D10 地质矿产勘察与开发综合 标准查询与下载

DIN 21913-6:2014 矿山测量平面图.地下采矿.第6部分:妥善保护

Mine plans - Deep mining - Part 6: Safekeeping

DZ/T 0266-2014 矿产资源开发遥感监测技术规范

本标准规定了矿产资源开发(矿产资源开发状况、矿山地质环境问题和矿产资源规划等)遥感监测的工作内容、程序、方法及要求等。本标准适用于应用航空、航天遥感技术进行矿产资源开发遥感监测。矿产资源开发应急监测等工作可参照执行。

Regulation on remote sensing monitoring of mining exploration

DZ/T 0264-2014 遥感解译地质图制作规范 （1：250000）

本标准规定了遥感解译地质图制作的工作内容、方法、程序以及图面要素的表达方式。本标准适用于区域地质、矿产地质和环境地质1∶250 000遥感解译地质图的制作,其他比例尺的遥感解译地质图的制作可参照执行。

Standard for production of geological map interpreted with remote sensing image (1∶250 000)

DZ/T 0054-2014 《定向钻探技术规程》

本标准规定了定向钻探的设计、设备的选择、施工工艺、轨迹控制与测量、事故的预防和处理及施工管理等技术要求。本标准适用于地质岩心钻探工程中的定向钻探,工程勘察、工程施工、水文水井钻探及油气井钻探中的定向钻探设计和施工可参照本标准。

Technical Specification for Directional Drilling

DZ/T 0255-2014 海洋区域地质调查规范(1∶50000)

本标准规定了 1 : 50 000海洋区域地质调查的目的任务、调查内容、调查方法、资料处理及成果编制等整个工作过程的技术要求。本标准适用于近海水域1 : 50 000海洋区域地质调查工作。

Specifications for regional marine geological survey (scale: 1 : 50 000)

DZ/T 0256-2014 海洋区域地质调查规范(1∶250000)

本标准规定了1:250 000海洋区域地质调查的目的任务、调查内容、调查方法、资料处理及成果编制等技术要求。本标准适用于1:250 000海洋区域地质调查工作。

Specifications for regional marine geological survey (scale:1:250 000)

DIN 21915:2013 开采计划.技术设施

Mine plans - Technical facilities

AQ/T 2049-2013 地质勘查安全防护与应急救生用品（用具）配备要求

Requirements for Geological Exploration Safety Protection and Emergency Lifesaving Articles (Apparatus)

EJ/T 363-2012 地面伽玛能谱测量规范

本标准规止了地「伽玛能谱测量的日的任务和工作设计、 仪器校准、 野外工作及室内资料整理的 技术耍求。 本标准适H于铀矿地质勘查。 也适川二′^其它相关矿产地质勘杳和地质环境调查评价。

Ground-based Gamma Spectroscopy Specifications

EJ/T 865-2012 硬岩型铀矿探矿工程地质物探原始编录规范

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Specifications for the original catalog of prospecting engineering geophysics and geophysical prospecting for hard rock type uranium deposits

DB37/T 2322-2013 智慧矿山建设规范

本标准规定了智慧矿山的建设原则、建设内容、系统升级策略及长效管理机制建设。 本标准适用于指导生产矿山的智慧化建设，同时作为智慧矿山建设验收的依据。

Smart Mine Construction Specifications

EN 16301:2013 天然石材试验方法 对意外染色敏感性的测定

The European Standard specifies a method to assess the sensitivity of natural stones when exposed to accidental staining. It defines a procedure for the application of the stains, the cleaning and the assessment of the surface appearance after cleaning. It also covers the possibility to assess the efficiency of a surface treatment. Note that the method does not intend to present any de-staining technique.

Natural stone test methods - Determination of sensitivity to accidental staining

DIN 21919-1:2013 矿计划. 地层学. 第1部分: 一般分类

Mine plans - Stratigraphy - Part 1: General classification

DIN 21920-1:2013 矿计划. 岩相学. 第1部分: 一般适用符号. 沉积物

Mine plans - Petrography - Part 1: Generally applicable symbols - Sediments

DIN 21912-3:2013 矿山平面图. 露天矿山. 第3部分:经营计划

Mine plans.Open cast mining.Part 3: Operating plan

ASTM E2278-13 露天矿土壤改良用煤燃烧产物使用的标准指南: 酸性矿山排水的消耗和缓解

4.1 General—CCPs can effectively be used to reclaim surface mines (5-10). First, CCPs are ideally suited for use in numerous reclamation applications. Any type of CCP may be evaluated for use in mine reclamation. Project specific testing is necessary to ensure that the CCPs selected for use on a given project will meet the project objectives. Second, the use of CCPs can save money because they are available in bulk quantities and reduce expenditures for the manufacture and purchase of Portland cement or quicklime. Third, large-scale use of CCPs for mine reclamation conserves valuable landfill space by recycling a valuable product to abate acid mine drainage and reduce the potential for mine subsidence, provided that the CCP is environmentally and technically suitable for the desired use. The availability of CCPs makes it possible to reclaim abandoned mineland that could not otherwise be reclaimed. The potential for leaching constituents contained in CCPs should be evaluated to ensure that there is no adverse environmental impact. 4.2 Physical and Chemical Properties and Behavior of CCPs—Fly ash, bottom ash, boiler slag, FGD material and FBC ash, or combinations thereof, can be used for mine reclamation. Each of these materials typically exhibits general physical and chemical properties that must be considered in the design of a mine reclamation project using CCPs. The specific properties of these materials vary from source to source so environmental and engineering performance testing is recommended for the material(s) or combinations to be used in mine reclamation projects. 4.2.1 Physical Properties: 4.2.1.1 Unit Weight—Unit weight is the weight per unit volume of material. Fly ash has a low dry unit weight, typically about 50 to 100 pcf (8 to 16 kN/m3). Bottom ash is also typically lighter than coarse grained soils of similar gradation. Stabilized FGD material from a wet scrubber and FGD material from a dry scrubber are also relatively lightweight, with unit weights similar to fly ash. 4.2.1.2 Strength—Shear strength is the maximum resistance of a material to shearing stresses. The relatively high shear strength of fly ash is beneficial for CCP flowable fill formulations requiring strengths sufficient to prevent mine subsidence. The shear strength of non-self-hardening fly ash is primarily the result of internal friction. Cementitious CCPs experience a cementing action that is measured as cohesion and increases over time, which results in high compressive strength. Unconfined compressive strengths in excess of 1000 psi can be achieved for cementitious CCPs. 4.2.1.3 Specific Gravity—Specific gravity is the ratio of the weight in air of a given volume of solids at a stated temperature to the weight in air of an equal volume of distilled water at a stated temperature. The particle specific gravity of fly ash is relatively low compared to that of natural materials, and generally ranges from 2.1 to 2.6. 4.2.1.4 Grain-Size Distribution—Grain-size distribution describes the proportion of various particle sizes present in a material. Fly ash is a uniformly-graded product with spherical, very fine grained particles. 4.2.1.5 Moisture Content—Moisture content is the ratio of the mass of water contained in the pore spaces of soil or rock material to the solid mass of particles in tha......

Standard Guide for Use of Coal Combustion Products (CCPs) for Surface Mine Reclamation: Revegetation and Mitigation of Acid Mine Drainage

ASTM D7572-13 从矿山岩和土壤中提取氰化物的回收标准指南

5.1 This guide is intended as a means for obtaining an extract from mine rock and soil samples to measure cyanide content in the aqueous portion of the sample on a dry weight basis. Cyanide is analyzed in mine rock and soil extracts for measurement of cyanide concentration; however, improper sample collection and extraction can result in significant positive or negative bias. 5.2 This guide is designed to mobilize aqueous cyanides present in the solids, so that the resulting extract can be used to assess leachate that could potentially be produced from mine rock or soil. 5.3 This guide is not intended to simulate actual site leaching conditions. 5.4 This guide produces extracts that are amenable to the determination of trace cyanides. When trace cyanides are being determined, it is especially important that precautions be taken in sample preservation, storage, and handling to avoid possible contamination of the extracts. 5.5 This guide uses a comparative test method and is intended for use as a routine method for monitoring mine rock and soils. It is assumed that all who use this guide will be trained analysts capable of performing it skillfully and safely. It is expected that work will be performed in a properly equipped laboratory applying appropriate quality control practices such as those described in Guide D3856. 5.6 This guide identifies proper methods for obtaining mine rock and soil samples for the specific purpose of measuring cyanide concentrations. 1.1 This guide is applicable for the collection, extraction, and preservation of extracts from mine rock and soil samples for the analysis of cyanide in the extracts. Responsibilities of field sampling personnel and the laboratory are indicated. 1.2 The sampling, preservation, and extraction procedures described in this guide are recommended for the analysis of total cyanide, available cyanide, weak acid dissociable cyanide, and free cyanide by Test Methods D2036, D4282, D4374, D6888, D6994, D7237, and D7284. The information supplied in this guide can also be applied to other analytical methods for cyanide, for example, US EPA Method 335.4. 1.3 The procedure options methods appear in the following order:   Procedure Option Sections

Standard Guide for Recovery of Aqueous Cyanides by Extraction from Mine Rock and Soil

ASTM E2243-13 露天矿土壤改良用煤燃烧产物使用的标准指南: 再造型和采矿工作面回收

4.1 Significance and Use—CCPs can be effective materials for use for reclamation of surface mines. Following are key scenarios in which CCPs may be utilized beneficially in a mined setting: Structural fill Road construction Soil modification or amendment for revegetation (5-9) Isolation of acid forming materials (5) Reduction of acid mine drainage (AMD) (5,10-15) Highwall mining (16,17) 4.1.1 These options represent most, but not all, scenarios under which CCPs would be returned to the mine. This guide discusses issues related to highwall mining and recontouring. Because of the chemical and physical characteristics of CCPs and the benefits derived from the use of CCPs in these applications, placement of CCPs in a surface mine setting qualifies as a beneficial use as defined in Terminology E2201. 4.1.2 CCPs are ideally suited for use in numerous fill applications. Structural fills and other high-volume fills are significant opportunities for placement of CCPs in mine situations for reclamation, recontouring, and stabilizing slopes. These applications are the focus of this guide. 4.1.3 Any type of CCP may be evaluated for use in mine reclamation, even fly ash with high carbon content. Project-specific testing is necessary to ensure that the CCPs selected for use on a given project will meet the project objectives. The use of CCPs can be cost effective because they are available in bulk quantities and reduce expenditures for the manufacture and purchase of borrow material, Portland cement, or quicklime. Large-scale use of CCPs for mine reclamation conserves landfill space by recycling a valuable product, provided that the CCP is environmentally and technically suitable for the desired use. 4.2 Use of CCPs for Mine Reclamation—E2201 the Standard on Fly ash, bottom ash, boiler slag, FGD material, and FBC ash or combinations thereof can be used for mine reclamation. Each of these materials typically exhibits general physical and chemical properties that must be considered in the design of a mine reclamation project using CCPs. The specific properties of these materials vary from source to source, so environmental and engineering performance testing is recommended for the material(s) or combinations to be used in mine reclamation projects. Guidance in evaluating the physical, engineering, and chemical properties of CCPs is given in Sections 6 and 7. 4.3 Engineering Properties and Behavior—Depending on the mine reclamation application, fly ash, bottom ash, boiler slag, FGD material, FBC fly ash, FBC bottom ash, or combinations thereof may have suitable an......

Standard Guide for Use of Coal Combustion Products (CCPs) for Surface Mine Reclamation: Re-contouring and Highwall Reclamation

SY/T 6932-2012 石油地质图形数据交换规范

本标准规定了平面图、录井图、剖面图、对比图、交汇图的图形文件格式。本标准适用于石油地质图形的存储。

Petroleum geological graphic data exchange specification

SY/T 6931-2012 石油地质绘图软件符号规范

本标准基于SY/T 6932—2012《石油地质图形数据交换规范》,规定了石油地质符号的计算机矢量定义,其中包括符号绘制所需的几何数据与样式数据。本标准适用于石油地质绘图软件中符号的绘制。

Drawing pattern of geology software for petroleum geology