了大型的展览作为庆祝现代工业技术和维多利亚式的设计。 从1892年至1896年威廉?莫里斯凯尔姆斯科特出版社出版的书籍的一些最重要的平面设计产品和工艺美术运动,并提出了一个非常赚钱的商机就是出版伟大文本论的图书并以高价出售给富人。莫里斯证明了市场的存在使平面设计在他们自己拥有的权利,并帮助开拓者从生产和美术分离设计。这历史相对论是,然而,重要的,因为它为第一次重大的反应对于十九世纪的陈旧的平面设计。莫里斯的工作,以及与其他私营新闻运动,直接影响新艺术风格和间接负责20世纪初非专业性平面设计的事态发展。 谁创造了最初的“平面设计”似乎存在争议。这被归因于英国的设计师和大学教授Richard Guyatt,但另一消息来源于20世纪初美国图书设计师William Addison Dwiggins。 伦敦地铁的标志设计是爱德华约翰斯顿于1916年设计的一个经典的现代而且使用了系统字体设计。 在20世纪20年代,苏联的建构主义应用于“智能生产”在不同领域的生产。个性化的运动艺术在俄罗斯大革命是没有价值的,从而走向以创造物体的功利为目的。他们设计的建筑、剧院集、海报、面料、服装、家具、徽标、菜单等。 Jan Tschichold 在他的1928年书中编纂了新的现代印刷原则,他后来否认他在这本书的法西斯主义哲学主张,但它仍然是非常有影响力。 Tschichold ,包豪斯印刷专家如赫伯特拜耳和拉斯洛莫霍伊一纳吉,和El Lissitzky 是平面设计之父都被我们今天所知。 他们首创的生产技术和文体设备,主要用于整个二十世纪。随后的几年看到平面设计在现代风格获得广泛的接受和应用。第二次世界大战结束后,美国经济的建立更需要平面设计,主要是广告和包装等。移居国外的德国包豪斯设计学院于1937年到芝加哥带来了“大规模生产”极简到美国;引发野火的“现代”建筑和设计。值得注意的名称世纪中叶现代设计包括阿德里安Frutiger ,设计师和Frutiger字体大学;保兰德,从20世纪30年代后期,直到他去世于1996年,采取的原则和适用包豪斯他们受欢迎的广告和标志设计,帮助创造一个独特的办法,美国的欧洲简约而成为一个主要的先驱。平面设计称为企业形象;约瑟夫米勒,罗克曼,设计的海报严重尚未获取1950年代和1960年代时代典型。 从道路标志到技术图表,从备忘录到参考手册,增强了平面设计的知识转让。可读性增强了文字的视觉效果。 设计还可以通过理念或有效的视觉传播帮助销售产品。将它应用到产品和公司识别系统的要素像标志、颜色和文字。连同这些被定义为品牌。品牌已日益成为重要的提供的服务范围,许多平面设计师,企业形象和条件往往是同时交替使用。