Q24 密封材料 标准查询与下载

BS EN 15466-3:2009 冷施和热施填缝料的引物.第3部分:固体含量和挥发物挥发特性的测定

This European Standard describes a method for determining the solids content and the evaporation behaviour of volatiles of primers for cold and hot applied joint sealants.

Primers for cold and hot applied joint sealants - Part 3:Determination of solids content and evaporation behaviour of volatiles

BS EN 15466-1:2009 冷施和热施填缝料的引物.第1部分:同质性的测定

This European Standard describes a method for determining the homogeneity of primers for cold and hot applied joint sealants.

Primers for cold and hot applied joint sealants - Part 1:Determination of homogeneity

BS EN 15466-2:2009 冷施和热施填缝料的引物.第2部分:耐碱性的测定

This European Standard describes a method for determining the resistance against alkali of primers for cold and hot applied joint sealants.

Primers for cold and hot applied joint sealants - Part 2:Determination of resistance against alkali

DIN 18542:2009 泡沫塑料制浸渍密封带用于密封外壁接缝.浸渍密封带.试验和要求

Sealing of outside wall joints with impregnated sealing tapes made of cellular plastics - Impregnated sealing tapes - Requirements and testing

SANS 1077:2009 建筑行业用两组分聚氨酯基密封剂

Covers requirements for two types (see 3.1) of two-component, cold-applied, polyurethane-base sealing compound, that are suitable for sealing, caulking and glazing applications in buildings and similar structures.

Sealing compounds for the building and construction industry, two-component, polyurethane-base

ISO 9047:2001/cor 1:2009 建筑结构.接合产品.可变温度条件下密封剂粘结/附着性能的测定.技术勘误1

Building construction - Jointing products - Determination of adhesion/cohesion properties of sealants at variable temperatures; Technical Corrigendum 1

ASTM C898/C898M-09(2017) 用于单独磨耗层上的含高浓度固体粒子的冷的液态使用的弹性防水薄膜的标准使用指南

4.1 Designers and installers of waterproofing systems may consult this guide for a discussion of important elements of the use of cold liquid-applied waterproofing membranes and associated elements of construction. This guide is not intended to serve as a specification for waterproofing installation. 4.2 Long-term performance of waterproofing with a separate wearing course is important because of the substantial difficulty in determining the location of leakage and in removing overlying materials to make repairs. 4.3 Refer to Guide C1471/C1471M for application on below grade walls and vertical surfaces. 1.1 This guide describes the use of a high solids content, cold liquid-applied elastomeric waterproofing membrane that meets the criteria in Specification C836/C836M, in a waterproofing system subject to hydrostatic pressure for building decks over occupied space where the membrane is covered with a separate protective wearing course. 1.2 The values stated in either SI units or inch-pound units are to be regarded separately as standard. The values stated in each system may not be exact equivalents; therefore, each system shall be used independently of the other. Combining values from the two systems may result in non-conformance with the standard. 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, health, and environmental practices and determine the applicability of regulatory limitations prior to use. 1.4 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

Standard Guide for Use of High Solids Content, Cold Liquid-Applied Elastomeric Waterproofing Membrane with Separate Wearing Course

ANSI/ASTM D4068:2009 隐含水密封薄板用氯化聚乙烯薄板规范

Specification for Chlorinated Polyethylene (CPE) Sheeting for Concealed Water-Containment Membrane

ASTM C1681-09 评定恒应变下密封剂抗扯性的标准试验方法

This test method is intended to determine if a joint that is subjected to a mechanically induced cut will resist tear propagation during normal joint movement. A sealant with a high resistance to tear propagation will typically perform better than a sealant with a low resistance to tear propagation.1.1 This test method evaluates the impact of an induced tear on a sealant specimen that is dimensioned, cured according to the guidelines in Test Method C 719 and then subjected to a constant strain. It is effective in differentiating between sealants that are used in dynamic joints subject to abrasion, punctures, tears, or combination thereof. 1.2 Since this test method is for the evaluation of tear propagation, an adhesive failure to the substrates provides no usable data regarding tear propagation. This would be considered a failed test and that data would be discarded, or at least separated from the other data from specimens that did not experience an adhesive failure. 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. 1.4 The committee with jurisdiction over this standard is not aware of any comparable standards published by other organizations.

Standard Test Method for Evaluating the Tear Resistance of a Sealant Under Constant Strain

ASTM C1193-09 接缝密封剂使用的标准指南

This guide provides information and guidelines for consideration by the designer or applicator of a joint seal. It explains the properties and functions of various materials, such as sealant, sealant backing, and primer, among others; and, procedures such as, substrate cleaning and priming, and installation of the components of a sealed joint. It presents guidelines for the use and application of the various materials, design of a sealant joint for a specific application, and environmental conditions and effects that are known to detrimentally affect a sealant joint. The information and guidelines are also useful for those that supply accessories to the sealant industry and for those that install sealants and accessory materials associated with sealant use. In addition to the design and installation data in this guide, consult the sealant manufacturer about applications for its products and their proper use and installation. Considering the range of properties of commercially available sealants, the variety of joint designs possible, and the many conditions of use, the information contained herein is general in nature. To assist the user of the guide in locating specific information, a detailed listing of guide numbered sections and their descriptors are included in Appendix X2.1.1 This guide describes the use of a cold liquid-applied sealant for joint sealing applications. Including joints on buildings and related adjacent areas, such as plazas, decks, and pavements for vehicular or pedestrian use, and types of construction other than highways and airfield pavements and bridges. Information in this guide is primarily applicable to a single and multi-component, cold liquid-applied joint sealant and secondarily to a precured sealant when used with a properly prepared joint opening and substrate surfaces. 1.2 An elastomeric or non-elastomeric sealant described by this guide should meet the requirements of Specification C 834, C 920, or C 1311. 1.3 This guide does not provide information or guidelines for the use of a sealant in a structural sealant glazing application. Guide C 1401 should be consulted for this information. Additionally, it also does not provide information or guidelines for the use of a sealant in an insulating glass unit edge seal used in a structural sealant glazing application. Guide C 1249 should be consulted for this information. 1.4 Practice C 919 should be consulted for information and guidelines for the use of a sealant in an application where an acoustic joint seal is required. 1.5 This guide also does not provide information relative to the numerous types of sealant that are available nor specific generic sealant properties, such as hardness, tack-free time, or curing process, among others. Guide C 1299 should be consulted for information on generally accepted comparative values for the characteristics and properties of the more common generic types of liquid-applied sealant. 1.6 The values stated in SI units are to be regarded as the standard. The values given in parenthesis are provided for information only. 1.7 The Committee with jurisdiction for this standard is not aware of any comparable standards published by other organizations. 1.8 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. 1.9 The committee with jurisdiction over this standard is not aware of any comparable standards published by other or......

Standard Guide for Use of Joint Sealants

ASTM C1501-09 用实验室加速风化程序测定建筑物密封材料颜色稳定性的标准试验方法

This test method is intended to induce color changes in sealants, as well as their constituent pigments, associated with end-use conditions, including the effects of sunlight, moisture, and heat. The exposures used in this test method are not intended to simulate the color change of a sealant caused by localized weathering phenomena, such as atmospheric pollution, biological attack, and saltwater exposure. When conducting exposures in devices that use laboratory light sources, it is important to consider how well the artificial test conditions will reproduce property changes and failure modes associated with end-use environments for the sealant being tested. Information on the use and interpretation of data from accelerated exposure tests is provided in ASTM G 151. When this test method is used as part of a specification, exact procedure, test conditions, test duration and evaluation technique must be specified. Results obtained between the two procedures may vary, because the spectral power distribution of the light sources (fluorescent UV and xenon arc) differ. Sealants should not be compared to each other based on the results obtained in different types of apparatus. These devices are capable of matching ultraviolet solar radiation reasonably well. However, for sealants sensitive to long wavelength UV and visible solar radiation, the absence of this radiation in the fluorescent UV apparatus can distort color stability ranking when compared to exterior environment exposure. Note 18212;Refer to Practices G 151 for full cautionary guidance regarding laboratory weathering of non-metallic materials.1.1 This test method describes laboratory accelerated weathering procedures using either fluorescent ultraviolet or xenon arc test devices for determining the color stability of building construction sealants. 1.2 Color stability rankings provided by these two procedures may not agree. 1.3 The values stated in SI units are to be regarded as the standard. Values given in parentheses are for information only. 1.4 There is no equivalent ISO standard for this test method. 1.5 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.

Standard Test Method for Color Stability of Building Construction Sealants as Determined by Laboratory Accelerated Weathering Procedures

ASTM C1401-09a 结构密封膏镶嵌玻璃标准指南

The old saying “A chain is only as strong as its weakest link” is very applicable to a SSG system. In reality, a SSG system, to be successful, must establish and maintain a chain of adhesion. For example, a factory applied finish must adhere adequately to a metal framing member, a structural glazing sealant to that metal finish, that structural glazing sealant to a reflective coating on a glass lite, and lastly, that reflective coating to a glass surface. This guide will assist in the identification and development of, among others, performance criteria, test methods, and industry practices that should be implemented to obtain the required structural glazing sealant adhesion and compatibility with other system components. Although this guide has been arranged to permit easy access to specific areas of interest, it is highly recommended that the entire guide is read and understood before establishing the requirements for a particular SSG system. This guide should not be the only criteria upon which the design and installation of a SSG system is based. The information herein is provided to assist in the development of a specific program with a goal of achieving a successful SSG system installation. Information and guidelines are provided for the evaluation, design, installation, and maintenance of a SSG system and many of its various components. Considering the range of properties of structural glazing silicone sealants, as well as the many types of framing system designs, material combinations that can be used, various material finishes, and the many types and varieties of accessories, the information contained herein is general in nature. Generally, the design, fabrication, and installation of a SSG system requires more technical knowledge and experience then is required for a conventionally glazed window or curtain wall system. To ensure the success of a SSG system, it is important that suppliers, fabricators, and installers of materials and components have a sound knowledge of SSG system requirements and become involved in the design and planning for each application. Suppliers of, among others, sealants, framing finishes, glazing materials and components, and various accessories should review and agree with the developed SSG system plans, requirements, and quality control program. 5.5 The results of not planning for and implementing quality control programs during at least the design, testing, fabrication, and installation phases of a SSG system''s development can result in less than desirable results, which can include nuisance air or water leakage or catastrophic failure where life safety of the public can be at risk (1, 2). 1.1 Structural sealant glazing, hereinafter referred to as SSG, is an application where a sealant not only can function as a barrier against the passage of air and water through a building envelope, but also primarily provides structural support and attachment of glazing or other components to a window, curtain wall, or other framing system. 1.2 This guide provides information useful to design professionals, manufacturers, contractors, and others for the design and installation of a SSG system. This information is applicable only to this glazing method when used for a building wall that is not more than 15° from vertical; however, limited information is included concerning a sloped SSG application. 1.3 Only a silicone chemically curing sealant specifically formulated, tested, and marketed for structural sealant glazing is acceptable for a SSG system application. 1.4 The committee with jurisdiction for this standard is not aware of any comparable standard published by other organizations. 1.5 The calculations and......

Standard Guide for Structural Sealant Glazing

ASTM C1247-09 连续浸液的密封剂寿命的标准试验方法

This test method uses elevated temperature to accelerate the degradation of a sealant and its adhesion to a substrate. This test method is an accelerated method and will only be a predictor of long-term durability if the actual service temperature is significantly lower than the elevated test temperature. This test method can be used as an indicator of longevity but direct correlation to actual use will be difficult for many applications. The correlation of data from this test method to applications where the sealant joint will have wet and dry cycles will be difficult since, with some sealants on some substrates, adhesion that is lost during wet periods is regained during dry periods. This test method is performed in a hot liquid and may be considered an acceleration of deterioration of the sealant or the sealant''s adhesion to a substrate. Compared to how the sealant will be used in some applications, in some cases, this test may be less severe than the actual application. The benefit from the use of this test method will depend on the comparison of the conditions of this test to the actual conditions of use (temperature, duration, nature of substrate, composition of the liquid). To determine the ability of a sealant to perform in a given application; modification of this procedure will often be required and is permissible, as mutually agreed upon by purchaser and seller.1.1 This test method covers a laboratory procedure that assists in determining the durability of a sealant and its adhesion to a substrate while continuously immersed in a liquid. This test method tests the influence of a liquid on the sealant and its adhesion to a substrate. It does not test the added influence of constant stress from hydrostatic pressure that is often present with sealants used in submerged and below-grade applications, nor does it test the added influence of stress from joint movement while immersed. This test method also does not (in its standard form) test the added influence of acids or caustics or other materials that may be in the liquid, in many applications. 1.2 The values stated in SI units are to be regarded as the standard. The inch-pound given in parentheses are provided 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.

Standard Test Method for Durability of Sealants Exposed to Continuous Immersion in Liquids

DIN 18545-2:2008 使用密封剂密封玻璃制品.第2部分:密封剂名称测试要求

Sealing of glazings with sealants - Part 2: Sealants, designation, requirements, testing

DIN 52452-4:2008 建筑结构密封材料的测试.密封制品的兼容性.第4部分:与其他防护涂层的兼容性

Testing of sealing compounds in building constructions - Compatibility of sealing products - Part 4: Compatibility with other protection coatings

AAMA 800-2008 密封胶的推荐规范和检测方法

1.1.2.1 802.3 Compound The pumpable and gunnable compound is used to bed glass to the surrounding substrate and is intended to remain ductile and prevent air infiltration and water leakage. Type I is recommended for intermittent water contact. Type II is recommended for extended water contact, but not continuous immersion. 1.1.2.2 805.2 Compound The pumpable and gunnable compound is used to bed glass to the surrounding substrate and is intended to bond or adhere the glass to the substrate and prevent air infiltration and water leakage. Group C demonstrates predominately cohesive failure, while Group A is limited to chemically curing sealants which demonstrate adhesive failure, when tested for peel adhesion according to Section 2.4.1 or lap shear according to Section 2.20. NOTE 1." Sealant manufacturers may choose to test sealants to either of the following sections or to both to qualify to AAMA 805.2 Groups A and C." Sections 1.1.4.3.3 (Group A) and 1.1.4.3.4 (Group C);or Section 1.1.4.4. The use of lap shear testing following exposures is offered to meet the needs of window manufacturers for sealant strength data which may be used for window design and estimating strength after accelerated aging. This data may provide insight on sealant durability and performance.

Voluntary Specification and Test Methods For Sealants

BS ISO 16938-2:2008 建筑结构.通过接缝密封胶测定多孔基板的锈蚀性.非压缩试验

Building construction - Determination of the staining of porous substrates by sealants used in joints - Test without compression

JIS A 6914 AMD 1:2008 石膏抹灰板用填缝材料(修改件1)

This standard is an Amendment of Jointing materials for gypsum plasterboards.

Jointing materials for gypsum plasterboards (Amendment 1)

JIS A 5750 AMD 1:2008 建筑物中窗、门和面板接缝用弹性泡沫预制密封垫(修改件1)

Elastomeric cellular preformed gaskets for windows, doors and joints of panel in buildings (Amendment 1)

ISO 16938-1:2008 建筑构件.接合处多孔基底用密封剂的着色测定.第1部分:压缩试验

This part of ISO 16938 specifies a method for determining the staining of porous substrates (e.g. marble, limestone, sandstone or granite) by sealants used in building construction. The method evaluates the likelihood of a sealant causing an early stain on a porous substrate due to exudation of materials from the sealant. The outcome of the test is specific to the tested sealant and tested substrate and cannot be extrapolated to other sealant formulations or other porous substrates. During this accelerated test, if the sealant does not stain or discolour the substrates, it does not mean that the tested sealant will not stain or discolour the tested porous substrate over a longer time period. Experience in various countries with similar test methods has shown that the compression of test specimens further accelerates the occurrence of staining.

Building construction - Determination of the staining of porous substrates by sealants used in joints - Part 1: Test with compression