D10 地质矿产勘察与开发综合 标准查询与下载

DZ/T 0186-1997 直流充电法技术规程

本标准适用于金属、非金属、能源矿产勘查中的充电法勘查，其中的技术规则也适用于水文、工程、环境、灾害等地质问题的充电法勘查。

Technical Regulations for DC Charging Method

DZ/T 0184.10-1997 铀系不平衡地质年龄和铀钍同位素比值测定

本标准规定了铀系不平衡地质年龄和铀、钍同位素比值的测定方法。 本标准适用于处于封闭体系的陆相和海洋碳酸盐(如洞穴堆积物石笋、钟乳石、海洋中未发生重结晶的珊瑚礁)等的同位素地质年龄及铀、钍同位素比值的测定。

Determination of uranium-series disequilibrium geological age and uranium-thorium isotope ratio

DZ/T 0184.9-1997 14C年龄测定

本标准规定了用锂法化学制样，液体闪烁计数法测定14C年龄的方法。 本标准适用于距今年龄在40000年以内的有机碳样品和无机碳样品的14C年龄测定。

14C age determination

DZ/T 0184.8-1997 40Ar-39Ar同位素地质年龄及氩同位素比值测定

本标准规定了40Ar-39Ar同位素地质年龄及氩同位素比值的测定方法。 本标准适用于全岩、单矿物的40Ar-39Ar同位素年龄及氩同位素比值的测定。

Determination of 40Ar-39Ar Isotope Geological Age and Argon Isotope Ratio

DZ/T 0184.7-1997 钾氩同位素地质年龄测定

本标准规定了钾氩同位素地质年龄的测定方法。 本标准适用于岩石、矿物钾氩同位素年龄的测定。

Potassium Argon Isotope Geological Age Determination

DZ/T 0184.6-1997 钐钕同位素地质年龄和钕同位素比值测定

本标准规定了衫(Sm)-钕(Nd)同位素地质年龄和钕(Nd)同位素比值的测定方法。 本标准适用于全岩、单矿物Sm-Nd同位素地质年龄及Nd同位素比值的测定。

Determination of Sm-Nd Isotope Geological Age and Neodymium Isotope Ratio

DZ/T 0187-1997 地面瞬变电磁法技术规程

本标准规定了地面瞬变电磁法工作的基本要求和技术规则。 本标准适用于中、小功率磁源瞬变电磁仪设备进行良导电目标物勘查及地电测深。主要应用于固体矿产勘查。其中的技术规则也适用于水文、工程勘测。

Technical Regulations for Surface Transient Electromagnetic Method

DZ/T 0184.5-1997 石英单矿物及其中热液流体包裹体的铷锶同位素地质年龄测定

本标准规定了石英单矿物及其中热液流体包裹体的铷锶同位素地质年龄测定方法。 本标准适用于石英单矿物及其中热液流体包裹体的铷锶同位素年龄的测定。

Rubidium and Strontium Isotope Geological Age Determination of Quartz Single Mineral and Its Hydrothermal Fluid Inclusions

DZ/T 0188-1997 地学数字地理底图 数据交换格式

本标准规定了地学数字地理底图数据文件交换格式，对数据文件交换格式作了描述和定义，对图素代码作了约定，规定了交换数据长度以及类型，保证地学数字地理底图数据交换的一致性。 本标准适用于1:50000、1:200000、1:250000、1:500000比例尺地学数字地理底图数据交换，也可供建立全国以及区域性大型地理底图数据库时参照。

Geoscience Digital Geographic Basemap Data Interchange Format

DZ/T 0184.1-1997 同位素地质样品分析方法 总则及一般规定

本标准规定了同位素地质分析方法总则及一般规定。 本标准适用于同位素地质分析方法标准的制定。

General rules and general provisions of isotope geological sample analysis methods

DZ/T 0184.2-1997 微量锆石铀铅同位素地质年龄测定

本标准规定了毫克量级锆石的铀铅同位素地质年龄测定方法。 本标准适用于毫克量级锆石的铀铅同位素地质年龄测定。

Determination of Trace Zircon U-Pb Isotope Geological Age

DZ/T 0189-1997 同位素地质年龄数据文件格式

本标准规定了同位素地质年龄数据文件格式，定义了数据项的名称、代码、数据类型及长度、计量单位及文件结构，并对各基本属性加以定义或说明。 本标准适用于地质矿产行业各部门有关同位素地质年龄的数据交换，也可用于数据采集、存储和建立数据库。

Isotope Geological Age Data File Format

DZ/T 0175-1997 煤田地质填图规程（1∶50000 1∶25000 1∶10000 1∶5000）

本规程规定了1：50000、1：25000、1：l0000、1：5000煤田地质填图的目的、工作程度、工作方法及精度要求、原始编录和资料整理、检查验收以及填图总结(报告)的编制。 本规程适用于裸露及半裸露地区煤炭地质勘探各阶段的煤田地质填图(1：50000~1：5000)，是其设计编写、成果验收、质量监控的主要依据。

Coalfield Geological Mapping Regulations (1:50000 1:25000 1:10000 1:5000)

DZ/T 0171-1997 大比例尺重力勘查规范

本标准规定了大比例尺重力勘查的技术设计、仪器准备(含重力仪调节及性能测试)、野外工作、资料整理、精度评价和成果提交等项要求。 本标准适用于矿产普查、详查、圈定岩体(层)、研究地质构造、洞穴探查以及其他特殊探测等目的的大比例尺重力勘查工作。

Specifications for large-scale gravity surveys

DZ/T 0179-1997 地质图用色标准及用色原则

本标准规定了1:50000地质图正式岩石地层、非正式岩石地层、变质深成岩、变质表壳岩、各类杂岩及花岗岩类侵入体岩石谱系单位、续铁质岩、超续铁质岩、碱性岩类、火山岩、潜火山岩、脉岩及其他要素用色标准。 本标准适用于比例尺为1:50000地质图件的彩色设计、制版和印刷用色,也可作为编制出版其他比例尺地质图件用色参考。

Color Standards and Principles for Geological Maps

ASTM D6151-97(2003) 地质技术勘探和土壤取样用空茎轴螺旋钻使用的标准操作规程

1.1 This practice covers how to obtain soil samples using hollow-stem sampling systems and use of hollow-stem auger drilling methods for geotechnical exploration. This practice addresses how to obtain soil samples suitable for engineering properties testing.1.2 In most geotechnical explorations, hollow-stem auger drilling is combined with other sampling methods. Split barrel penetration tests (Test Method D 1586) are often performed to provide estimates of engineering properties of soils. Thin-wall tube (Practice D 1587) and ring-lined barrel samples (Practice D 3550) are also frequently taken. This practice discusses hole preparation for these sampling events. For information on the sampling process, consult the related standards. Other in situ tests, such as the vane shear Test Method D 2573, can be performed below the base of the boring by access through the drill string.1.3 This practice does not include considerations for geoenvironmental site characterizations and installation of monitoring wells which are addressed in Guide D 5784.1.4 This practice may not reflect all aspects of operations. It offers guidance on current practice but does not recommend a specific course of action. It should not be used as the sole criterion or basis of comparison, and does not replace or relieve professional judgment.1.5 Hollow-stem auger drilling for geotechnical exploration often involves safety planning, administration, and documentation. This standard does not purport to specifically address exploration and site safety. 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 its use. Performance of the test usually involves use of a drill rig, therefore, safety requirements as outlined in applicable safety standards, for example OSHA (Occupational Health and Safety Administration) regulations, DCDMA safety manual, drilling safety manuals, and other applicable state and local regulations must be observed.

Standard Practice for Using Hollow-Stem Augers for Geotechnical Exploration and Soil Sampling

ASTM D6168-97e1 确定土壤、岩石和其所含液体描述信息的现场收集用场所所要求的最小数据元集合的选择的标准指南

1.1 This guide covers factors to consider for the selection of the minimum set of data elements required for the accurate location and cataloging of information collected for geological science (geoscience) investigations, which includes geoecology. 1.1.1 Geoscience investigations include soil surveys, foundation investigations, geologic studies, hydrologic evaluations, environmental appraisals, contamination inquiries, archaeological surveys, and other studies that involve the soil, rock, and contained fluids from the lands surface to any explored depth underground. 1.2 A unique geoscience data location, on or below the earth''s surface, can be described by X, Y, and Z coordinates and by that method establish the dimensional relationship to data of a similar nature. Additional location information needed depends upon the type of geoscience data collection locality. 1.2.1 The basic type is a single position described by finite X, Y, and Z coordinates. The X, Y, and Z coordinates uniquely position the location on or below the earth''s surface. Note 1-An example is the latitude and longitude in horizontal coordinates and the altitude (or elevation) in vertical distance of a ground-water location or site. Data collected at the site, for example, water levels, are measured by the vertical interval as referenced to the altitude. 1.2.2 Another type of location is described by finite X and Y coordinates that has multiple vertically positioned Z coordinates. This is equivalent to the location type described in 1.2.1, except that mulitple vertical dimensions are stated as Z coordinates, rather than vertical intervals. Note 2-An example of latitude, longitude, and multiple altitudes of a soil sampling location or site. Each altitude represents a different sampling position that has the same latitude and longitude coordinate. The upper and lower limit of a sampling interval can be expressed by altitudes. 1.2.3 Another type is a location described by finite X and Y coordinates with multiple Z coordinates that are not vertically oriented from X and Y coordinates. Note 3-An example is a slanted borehole where the top is at a different latitude and longitude coordinate than the sampling positions in the hole. Methods of describing these sampling points are: treat each position as a separate location with finite latitude, longitude, and altitude values; describe the horizontal deviation of the sampling point from the finite latitude and longitude coordinates at the top of the borehole. 1.2.4 Another type is a location with considerable horizontal dimension that cannot be described by a finite X and Y coordinate, however, a single Z coordinated may be acceptable. Note 4-Examples are sinkholes, waste disposal pits, septic systems, underground injection facilities, mines, archaelogical sites, and some ponds or lakes. These locations can be described by including additional information that gives the horizontal components of the location along with the latitude, longitude, and altitude coordinates or by multiple sets of X and Y coordinates that encompass the location. 1.3 Additional key data elements are needed to simplify the identification and cataloging of the geoscience data. 1.3.1 These elements describe political entities, data sources, and individual characteristics of the location. Note 5-The data assist in file organization by placing the information into logical categories and to further identify the geoscience location by use of familiar terminology. A carefully designed minimum set of data elements contributes to the recoverability and the future value of the entire data file. 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 ......

Standard Guide for Selection of the Minimum Set of Data Elements Required to Identify Locations Chosen for the Field Collection of Information to Describe Soil, Rock, and Their Contained Fluids

ASTM D6167-97(2004) 地球物理测井管道钻孔的标准指南:机械卡钳

An appropriately developed, documented, and executed guide is essential for the proper collection and application of caliper logs. This guide is to be used in conjunction with Guide D 5753. The benefits of its use include the following: improving selection of caliper logging methods and equipment, caliper log quality and reliability, and usefulness of the caliper log data for subsequent display and interpretation. This guide applies to commonly used caliper logging methods for geotechnical applications. It is essential that personnel (see the Personnel section of Guide D 5753) consult up-to-date textbooks and reports on the caliper technique, application, and interpretation methods.1.1 This guide covers the general procedures necessary to conduct caliper logging of boreholes, wells, access tubes, caissons, or shafts (hereinafter referred as boreholes) as commonly applied to geologic, engineering, ground-water and environmental (hereinafter eeferred as geotechnical) investigations. Caliper logging for mineral or petroleum exploration and development are excluded.

Standard Guide for Conducting Borehole Geophysical Logging: Mechanical Caliper

ASTM D6168-97(2004) 确定土壤、岩石和其所含液体描述信息的现场收集用场所所要求的最小数据元集合的选择的标准指南

Adequately documented geoscience data are beneficial to studies utilizing traditional and computer technology for conducting resource surveys and in analyzing environmental concerns. 4.1.1 Geoscience data that include the standard coordinates pinpoint the location of the information on or below the earthrsquo;surface and by that establish the dimensional relationship to data of a similar nature (see 5.2). Note 68212;Some investigations destroy the sample in the process. As such, the information cannot be duplicated by resampling. The data and the original location of the tested sample may be the only remaining result. 4.1.2 Geoscience data that include “key” information has an enhanced capability for acceptable verification, as each additional data item strengthens the uniqueness for singular identification. 4.1.2.1 Key data categories included for unique identification of the geoscience information consist of political regimes, source of data, and location characteristics (see 5.3). Use of a standardized minimum set of data elements by project investigators increase the usefulness of the geoscience information, in that the material can more easily be interchanged. 4.2.1 Data verification, essential in quality control, can be more routine when geoscience locations are accurately identified. 4.2.2 Key items allow for ease of selection by placing the geoscience data into logical categories, such as counties, resource extraction locations, and source agencies. 4.2.3 Data files organized by use of key data elements, whether stored in cabinets or a computer file, are less complicated to find. 4.2.4 Geoscience data are usually collected for an ongoing project, however, the value is greatly increased when these data are available for future studies.1.1 This guide covers factors to consider for the selection of the minimum set of data elements required for the accurate location and cataloging of information collected for geological science (geoscience) investigations, which includes geoecology.1.1.1 Geoscience investigations include soil surveys, foundation investigations, geologic studies, hydrologic evaluations, environmental appraisals, contamination inquiries, archaeological surveys, and other studies that involve the soil, rock, and contained fluids from the lands surface to any explored depth underground.1.2 A unique geoscience data location, on or below the earth''s surface, can be described by X, Y, and Z coordinates and by that method establish the dimensional relationship to data of a similar nature. Additional location information needed depends upon the type of geoscience data collection locality.1.2.1 The basic type is a single position described by finite X, Y, and Z coordinates. The X, Y, and Z coordinates uniquely position the location on or below the earth''s surface.Note 18212;An example is the latitude and longitude in horizontal coordinates and the altitude (or elevation) in vertical distance of a ground-water location or site. Data collected at the site, for example, water levels, are measured by the vertical interval as referenced to the altitude.1.2.2 Another type of location is described by finite X and Y coordinates that has multiple vertically positioned Z coordinates. This is equivalent to the location type described in , except that multiple vertical dimensions are stated as Z coordinates, rather than vertical intervals.Note 28212;An example is latitude, longitude, and multiple altitudes of a soil sampling location or site. Each altitude represents a different sampling position that has the same latitude and longitude......

Standard Guide for Selection of Minimum Set of Data Elements Required to Identify Locations Chosen for Field Collection of Information to Describe Soil, Rock, and Their Contained Fluids

ASTM D6168-97(2010) 确定土壤、岩石和其所含液体描述信息的现场收集用场所所要求的最小数据元集合的选择的标准指南

Adequately documented geoscience data are beneficial to studies utilizing traditional and computer technology for conducting resource surveys and in analyzing environmental concerns. Geoscience data that include the standard coordinates pinpoint the location of the information on or below the earth's surface and by that establish the dimensional relationship to data of a similar nature (see 5.2). Note 68212;Some investigations destroy the sample in the process. As such, the information cannot be duplicated by resampling. The data and the original location of the tested sample may be the only remaining result. Geoscience data that include “key” information has an enhanced capability for acceptable verification, as each additional data item strengthens the uniqueness for singular identification. Key data categories included for unique identification of the geoscience information consist of political regimes, source of data, and location characteristics (see 5.3). Use of a standardized minimum set of data elements by project investigators increase the usefulness of the geoscience information, in that the material can more easily be interchanged. Data verification, essential in quality control, can be more routine when geoscience locations are accurately identified. Key items allow for ease of selection by placing the geoscience data into logical categories, such as counties, resource extraction locations, and source agencies. Data files organized by use of key data elements, whether stored in cabinets or a computer file, are less complicated to find. Geoscience data are usually collected for an ongoing project, however, the value is greatly increased when these data are available for future studies.1.1 This guide covers factors to consider for the selection of the minimum set of data elements required for the accurate location and cataloging of information collected for geological science (geoscience) investigations, which includes geoecology. 1.1.1 Geoscience investigations include soil surveys, foundation investigations, geologic studies, hydrologic evaluations, environmental appraisals, contamination inquiries, archaeological surveys, and other studies that involve the soil, rock, and contained fluids from the lands surface to any explored depth underground. 1.2 A unique geoscience data location, on or below the earth's surface, can be described by X, Y, and Z coordinates and by that method establish the dimensional relationship to data of a similar nature. Additional location information needed depends upon the type of geoscience data collection locality. 1.2.1 The basic type is a single position described by finite X, Y, and Z coordinates. The X, Y, and Z coordinates uniquely position the location on or below the earth's surface. Note 18212;An example is the latitude and longitude in horizontal coordinates and the altitude (or elevation) in vertical distance of a ground-water location or site. Data collected at the site, for example, water levels, are measured by the vertical interval as referenced to the altitude. 1.2.2 Another type of location is described by finite X and Y coordinates that has multiple vertically positioned Z coordinates. This is equivalent to the location type described in 1.2.1, except that multiple vertical dimensions are stated as Z coordinates, rather than vertical intervals. Note 28212;An example is latitude, longitude, and multiple altitudes of a soil sampling location or site. Each altitude represents a different sampling position that has the same latitud......

Standard Guide for Selection of Minimum Set of Data Elements Required to Identify Locations Chosen for Field Collection of Information to Describe Soil, Rock, and Their Contained Fluids