Q24 密封材料 标准查询与下载

DIN 18531-2:2010 屋顶的防水.无用屋顶的密封件.第2部分:材料

Waterproofing of roofs - Sealings for non-utilized roofs - Part 2: Materials

DIN 18531-4:2010 屋顶的防水.无用屋顶的密封件.第4部分:维护

Waterproofing of roofs - Sealings for non-utilized roofs - Part 4: Maintenance

DIN 18531-3:2010 屋顶的防水.无用屋顶的密封件.第3部分:设计、材料搬运和密封

Waterproofing of roofs - Sealings for non-utilized roofs - Part 3: Design, handling of materials, execution of sealings

BS EN 1847:2009 防水柔性板.屋顶防水用防水塑料和橡胶薄板.暴露于包括水的液体化学药品的方法

This European Standard specifies a method of exposing test specimens of plastic and rubber sheets for roofing, free from all external restraint, to liquid chemicals (including water), and methods for determining the changes in properties resulting from such exposure.

Flexible sheets for waterproofing - Plastics and rubber sheets for roof waterproofing - Methods for exposure to liquid chemicals, including water

JIS A 5758:2010 建筑物中密封和门窗玻璃用密封剂

Sealants for sealing and glazing in buildings

JIS A 1439:2010 建筑物中密封和门窗玻璃用密封剂的试验方法

Testing methods of sealants for sealing and glazing in buildings

JG/T 264-2010 混凝土裂缝修复灌浆树脂

本标准规定了混凝土裂缝修复灌浆树脂(简称灌浆树脂)的术语和定义、型号和标记、要求、试验方法、检验规则、标志、包装、运输与贮存。 本标准适用于对混凝土裂缝进行修复的灌浆树脂。

Grouting resin for concrete crack

ASTM C1519-10 实验室加速风化法评估建筑密封胶的标准试验方法

This test method describes the procedure to evaluate or compare, or both, the durability of sealants when subjected to accelerated weathering and cyclic movement in a joint. Sealant installation procedures, design considerations and movement during cure affect the aging processes and are fundamental to the success of any sealant. These factors are not addressed with this test method. The amount, type and frequency of movement a sealant experiences during its lifetime strongly depends on the materials used in construction and on the orientation of the joint toward sunlight and many other factors that are not uniform or consistent. Climatic exposures will differ with the orientation of the building and shading as well as with local and regional climatic conditions. Climates in a given location can vary from year to year because of differences in solar radiation, temperature, rainfall, and atmospheric conditions. Further, the quality and intensity of solar radiation on the earth's surface varies with geographic location, season, time of day, and cloud cover. Variations in results may be expected when operating conditions are varied within the accepted limits of this test method. Therefore, all test results using this test method must be accompanied by a report of the specific operating conditions as required in Section 12. Refer to Practice G151 for detailed information on the caveats applicable to use of results obtained according to this test method. The results of laboratory exposure cannot be directly extrapolated to estimate an absolute rate of deterioration caused by natural weathering because the acceleration factor is material dependent and can be significantly different for each material and for different formulations of the same material. However, exposure of a similar material of known outdoor performance, a control, along with the test specimens allows comparison of the durability relative to that of the control under the test conditions. Evaluation in terms of relative durability also greatly improves the agreement in test results among different laboratories. Results of this procedure will depend on the care that is taken to operate the equipment according to Practices G154 and G155. Significant factors include regulation of the line voltage, freedom from salt or other deposits from water, temperature control, humidity control, where applicable, condition and age of the burners and filters in xenon arc equipment, and age of lamps in fluorescent UV equipment. Note 18212;Additional information on sources of variability and on strategies for addressing variability in the design, execution and data analysis of laboratory accelerated exposure tests is found in Guide G141.1.1 This test method covers the method for the determination of the durability of a sealant based on its ability to function in cyclic movement maintaining adhesion and cohesion after repeated exposure to laboratory accelerated weathering procedures. 1.2 This test method describes two laboratory accelerated weathering procedures for evaluating the durability of a sealant. 1.3 RILEM TC139–DBS is related to this test method. 1.4 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 ......

Standard Test Method for Evaluating Durability of Building Construction Sealants by Laboratory Accelerated Weathering Procedures

ASTM C1737-10 评定在配施前和配施后温度对气溶胶泡沫密封剂的影响的标准指南

This guide is not intended to measure the precise temperature range for dispensing and curing product under all the possible substrate and environmental factors but to provide a basis for benchmarking a foam sealant product under specific laboratory conditions. The product user is encouraged to evaluate each application and determine suitability for actual use.1.1 This guide covers the general effects of temperature during the use temperatures for aerosol foam sealant (either polyurethane or latex types). 1.2 The guide is intended to estimate the observed product dispensing character and foam quality of aerosol foam dispensed or cured, or both, at specific temperatures. 1.3 Such foam sealants are used for a variety of end use applications primarily intended to reduce air movement in building enclosures. 1.4 Currently two main foam sealant types are applicable to this standard, single component polyurethane and latex types. 1.5 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard. 1.6 There are no other known test methods specific for measuring the product temperature range for aerosol foam sealant. 1.7 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 Guide for Evaluating Temperature Effects to Aerosol Foam Sealant During and After Dispensing

ASTM C920-10 弹性接缝剂标准规范

This specification covers several classifications of sealants as described in Section 4 for various applications. It should be recognized by the purchaser or design professional that not all sealants meeting this specification are suitable for all applications and all substrates. It is essential, therefore, that the applicable type, grade, class, and use be specified so that the proper classification of sealant is provided for the intended use. Test methods relate to special standard specimen substrates of mortar, glass, and aluminum. If tests are required using substrates in addition to or other than the standard, they should be so specified for testing.1.1 This specification covers the properties of a cured single- or multicomponent cold-applied elastomeric joint sealant for sealing, caulking, or glazing operations on buildings, plazas, and decks for vehicular or pedestrian use, and types of construction other than highway and airfield pavements and bridges. 1.2 A sealant meeting the requirements of this specification shall be designated by the manufacturer to be one or more of the types, classes, grades, and uses defined in Section 7. 1.3 The values stated in SI units are to be regarded as the standard. The values given in parentheses are for information only. 1.4 This standard is similar, but not identical, to ISO 11600.

Standard Specification for Elastomeric Joint Sealants

ASTM E2342-10 管道密封胶耐久性试验的标准试验方法

Residential duct systems are often field designed and assembled. There are many joints, often of dissimilar materials that require both mechanical connection and air sealing. Without this sealing, duct systems would be extremely leaky and hence inefficient. While some duct sealants are rated on their properties at the time of manufacture or during storage, none of these ratings adequately addresses the in-service lifetime. This test method has been developed to address this durability issue. This standard applies to products which list duct sealing as one of their uses. This includes duct tape (cloth, metal foil, or plastic backed), mastics, and sprayed/aerosol sealants. It does not apply to caulks or plaster patches that are not intended to be permanent duct sealing methods. The standard duct leak site is a collar to plenum connection for round duct that is 10 to 20 cm (4 to 8 in.) in diameter. This perpendicular connection was chosen because almost all residential duct systems have this type of connection and in field observations of duct systems, it is often this type of connection that has sealant failure.1.1 This test method describes an accelerated aging test for evaluating the durability of duct sealants by exposure to temperatures and static pressures characteristic of residential duct systems. 1.2 This test method is intended to produce a relative measure of the durability of duct sealants. This standard does not measure durability under specific conditions of weather and building operation that might be experienced by an individual building and duct system. Instead it evaluates the sealant method under fixed conditions that do not include the manifold effects of installation practice. 1.3 This test method only addresses sealants not mechanical strength of the connections. 1.4 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 7.

Standard Test Method for Durability Testing of Duct Sealants

ASTM C1311-10 溶剂释放器密封件的标准规范

This specification describes solvent release sealants for general caulking and sealing operations in building construction. However, it should be recognized by the user that not all sealants meeting this specification are suitable for all applications and all substrates and that there is no implication that the sealants are equivalent in all physical properties. Refer to Guide C1193 for information on the proper use of sealants meeting this specification.1.1 This specification describes the properties of a one-component solvent release sealant for use in building construction. These sealants are generally formulated to withstand a maximum joint movement of 7.5 % in extension and 7.5 % in compression of the nominal joint width. 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 The committee with jurisdiction of this specification is not aware of any similar specification within ISO or any other organization.

Standard Specification for Solvent Release Sealants

ASTM C957/C957M-10 带整体磨损面的高固体含量、应用冷却液的弹性防水薄膜的标准规范

1.1 This specification describes the required properties and test methods for a cold liquid-applied elastomeric membrane for waterproofing building decks not subject to hydrostatic pressure. The specification applies only to a membrane system that has an integral wearing surface. This specification does not include specific requirements for skid resistance or fire retardance, although both may be important in specific uses. 1.2 The type of membrane system described in this specification is used for pedestrian and vehicular traffic and in high-abrasion applications. The membrane may be single- or multi-component, and may consist of one or more coats (for example base coat, top coat, etc.). The coat(s) may be built to the desired thickness in one or more applications. One coat (base coat) provides the primary waterproofing function and normally comprises the major amount of organic material in the membrane. The function of the top coat(s) is to resist wear and weather. Aggregate may be used as a component of the membrane system, as all or part of a course, to increase wear and skid resistance. 1.3 The committee with jurisdiction over this standard is not aware of any comparable standards published by other organizations. 1.4 Test methods in this specification require a minimum 0.5-mm [0.020-in.] base coat dry film thickness. Actual thickness required for a particular application and the use of aggregate in topcoats shall be established by the membrane manufacturer. 1.5 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. 1.6 The following safety hazards caveat pertains only to the test method portion, Section 5, of this specification: This standard does not purport to address all of the safety problems, 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 Specification for High-Solids Content, Cold Liquid-Applied Elastomeric Waterproofing Membrane With Integral Wearing Surface

ASTM C836/C836M-10 与独立磨损层一起使用的高固体含量、应用冷却液体的弹性防水薄膜用标准规范

1.1 This specification describes the required properties and test methods for a cold liquid-applied elastomeric-type membrane, one- or two-component, for waterproofing building decks and walls subject to hydrostatic pressure in building areas to be occupied by personnel, vehicles, or equipment. This specification applies only to a membrane system that will be covered with a separate wearing course, traffic course, or backfill. Note 18212;See Guide C898 and Guide C1471 for proper application of membrane. 1.2 There are no ISO standards similar or equivalent to this ASTM standard. 1.3 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. 1.4 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 Specification for High Solids Content, Cold Liquid-Applied Elastomeric Waterproofing Membrane for Use with Separate Wearing Course

ASTM C834-10 胶乳密封料用标准规范

This specification covers two types and three grades of latex sealants as described in Section 4 that are formulated for general caulking and sealing operations in building construction. It should be recognized by the user that not all sealants meeting this specification are suitable for all applications and all substrates. It is essential, therefore, that the type and grade be specified for proper description of a sealant. Test methods relate to special standard substrates of glass, wood and aluminum. If tests are required using substrates in addition to or other than standard, they should be so specified for testing. Refer to Guide C1193 for information on the proper use of sealants meeting this specification.1.1 This specification covers one component latex sealants used for sealing joints in building construction. 1.2 A sealant meeting the requirements of this specification shall be classified by the manufacturer to be one of the types and grades defined in Section 4. 1.3 The values stated in SI units are to be regarded as the standard. The inch-pound in parenthesis are provided for information purposes only. 1.4 The following precautionary caveat pertains only to the test method portion, Section 10, of this Specification: 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. Note 18212;Currently, there is no ISO standard similar to this specification.

Standard Specification for Latex Sealants

ASTM C717-10e1 建筑用密封件和密封剂的标准术语

1.1 This standard describes terms and definitions and descriptions of terms used or likely to be used in test methods, specifications, guides, and practices (related to building seals and sealants) consistent with the scope and areas of interest of ASTM Committee C24. 1.2 Definitions and descriptions of terms are written to ensure that building seals and sealants standards are properly understood and interpreted.

Standard Terminology of Building Seals and Sealants

ASTM C1472-10 确定密封层接缝宽度时位移和其他影响计算的标准指南

Design professionals, for aesthetic reasons, have desired to limit the spacing and width of sealant joints on exterior walls and other locations of new buildings. Analysis of the performance factors and especially tolerances that affect a sealant joint is necessary to determine if a joint will have durability and be effective in maintaining a seal against the passage of air and water and not experience premature deterioration. If performance factors and tolerances are not understood and included in the design of a sealant joint, then the sealant may reach its durability limit and failure is a distinct possibility. Sealant joint failure can result in increased building energy usage due to air infiltration or exfiltration, water infiltration, and deterioration of building systems and materials. Infiltrating water can cause spalling of porous and friable building materials such as concrete, brick, and stone; corrosion of ferrous metals; and decomposition of organic materials, among other effects. Personal injury can result from a fall incurred due to a wetted interior surface as a result of a failed sealant joint. Building indoor air quality can be affected due to organic growth in concealed and damp areas. Deterioration is often difficult and very costly to repair, with the cost of repair work usually greatly exceeding the original cost of the sealant joint work. This guide is applicable to sealants with an established movement capacity, in particular elastomeric sealants that meet Specification C920 with a minimum movement capacity rating of ± 12½ percent. In general, a sealant with less than ± 12½ percent movement capacity can be used with the joint width sizing calculations; however, the width of a joint using such a sealant will generally become too large to be practically considered and installed. It is also applicable to precured sealant extrusions with an established movement capacity that meets Specification C1518. The intent of this guide is to describe some of the performance factors and tolerances that are normally considered in sealant joint design. Equations and sample calculations are provided to assist the user of this guide in determining the required width and depth for single and multi-component, liquid-applied sealants when installed in properly prepared joint openings. The user of this guide should be aware that the single largest factor contributing to non-performance of sealant joints that have been designed for movement is poor workmanship. This results in improper installation of sealant and sealant joint components. The success of the methodology described by this guide is predicted on achieving adequate workmanship. Joints for new construction can be designed by the recommendations in this guide as well as joints that have reached the end of their service life and need routine maintenance or joints that require remedial work for a failure to perform. Guide C1193 should also be consulted when designing sealant joints. Failure to install a sealant and its components following its guidelines can and frequently will result in failure of a joint design. Peer reviewed papers, published in various ASTM Special Technical Publications (STP), provide additional information and examples of sealant joint width calculations that expand on the information described in this guide (2-5). For cases in which the state of the art is such that criteria for a particular condition is not firmly established or there are numerous..........

Standard Guide for Calculating Movement and Other Effects When Establishing Sealant Joint Width

ASTM C1536-10 气溶胶泡沫密封剂流动性测量的标准试验方法

The yield measurement of aerosol foam sealants is used to indicate the amount of foam sealant that can be obtained from a single can of product. The yield does not predict the performance capability of the foam sealant product or its suitability for the intended application. Procedure A was developed for use with products that can be volumetrically measured by submersion in water. Procedure B was developed for product that cannot be measured by using a water displacement method. Yield is often dependent on the bead size dispensed. Extrapolation of test results using data measured for larger size beads to estimate smaller sized beads has shown inaccuracies. Since yield will be reported based on the diameter of the cured bead (not initial bead size), the operator shall determine the nominal initial bead size required to produce a specific nominal cured bead diameter. This foam characteristic, called “post dispensing contraction” or “post dispensing expansion,” is defined in Terminology C717.1.1 This test method determines the quantity of linear units of a foam sealant having a specified bead diameter that may be obtained from a single can of aerosol product. Four (4) cans are required for each product determination. 1.2 The test method is intended to estimate the contents of the aerosol container (1) for purposes of label statements, and (2) to provide the user information needed to estimate job requirements. 1.3 Foam sealants are used for a variety of end-use applications but are primarily intended to reduce air movement in the building envelope. 1.4 Currently, two main foam sealant types are applicable to this standard: single component polyurethane and latex. 1.5 There is no other known standard test method to measure aerosol foam sealant yield. 1.6 Values are reported in SI units only. Certain apparatus and supply items are referenced in inch-pound units for purchasing purposes. 1.7 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 Measuring the Yield for Aerosol Foam Sealants

ASTM C717-10 建筑密封件和密封胶标准术语

1.1 This standard describes terms and definitions and descriptions of terms used or likely to be used in test methods, specifications, guides, and practices (related to building seals and sealants) consistent with the scope and areas of interest of ASTM Committee C24. 1.2 Definitions and descriptions of terms are written to ensure that building seals and sealants standards are properly understood and interpreted.

Standard Terminology of Building Seals and Sealants

BS EN 14188-4:2009 接缝填充物和密封胶.第4部分:与接缝密封胶一起使用的涂底剂规格

This European Standard specifies requirements for material characterisation for primers for hot and cold applied joint sealants for use in roads, airfields and other concrete pavements. This European Standard also applies to primers for hot and cold applied joint sealants in bituminous surfacing and a bituminous surfacing and an adjacent concrete pavement.

Joint fillers and sealants - Part 4:Specifications for primers to be used with joint sealants