Q34 工业技术玻璃 标准查询与下载

DIN 8902:1996 无低温范围限制的耐压氧化钠石灰玻璃制圆形视孔玻璃板

This document applies to circular sight glasses of tempered soda-lime-glass.

Pressure resistant circular sight glasses of soda-lime-glass without limitation in the range of low temperature

VC 8051-1995 公路车辆用替换安全玻璃

Covers safety glass that are offered for sale as replacement parts for use in road vehicles. Does not cover safety glass for use in off-road vehicles such as agricultural machines or earth-moving machines.

Replacement safety glass for use in road vehicles

JIS R 3254:1995 氟化玻璃化学稳定性的测试方法

この規格は，ふっ化物ガラスの水に対する化学的耐久性の試験方法について規定する。

Testing method for chemical durabilities of fluoride glasses

QB/T 2112-1997 液位计用玻璃板

Glass plate for liquid level gauge

JIS R 3105:1995 硼硅酸盐玻璃的化学分析方法

この規格は，ほうけい酸ガラスの分析方法について規定する。

Methods for chemical analysis of borosilicate glasses

JIS R 3101:1995 钠钙硅镁玻璃的化学分析方法

この規格は，ソーダ石灰ガラスの分析方法について規定する。

Methods for chemical analysis of Soda-Lime-Magnesia-Silica glasses

JIS R 3209:1995 密封绝缘玻璃

Sealed insulating glass

JIS R 3301:1995 交通色漆用玻璃珠

この規格は，路面標示塗料に使用する無色透明な反射用ガラスピーズ(以下，ガラスビーズという。)について規定する。

Glass beads for traffic paint

JIS R 3252:1994 激光干涉仪检测玻璃匀质性的测量方法

この規格は，レーザ干渉法によるガラスの属折率の均質度の測定方法について規定する。

Measuring method for the homogeneity of glasses by laser interferometry

DIN 52341:1993 玻璃的试验.铅晶体玻璃和晶体玻璃的化学分析

Testing of glass; chemical analysis of lead crystal glass and crystal glass

BS 3193:1993 家用电器用热韧化玻璃板规范

This edition recognizes that the fragmentation test in Appendix B can only be carried out on panels at least 76 mm x 76 mm in area. Also incorporates a more realistic impact test in which the impactor is a loaded vessel as opposed to a steel ball.

Specification for thermally toughened glass panels for use in domestic appliances

ASTM C912-93(2003) 设计玻璃清洗方法的标准实施规程

Many of the low-silica technical glasses which contain soluble or reactive oxides require processing or involve applications that require cleaning. Very often these cleaning procedures have evolved over several decades and are considered an art. They usually contain numerous steps, some of questionable validity. It is the premise of this practice that cleaning glass can be more scientific. Design of a cleaning procedure should involve (1) a definition of the soil to be removed, (2) an awareness of the constraints imposed by the glass composition, and (3) a rational selection of alternative methods that will remove the soil and leave the glass in a condition suitable for its intended application. This practice provides information to assist in step (3). General references on glass cleaning and on various methods of evaluating cleanliness and associated information has been published.2 1.1 This practice is intended to provide information that will permit design of a rational cleaning procedure that can be used with a glass that is somewhat soluble in many aqueous chemical solutions. Typically, this type of glass is used in applications such as optical ware, glass-to-metal seals, low dielectric loss products, glass fibers, infrared transmitting products, and products resistant to metallic vapors. 1.2 In most cases, this type of glass contains high concentrations of oxides that tend to react with a number of aqueous chemicals. Such oxides include B2 O3 , Al2 O3 , R2 , RO, La2 O3 , ZnO, PbO, P2 O5 , and Fe2 O3 . The more conventional high-silica glasses are usually more chemically resistant, but the cleaning principles outlined here also apply to them. 1.3 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory limitations prior to use. Specific hazard statements are given in Section 4 and Table 1.

Standard Practice for Designing a Process for Cleaning Technical Glasses

ASTM C912-93(2008)e1 工业用玻璃清洗过程设计的标准实施规程

Many of the low-silica technical glasses which contain soluble or reactive oxides require processing or involve applications that require cleaning. Very often these cleaning procedures have evolved over several decades and are considered an art. They usually contain numerous steps, some of questionable validity. It is the premise of this practice that cleaning glass can be more scientific. Design of a cleaning procedure should involve (1) a definition of the soil to be removed, (2) an awareness of the constraints imposed by the glass composition, and (3) a rational selection of alternative methods that will remove the soil and leave the glass in a condition suitable for its intended application. This practice provides information to assist in step (3). General references on glass cleaning and on various methods of evaluating cleanliness and associated information has been published. 1.1 This practice covers information that will permit design of a rational cleaning procedure that can be used with a glass that is somewhat soluble in many aqueous chemical solutions. Typically, this type of glass is used in applications such as optical ware, glass-to-metal seals, low dielectric loss products, glass fibers, infrared transmitting products, and products resistant to metallic vapors. 1.2 In most cases, this type of glass contains high concentrations of oxides that tend to react with a number of aqueous chemicals. Such oxides include B2O3, Al2O3, R2O, RO, La2O3, ZnO, PbO, P2O5, and Fe2O3. The more conventional high-silica glasses are usually more chemically resistant, but the cleaning principles outlined here also apply to them. 1.3 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory limitations prior to use. Specific hazard statements are given in Section 4 and Table 1. TABLE 1 Relative Solubility of Various Glass Component Oxides in HF, Other Inorganic Acids, and NaOH, in Concentrated Solutions at Room Temperature Note 18212;Macro or minor/trace levels will determine degree of precipitation, especially in acids, for example, HNO3 (Sn, Sb, Mo). Note 28212;W is soluble in acid but heat may precipitate it, for example, H2WO4. Note 38212;Sn+4 is soluble in hot H2SO4; Sn+2 is soluble in other reagents as well. Note 48212;Most alkali solutions must be hot to effect solution. Note 58212;PbSO4 is soluble in hot concentrated H2SO4. Note 68212;Sb and Bi form insoluble oxychlorides in dilute HCl. Note 78212;Ba is insoluble in concentrated HNO3. Oxides ofHF 49 %H2SO4 96 %

Standard Practice for Designing a Process for Cleaning Technical Glasses

ASTM C912-93(2008) 工程玻璃清洗过程的设计的标准实施规程

Many of the low-silica technical glasses which contain soluble or reactive oxides require processing or involve applications that require cleaning. Very often these cleaning procedures have evolved over several decades and are considered an art. They usually contain numerous steps, some of questionable validity. It is the premise of this practice that cleaning glass can be more scientific. Design of a cleaning procedure should involve (1) a definition of the soil to be removed, (2) an awareness of the constraints imposed by the glass composition, and (3) a rational selection of alternative methods that will remove the soil and leave the glass in a condition suitable for its intended application. This practice provides information to assist in step (3). General references on glass cleaning and on various methods of evaluating cleanliness and associated information has been published. 1.1 This practice covers information that will permit design of a rational cleaning procedure that can be used with a glass that is somewhat soluble in many aqueous chemical solutions. Typically, this type of glass is used in applications such as optical ware, glass-to-metal seals, low dielectric loss products, glass fibers, infrared transmitting products, and products resistant to metallic vapors. 1.2 In most cases, this type of glass contains high concentrations of oxides that tend to react with a number of aqueous chemicals. Such oxides include B2O3, Al2O3, R2O, RO, La2O3, ZnO, PbO, P2O5, and Fe2O3. The more conventional high-silica glasses are usually more chemically resistant, but the cleaning principles outlined here also apply to them. 1.3 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory limitations prior to use. Specific hazard statements are given in Section 4 and Table 1.

Standard Practice for Designing a Process for Cleaning Technical Glasses

ISO 3917:1992 道路车辆.安全窗玻璃.耐辐射、耐高温、耐湿度和耐燃烧和气候模拟试验方法

Road vehicles; safety glazing materials; test methods for resistance to radiation, high temperature, humidity, fire and simulated weathering

CGSB 12.4-M91-CAN/CGSB-1991 隔热玻璃

Heat Absorbing Glass

Heat Absorbing Glass

ASTM C824-91(2010) 用膨胀计法测定透明玻璃釉瓷及玻璃色料的线性热膨胀的标准试验方法

The dilatometer method of measuring linear thermal expansion of vitreous glass enamels and glass enamel frits has the advantage of simplicity, lends itself to automatic, self-recording arrangements, and requires test specimens of simple configuration.1.1 This practice covers the preparation of vitreous glass enamels and glass enamel frit specimens for the measurement of linear thermal expansion using Test Method E228. 1.2 The values stated in SI units are to be regarded as the standard. The values given in parentheses are for information only. 1.3 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory limitations prior to use. For specific hazard statements, see Section 6.

Standard Practice for Specimen Preparation for Determination of Linear Thermal Expansion of Vitreous Glass Enamels and Glass Enamel Frits by the Dilatometer Method

SAE AMS3751B-1990 空心玻璃微球形体

This specification covers hollow glass microspheres. Primarily as a filler material in syntactic foam shapes or parts for dielectric applications.

Microspheres, Hollow Glass

CGSB 12.1-M90-CAN/CGSB-1990 钢化或夹层安全玻璃

Tempered or Laminated Safety Glass

Verre De Securite Trempe Ou Feuillete

JIS R 3205:1989 夹层玻璃

Laminated glasses