23.100.01 流体动力系统综合 标准查询与下载

T/CMES 24002-2018 水液压系统通用技术条件

本标准规定了水液压系统的设计、安装、运行、监测和维护的一般要求和规则。本标准适用于以水作为工作介质的液压系统与设备

General technical specification for water hydraulic system

BS ISO 18582-2:2018 流体动力 参考词典规范 气动类和属性的定义

What is ISO 18582 ‑ 2 - Fluid power about?    ISO 18582 is a series on fluid power. Fluid power is the use of fluids under pressure to generate, control, and transmit power. ISO 18582 ‑ 2 specifies a reference dictionary of standardized product properties for the area of pneumatic fluid power on the basis of ISO 18582-1 .   ISO 18582 ‑ 2 specifies the attribute information for the definition class, the attribute information for their associated properties and the application classes of the fluid power.   Who is ISO 18582 ‑ 2 - Fluid power for?   ISO 18582

Fluid power. Specification of reference dictionary - Definitions of classes and properties of pneumatics

ISO 18582-2:2018 流体动力.参考字典规范.第2部分:气动分类和特性的定义

This document specifies a reference dictionary of standardized product properties for the area of pneumatic fluid power on the basis of ISO 18582-1. The properties are determined on the basis of standardized attributes.

Fluid power — Specification of reference dictionary — Part 2: Definitions of classes and properties of pneumatics

ISO/TR 22165:2018 流体动力 - 气动系统能源效率优化的应用笔记

Pneumatic fluid power — Application notes for the improvement of the energy efficiency of pneumatic systems

T/ZZB 0703-2018 密相气力滑移输送机系统

本标准规定了密相气力滑移输送机系统的术语和定义、型式和基本式样、基本要求、技术要求、试验方法、检验规则、标志、运输及贮存和质量承诺。 本标准适用于可流态化物料的密相气力滑移输送机系统。 本标准不适用于输送距离大于500 m或负压输送的输送机系统。

Dense pneumatic sliding conveyor system

T/ZZB 0600-2018 家用清洗机

本标准规定了家用清洗机的术语和定义、基本要求、技术要求、试验方法、检验规则、标志、说明书、包装、运输和贮存、质量承诺。 本标准适用于额定压力2.5 MPa～25 MPa，额定输入功率≤5.5 kW，工作介质为常温清水或添加清洗剂配成清洗溶液的家用清洗机（以下简称“清洗机”）。

Household pressure washer

ASTM D4174-17 石油液液压系统的清洗、冲洗和净化的标准实施规程

1.1 This practice covers aid for the equipment manufacturer, the installer, the oil supplier and the operator in coordinating their efforts towards obtaining and maintaining clean petroleum fluid hydraulic systems. Of necessity, this practice is generalized due to variations in the type of equipment, builder’s practices, and operating conditions. Constant vigilance is required throughout all phases of design, fabrication, installation, flushing, testing, and operation of hydraulic systems to minimize and reduce the presence of contaminants and to obtain optimum system reliability. 1.2 This practice is presented in the following sequence: Section Scope 1 Referenced Documents 2 Terminology 3 Significance and Use 4 Types of Contamination 5 General 5.1 Water 5.2 Soluble Contaminants 5.3 Insoluble Contaminants 5.4 Lodged Contamination 5.4.2.1 Suspended or Loose Contamination 5.4.2.2 Contamination Control 6 General 6.1 Initial Filling 6.1.1 In-Service Units 6.1.2 Connection of Contamination Control System 6.1.3 Piping or Tubing Contamination Control System 6.1.4 Contamination Control Procedures 6.2 Full Flow Contamination Control 6.2.1 Bypass Contamination Control 6.2.2 Batch Contamination Control 6.2.3 Contamination Control Processes 6.3 Gravity 6.3.1 Mechanical 6.3.2 Centrifuge 6.3.2.1 Section Filters 6.3.2.2 Supplementary Methods 6.3.3 Limitations of Contamination Control Devices 6.3.4 Storage 7 General 7.1 Inspection 8 General 8.1 System Components 8.2 Valves, Strainers, and Coolers 8.2.1 Sumps and Tanks 8.2.2 Control Devices 8.2.3 Pumps 8.2.4 Flushing Program 9 General 9.1 Preparation of System for Flushing 9.2 Fluid Heating Prior to Flushing 9.3 Selection of Flushing Oils 9.4 System Operation Fluid 9.4.1 Special Flushing Oil 9.4.2 Flushing Oil Selection Guide 9.4.3 Flushing Procedure for New Systems 9.5 Flushing Oil Charge 9.5.1 Cleaning of Filtration Devices 9.5.2 Cleaning of System Components 9.5.3 System Flushing and Flush Acceptance Criteria 9.5.4 Draining of Flushing Oil 9.5.5 Displacement Oil 9.5.6 Interim Corrosion Protection 9.5.7 New Fluid Charge 9.5.8 Flushing of Used Systems 9.6 General Guidelines 9.6.1 Procedure 9.6.2 System Maintenance 10 Preinstallation 10.2 In-Service Units 10.3 Decision to Flush In-Service Hydraulic Systems 10.4 Fluid Condition Monitoring 11 Fluid Sampling Techniques 11.2 Visual Inspection 11.3 Laboratory Analysis 11.4 Fluid Cleanliness Criteria 11.5 General Information 12 Centrifuge Ratings 12.2 Coalescence 12.3 Vacuum Dehydration 12.4 Adsorption 12.5 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 This practice is under the jurisdiction of ASTM Committee D02 on Petroleum Products, Liquid Fuels, and Lubricants and is the direct responsibility of D02.N0 on Hydraulic Fluids. Current edition approved Dec. 1, 2017. Published January 2018. Originally approved in 1982. Last previous edition approved in 2015 as D4174 – 15. DOI: 10.1520/D4174-17. *A Summary of Changes section appears at the end of this standard Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States 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. 1 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, health, and environmental practices and determine the applicability of regulatory limitations prior to use. 1.5 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 Practice for Cleaning, Flushing, and Purification of Petroleum Fluid Hydraulic Systems

KS B 6612-2017 加热自动控温系统

Automatic temperature control system for heating

KS B 6452-2017 液压破碎锤

Hydraulic breakers

KS B 6452-2017(2022) 液压破碎机

Hydraulic breakers

T/ZZB 0231-2017 商用清洗机

本标准规定了商用清洗机的术语和定义、分类、基本要求、技术要求、试验方法、检验规则、包装、运输和贮存、质量承诺等。 本标准适用于工作压力10MPa～40MPa，流量6L/min～90L/min，功率2kW～25kW，转速600r/min～3600r/min，工作压力能平稳调节，使用介质为常温清水或添加清洗剂水溶液的高压清洗机（以下简称清洗机）。

Commercial pressure washer

BS ISO 18869:2017 液压流体动力 使用或不使用工具驱动的联轴器的测试方法

Hydraulic fluid power. Test methods for couplings actuated with or without tools

ISO 18869:2017 液压流体动力 - 用或不用工具启动的联轴器的测试方法

This document specifies methods for testing and evaluating the performance of quick-action couplings for use in hydraulic fluid power applications. This document does not apply to the testing of tube connections, stud ends for ports and flange connections, which are covered by ISO 19879. Test methods covered in this document are independent of each other and outline the method to follow for each test. See the respective connector standard for which tests to conduct and for performance requirements. It is not intended that all tests be carried out for every application; it is up to the user of this document to select the applicable tests. For qualification of the coupling, the minimum number of samples specified in this document is to be tested, unless otherwise specified in the relevant coupling standard or as agreed upon by the manufacturer and the user.

Hydraulic fluid power — Test methods for couplings actuated with or without tools

ISO/TR 16194:2017 气压液动. 通过加速寿命试验评定部件的可靠性. 通用指南和程序

Pneumatic fluid power - Assessment of component reliability by accelerated life testing - General guidelines and procedures

GSO ISO 6358-1:2016 气动流体动力—使用可压缩流体的部件流量特性的测定— 第1部分：稳态流动的一般规则和试验方法

This part of ISO 6358 specifies a steady-state method for testing pneumatic fluid power components that use compressible fluids, i.e. gases, and that have internal flow paths that can be either fixed or variable in size, to determine their flow-rate characteristics. However, this part of ISO 6358 does not apply to components whose flow coefficient is unstable during use, i.e. components that exhibit remarkable hysteretic behaviour (because they can contain flexible parts that deform under the flow) or that have an internal feedback phenomenon (such as regulators). In addition, it does not apply to components that exchange energy with the fluid during flow-rate measurement, e.g. cylinders, accumulators, etc. Table 1 provides a summary of which parts of ISO 6358 can be applied to various components. This part of ISO 6358 specifies requirements for the test installation, the test procedure, and the presentation of results for the steady-state method. This part of ISO 6358 includes several test procedures, including the one described in Annex A, which is from ISO 6358:1989. Flowmeter calibration is described in Annex B. Evaluation of measurement uncertainties is described in Annex C. Observations of the error in the test results are described in Annex D. Equations and graphical representations of flow-rate characteristics are given in Annex E. Guidance on the use of practical units for the presentation of results is given in Annex F. Test results using commercially available pneumatic components are given in Annex G. Guidance on calculating the flow-rate characteristics is given in Annex H.

Pneumatic fluid power -- Determination of flow-rate characteristics of components using compressible fluids -- Part 1: General rules and test methods for steady-state flow

GSO ISO 19973-2:2016 气动流体动力 通过测试评估元件可靠性 第2部分：方向控制阀

This part of ISO 19973 provides test procedures for determining the reliability of pneumatic directional control valves by testing and the methods of reporting the results of testing. General test conditions and the calculation method are provided in part 1 of ISO 19973. The methods specified in that part of ISO 19973 apply to the first failure without repairs, but exclude outliers. The lifetime of pneumatic and electro-pneumatic directional control valves is usually given as a number of cycles. Therefore, whenever the term “time” is used in this part of ISO 19973, this variable is be understood as cycles. This part of ISO 19973 also specifies test equipment and threshold levels for tests to determine the reliability of pneumatic directional control valves.

Pneumatic fluid power -- Assessment of component reliability by testing -- Part 2: Directional control valves

GSO ISO 6358-3:2016 气动流体动力 可压缩流体元件流量特性的测定 第3部分：系统稳态流量特性的计算方法

This part of ISO 6358 specifies a method that uses a simple numerical technique to estimate without measurements the overall flow-rate characteristics of a system of components and piping with known flow-rate characteristics. The formulae used in this part of ISO 6358 describe the behaviour of a compressible fluid flow through a component for both subsonic and choked flows. NOTE The conductance of a tube, silencer or filter is influenced by the upstream pressure, so the values of C and b are only valid for the upstream pressure at which they are determined. This part of ISO 6358 also provides methods to obtain equivalent flow-rate characteristics for components whose flow-rate characteristics differ from those defined in the ISO 6358 series.

Pneumatic fluid power -- Determination of flow-rate characteristics of components using compressible fluids -- Part 3: Method for calculating steady-state flow-rate characteristics of systems

GSO ISO 6358-2:2016 气动流体动力 使用可压缩流体确定部件的流量特性 第2部分：替代测试方法

This part of ISO 6358 specifies a discharge test and a charge test as alternative methods for testing pneumatic fluid power components that use compressible fluids, i.e. gases, and that have internal flow passages that can be either fixed or variable in size to determine their flow-rate characteristics. However, this part of ISO 6358 does not apply to components whose flow coefficient is unstable during use, i.e. components that exhibit remarkable hysteretic behaviour (because they can contain flexible parts that deform under the flow) or that have an internal feedback phenomenon (such as regulators), or components that have a cracking pressure such as non-return (check) valves and quick-exhaust valves. In addition, it does not apply to components that exchange energy with the fluid during flow-rate measurement, e.g. cylinders, accumulators, etc. NOTE This part of ISO 6358 does not provide a method to determine if a component has hysteretic behaviour; ISO 6358-1 does provide such a method. Table 1 provides a summary of which parts of ISO 6358 can be applied to various components. The charge test cannot be performed on components that do not have downstream port connections. This part of ISO 6358 specifies requirements for the test installation, the test procedure, and the presentation of results. Evaluation of measurement uncertainties is described in Annex A. Requirements for a method to test the volume of an isothermal tank are given in Annex B. Guidance on the isothermal tank is given in Annex C. Requirements for a method to test isothermal performance are given in Annex D. Guidance on the equation for calculating characteristics is given in Annex E. Guidance on calculating flow-rate characteristics is given in Annex F.

Pneumatic fluid power -- Determination of flow-rate characteristics of components using compressible fluids -- Part 2: Alternative test methods

KS B 6612-2016 加热自动控温系统

Automatic temperature control system for heating

BS ISO 18582-1:2016 流体传动. 参考字典规范. 组织和结构的总体综述

Fluid power. Specification of reference dictionary. General overview on organization and structure