S9030程序介绍

依玛士 9020/9030 喷码机高级培训手册依玛士（上海）标码技术有限公司目 录一．公司简介及安全事项--------------------------------------41-1 公司及产品简介1-2 设备保修期内、外的服务1-3 喷码机使用安全注意事项1-4 操作中的注意事项二．喷码基本原理----------------------------------------------112-1 点阵成字原理2-2 喷头工作原理三、喷码机结构-------------------------------------------------133-1 喷码机外观3-2 喷码机内部结构3-3 喷头结构3-4 控制面板说明四、喷码机工作原理----------------------------------------- -59 油墨管路工作原理五、日常开关机步骤--------------------------------- ----------545-1 日常开机步骤5-2 油墨和添加剂液位报警5-3 墨线开启不成功的处理5-4 日常关机步骤六、信息编辑----------------------------------------------------356-1 新建一条信息---- F26-2 选择字形（图案或特殊字体）6-3 固定字符的输入（英文与数字等）6-4 变量的输入（日期）6-5 变量的输入（计数器）6-6 信息参数的修改6-7 信息保存与关闭6-8 选择喷印信息--- F16-9 编辑当前信息的内容--- F36-10 拼音输入汉字6-11 修改当前信息的参数--- F46-12 计数器的显示与复位--- F5 七、机器维护保养----------------------------------------------497-1 维护保养的重要性7-2 消耗品与机器维护7-3 保养计划7-4 清洁机器7-5 清洗油墨管路并更换过滤组件7-6 整机维护功能介绍八、电气连接----------------------------------------------------548-1 工业接口板概貌8-2 传感器接线8-3 同步器接线8-4 报警输出8-5 交换数据-----PCMCIA卡的应用九、故障处理----------------------------------------------------689-1 喷头盖未合（84）9-2 充电检测故障（81&82）9-3 断点调整9-4 高压故障（87&86）9-5 回收故障（85）9-6 喷印不良9-7 浓度故障（70&83）9-8 无故障显示，但不喷印9-9 喷印速度报警（40&48）9-10油墨管路故障（71～79）附录----------------------------------------------------------------76 9020/9030 主动性维护服务协议一．公司简介及安全事项1-1 公司及产品简介一家跨国专业公司 依玛士公司是集科研、开发、生产为一体的跨国专业公司，总部及主要生产基地位于法国，在全球设有32个分公司、60个商务代表处。

第三章作业控制语言3．1 基本概念在大型服务器系统中，当用户需要使用计算机完成某项任务时，用户必须准备一个作业流(Job Stream)。

作业流中包含一个或多个作业（Job）。

作业是用户在完成该任务时要求计算机所做工作的集合。

与COBOL等一般的编程语言不同，作业控制语言JCL（Job Control Language）是用户与操作系统的接口。

用户通过JCL的相应语句来与操作系统通讯，获得作业所需的资源等，按自己的意图来控制作业的执行。

ＪＣＬ由几个语句组成，对于一个作业，JCL为被执行的任务引导操作系统，并说明所需要的全部Ｉ／Ｏ设备。

在一个作业中，每一次程序的执行称为一个作业步，一个作业可包含几个作业步。

一般的，一个作业由以下相对独立的三步组成：（1）编译：把源程序语句（源模块）转换成目标模块；（2）链接编辑：把目标模块同子程序库中的其他程序链接起来得到可执行模块；（3）执行：运行可执行模块得到结果。

一个作业中的各步是顺序执行的，因此一个作业步的输出可以作为下一个作业步的输入。

大型服务器系统中用户的作业可以由一个或多个作业步构成。

只有一个作业步的作业叫做单步作业；由多个作业步构成的作业叫做多步作业。

不论单步作业还是多步作业都必须包含三个JCL基本语句（JCL Statement）。

它们分别是：（1）作业语句（JOB）：标识一个作业的开始，提供必要的运行参数。

（2）执行语句（EXEC）：标识一个作业步的开始，定义本作业步所要执行的程序或过程。

（3）数据定义语句（DD）：用于描述应用程序所需要的数据文件。

系统规定这三种语句行必须以“//”开头。

下面是一个多步作业的例子：//JOB1 JOB …//STEP1 EXEC …//DD1 DD …作业步1//STEP2 EXEC …//INDD1 DD …作业步2//INDD2 DD …//除了上述一些基本概念，有关数据结构和存取方法的概念在JCL的使用中也是非常重要的，由于这一部分已在本书的第二章中详细讨论过，就本章不再重复了。

USER MANUALPROCESS ANALOGUE CALIBRATORAR904Version 1.1.12013.02.13Thank you for choosing our product.This user manual will help you with proper and safeoperation and full use of the process analogue calibrator device.Before installing and operating, please readand understand this manual.If you have any additional questions, please contact the technical advisor. TABLE OF CONTENTSPay special attention to information marked with this sign!Manufacturer reserves the right to make changes in design and software of the device without compromising technical parameters1.SAFETY PRECAUTIONS▪Before using the unit, please read this manual carefully.▪To avoid electrical shock or damage to the device, mechanical and electrical installation have to be performed by a qualified personnel.▪Before turning on the power make sure that all cables are properly connected.▪Before making any modifications to the wiring connections, turn off all voltages applied to the device. ▪You have to ensure proper working conditions, according to the specifications of the device (power supply voltage, humidity, temperature, chapter 5).2.INSTALLATION NOTESThis instrument was designed to provide the appropriate level of resistance to most disturbances that may occur in industrial environments. In environments with unknown level of interference it is recommended to use the following measures to prevent possible interference with operation of the instrument:▪Do not power supply the device from the same line as the power component without the appropriate network filters.▪Use only shielded power and signal cables taking into account that the grounding of the shield should bea single point, made as close to the device as possible.▪Avoid placing signal cables very close and parallel to energy and power cables.▪It is recommended to twist signal cables in pairs.▪Avoid proximity of remote controlled devices, electromagnetic meters, high power loads, loads with phase or group power control and other devices that generate large impulse disturbances.▪Ground or zero metal rails that are used to mount rail devices.Before using the device, remove the protective film from the LED display.3.GENERAL PROCESS ANALOGUE CALIBRATOR CHARACTERISTICS▪This device allows you to control or test devices with current or voltage input (proportional valves, servomotors, inverters, motors, etc.)▪ 2 analogue outputs (working simultaneously):-current 4÷20mA or 0÷20mA (active, cannot be powered from 2 wires current loop)-voltage 0÷10V▪Soft start/stop (ramping) or triangle wave generator with manual or automatic (activated after device power on) trigger.▪Programmable setpoint value, output signal change step, display range, soft start/stop options, communication options, access options and other configuration parameters.▪7-segment LED display with brightness adjustment.▪Optional RS485/RS232 serial interface (galvanically isolated, MODBUS-RTU protocol).▪Parameters configuration methods:-Using IP65 foil keyboard located on the device front panel-Using AR955 programmer or RS485/RS232 interface with PC software (Windows 2000/XP/Vista/7)▪Available free software that allows parameters configuration.▪Access to configuration parameters can be password protected.▪High accuracy and high resistance to interference.▪Available accessories:-AR955 programmer-RS485 to USB converterCAUTION:Before starting work with the process analogue calibrator, read this manual carefully and perform electrical and mechanical installation properly and set parameters correctly.4.PACKAGE CONTENTS▪Process analogue calibrator▪User manual▪Warranty card5.TECHNICAL DATA(1)- Output cannot be powered from two wires current loop6.HOUSING DIMMENSIONS AND INSTALLATION DATA7.TERMINAL STRIPS AND ELECTRICAL CONNECTIONS DESCRIPTIONa)Terminals and output signals descriptionOnly AR955 programmer can be connected to PRG socket. Connecting other devices to PRG socket can damage connected device and AR904 process analogue calibrator.8.BUTTONS DESCRIPTIONa) Buttons functions in setpoint value display mode (normal mode)) )and 9: b) Buttons functions in parameters configuration mode (chapter 10)9.OUTPUTS SETPOINT VALUE CHANGEPressing [UP] or [DOWN] button while setpoint value is being displayed will change the value by pre-set step(parameter 6: , chapter 10, table 10). Changes of the output signal are proportional to changes of the displayed value. Pressing [SET] + [DOWN] buttons together will set output value immediately to lower rangevalue (2: or 4: ) while pressing [SET] + [UP] buttons together will set output value immediately to upperrange value (3: or 5: ). In addition, the output signal may be given also in parameters programming mode(parameter 7: ) and using serial interface RS485/RS232 or AR955 programmer (chapter 15, table 15). Moreover, it is possible to set the setpoint value outside of the display range based on the parameters 2: and 3:. The value of this override that can be set using the buttons is ±5% for 4÷20mA (2÷10V) output and 6,2% for the remaining outputs.10.CONFIGURATION PARAMETERS SETUPAll configuration parameters of the device are saved in the non-volatile EEPROM internal memory. Two parameters configuration methods are available:ing IP65 foil keyboard located on the front panel of the device:-From the setpoint value display mode enter configuration menu (press and hold for more than 1 second [UP] and [DOWN] buttons together). If parameter 13: (password protection is turned on), display will show message and then with first digit blinking. Using [UP] or [DOWN] button enter protection password (by default parameter 12: ). To proceed to the next digit or confirm the code use [SET] button.-After opening configuration menu you will see mnemonic parameter names ( <-> <-> <-> etc.), [UP] button will proceed to the next parameter and [DOWN] button will go back to theprevious parameter (all parameters are listed in table 10).-To change or display current parameter value press the [SET] button.-Using [UP] or [DOWN] button change the edited parameter value.-Confirm modified value using [SET] button or cancel using [UP] and [DOWN] buttons (simultaneously), then parameter name will be displayed.ing RS485/RS232 port or AR955 programmer and pc software ARSOFT-WZ1:-Connect process analogue calibrator to the PC port and start ARSOFT-WZ1 application.-After connection is established application window will display current setpoint value.-Device parameters can be displayed and modified in the parameters configuration window.-New paramete rs values have to be saved using “Zatwierdź zmiany” button.-Current configuration can be saved in a file or can be read from the file.CAUTION:-Do not use RS485/RS232 port and AR955 programmer simultaneously, because communication errors will occur.Table 10. Configuration parameters0: currentdot position(0.0)display units – display for 0mA, 4mA, 0V – lower output rangedisplay units – display for 20mA, 10V – upper output rangesetpoint units – lower setpoint value limit (parameter 7: )when set using buttonssetpoint units – upper setpoint value limit (parameter 7: )when set using buttonsvalue units, setpoint value change step (parameter 7: ) when setusing buttonssetpoint or 4:or 5: , changes step: 6:soft start The duration of the rising edge (ramp). Function isturned on for value (description in chapter 11) soft stop The duration of the falling edge (ramp). Function isturned on for value (description in chapter 11) rampsetpointdisplay (10% step)RS485/RS232 kbit/s kbit/s kbit/s kbit/s kbit/s kbit/s11.SOFT START/STOP AND TRIANGLE WAVEFORM GENERATORThis device has soft start and stop (ramp) function. This function works as shown on the below charts (illustrations 11.1, 11.2, 11,3). To turn on this function you will have to configure soft start time (rising slope,parameter 8: , chapter 10) or soft stop time (falling slope, parameter 9: ) and trigger mode (parameter10: ). If both times are different than 0 (8: and 9: ) device outputs will generate triangle periodicalsignal. Amplitudes (end values) of output signals are defined by parameter 2: , 3: , 4: and 5:. Function is activated automatically after device power on (when parameter 10: ) or manually (10: ) using [SET] button (pressed and hold for more than 1.5 seconds). Moreover ramp function can be stopped and resumed at any time using [SET] button (short message will be displayed - start or - stop). Output status in this mode is refreshed 4 times per second.Illustration 11.1. Output status in soft start mode (parameter ).Illustration 11.2. Output status in soft stop mode (parameter ).Illustration 11.3. Output status in triangle signal generator mode (parameter ).12.MESSAGES AND ERRORS LISTFollowing short messages can be displayed during device operation:13.RS485 COMMUNICATION INTERFACE (per EIA RS-485)Maximum RS485 cable length – 1km.Maximum number of devices in RS485 line – 30. To increase this number you can use RS485/RS485 repeater. Terminal resistors when MASTER is on the line beginning (above illustration):-On the line beginning –2 x 820Ω to ground and +5V of the MASTER and 150Ω between lines,- On the line end - 150Ω between lines.Terminal resistors when MASTER is in the middle of the line:- Near the converter – 2 x 820Ω to ground and +5V of the converter, - On both line ends – each end 150Ω between lines.14. RS232C COMMUNICATION INTERFACE (per EIA RS-232C)15. MODBUS-RTU SERIAL TRANSMISSION PROTOCOL Character format:8 bits, 1 stop bit, no parity bitAvailable functions: READ – 3 or 4, WRITE – 6Table 15.1. Request frame format for READ function (frame length – 8 Bytes):Table 15.2. Request frame format for WRITE function (frame length– 8 Bytes):Table 15.3. Response frame format for READ function (minimum frame length – 7 Bytes):Table 15.4. Response frame format for WRITE function (frame length – 8 Bytes):Table 15.5. Special response (errors: function field = 0x84 or 0x83 for READ function and 0x86 for WRITE function):Table 15.6. MODBUS-RTU protocol registers mapParameter 0:Parameter 1: dot positionParameter 2: display lower rangeParameter 3:Parameter 4:Parameter 5:Parameter 6:Parameter 7:Parameter 8:Parameter 9:Parameter 10:Parameter 11:Parameter 12:Parameter 13:Parameter 14:Parameter 15:Parameter 16:ER NOTES。

订购信息目录编号描述目录编号描述离散量输入模块IC693MDL230120 VAC 隔离输入（8点）IC693MDL64524 VDC 输入、负/正逻辑（16点）IC693MDL231240 VAC 隔离输入（8点）IC693MDL64624 VDC 输入、负/正逻辑、1 msec 过滤器（16点）IC693MDL240120 VAC 输入（16点）IC693MDL64848 VDC 输入、负/正逻辑、1 msec 过滤器、负/正逻辑（16点）IC693MDL24124 VAC/VDC 输入（16点）IC693MDL65324 VDC 输入、负/正逻辑、2msec 过滤器（32点）IC693MDL250*120 VAC 隔离输入（16点）IC693MDL6545/12 VDC(TTL)输入、负/正逻辑、（32点）IC693MDL260*120 VAC 输入（32点）IC693MDL65524 VDC 输入、负/正逻辑、1 ms、（32点）IC693MDL632125 VDC 输入（8点）IC693MDL660*24 VDC 输入、负/正逻辑、0.5ms、1.0ms、2.0ms、5ms、10ms、50ms和100ms 过滤（32点）IC693MDL63424 VDC 输入、负/正逻辑（8点）IC693ACC300输入模拟器模块（8点）离散量输出模块IC693MDL310120 VAC 输出、0.5 Amp（12点）IC693MDL74012/24 VDC 输出、0.5 Amp、正逻辑（16点）IC693MDL330120/240 VAC 输出、2 Amp（8点）IC693MDL74112/24 VDC 输出、0.5 Amp、负逻辑（16点）IC693MDL340120 VAC 输出、0.5 Amp（16点）IC693MDL74212/24 VDC 输出、1 Amp、正逻辑（16点）、有保险丝IC693MDL350*120/240 VAC 隔离输出、2 Amp（16点）IC693MDL74848 VDC 输出、0.5 Amps、正逻辑（8点）IC693MDL390120/240 VAC 隔离输出、2 Amp（5点）IC693MDL75012/24 VDC 输出、负逻辑（32点）IC693MDL73012/24 VDC 输出、2 Amp、正逻辑（8点）IC693MDL75112/24 VDC 输出、正逻辑（32点）IC693MDL73112/24 VDC 输出、2 Amp、负逻辑（8点）IC693MDL7525/12/24 VDC （TTL）输出、负逻辑、（32点）IC693MDL73212/24 VDC 输出、0.5 Amp、正逻辑（8点）IC693MDL75312/24 VDC 输出、正逻辑（32点）IC693MDL73312/24 VDC 输出、0.5 Amp、负逻辑（8点）IC693MDL754*12/24 VDC 输出、0.75 amps、具有 ESCP 保护的正逻辑（32点）IC693MDL734125 VDC 输出（6点）中继输出模块IC693MDL930*中继输出、隔离、4 Amp（16点）IC693MAR940中继输出、2 Amp（16点）IC693MDL931中继输出、8 Amp Form B/C 触点、隔离分为 4 个 2 组（8点）混合离散量模块IC693MDR390混合 I/O、24 VDC 输入（8点）、中继输出（8点）IC693MAR590混合 I/O、120 VAC 输入（8 点）、中继输出（8 点）模拟输入模块IC693ALG220模拟输入、电压/电流、4 通道IC693ALG222模拟输入、电压 16 个单一 / 8个不同通道IC693ALG221模拟输入、电流、4 通道IC693ALG223模拟输入、电流、16 个单一通道模拟输出模块IC693ALG390模拟输出、电压、2 通道IC693ALG392高密度模拟输出（8 个通道）IC693ALG391模拟输出、电流、2 通道混合模拟模块IC693ALG442模拟联合模块 4入 / 2出传动模块IC693APU300高速计数器（HSC）IC693DSM302数字伺服控制器 2 轴IC693APU301轴定位模块（APM）、1轴IC693DSM314数字伺服控制器、数字伺服器 1-2 轴或 1-4 轴模拟伺服器IC693APU302轴定位模块（APM）、2轴IC693DSM324数字伺服控制器、数字伺服器4 轴，带与放大器的光纤接口IC693APU305具有格雷码编码器或 QUAD B 编码器输入的高速计数器特殊功能模块IC693MDL760Solenoid Valve 输出（11点）/ 24 VDC 输出、0.5 Amp、负逻辑（5点）IC693PTM101功率变送器模块、CT 和 PT 接口120/240 VAC（1m电缆）IC693PCM301可编程的协处理器模块、192 KB（47 KB Basic 或 C Program）、2个串行端口IC693TCM302温度控制模块（8）TC In 和（8）24 VDC 固态输出IC693PCM311可编程的协处理器模块、 640 KB（640 KB Basic 或C Program）、2个串行端口IC693TCM303温度控制模块扩大温度范围（8）TC In 和（8）24 VDC 固态输出IC693PTM100功率变送器模块、CT 和 PT 接口 120/240 VAC（0.5m电缆）通讯模块IC693BEM331Genius总线控制器（支持 I/O 和 Datagrams）IC693PBM200Profibus DP 主模块IC693CMM302通讯模块、Genius（1 Kbyte）GCM+（不支持Datagram）IC693PBM201Profibus DP 从动模块IC693CMM311通讯模块、CCM、RTU、SNP 和 SNPx 协议IC693DNM200DeviceNet 主模块IC693CMM321以太网接口 TCP / IP 模块、10Mbs（支持SRTP 和 Modbus TCP/IP、无EGD）IC693DNS201DeviceNet 从动模块远程 I/O IC693NIU004以太网网络接口单元。

3．6实用程序3．6．1实用程序的分类在MVS系统中，IBM提供了种类繁多且十分有用的实用程序，来辅助用户对数据进行组织与维护。

实用程序分为三类：系统实用程序、数据集实用程序和独立实用程序。

系统实用程序通常以IEH打头，它的主要功能是维护和管理系统、用户数据集合整个盘卷。

系统实用程序及其功能如下：IEHNITT：为磁带卷写标号。

IEHLIST：系统控制数据信息列表。

IEHMOVE：移动或拷贝若干组数据、移动或拷贝整个卷、移动或拷贝编目目录等。

IEHPROGM：建立及维护系统控制数据、建立时代数据组索引、重命名磁带卷、删除数据集等。

IEHDASDR：初始化一个直接存取卷。

数据集实用程序通常以IEB打头。

它的主要功能是对数据集或数据集纪录进行组织、修改或比较。

它可以作为单个作业来执行，也可以作为某个程序的子程序被调用。

需要注意的是这些数据维护实用程序不能用于VSAM数据集。

以下是数据集实用程序及其功能：IEBCOMPR：比较顺序数据集、分区数据集或扩展分区数据集。

IEBCOPY：拷贝、压缩或合并分区数据集及扩展分区数据集。

IEBDG：创建含有模型数据的测试数据集。

IEBEDIT：有选择的拷贝作业步及其相关的作业语句。

IEBGENER：拷贝顺序数据集记录或将顺序数据集转换为分区数据集。

IEBIMAGE：修改、打印或连接模块。

IEBISAM：卸载、装载、拷贝或打印ISAM数据集。

IEBPTPCH：打印或穿卡输出一个数据集。

IEBUPDATE：对顺序、分区数据集或扩展分区数据机进行合并修改。

独立实用程序通常以IBC开头。

它是一种特殊的实用程序，可独立于操作系统运行，通常被存放在磁带上。

当系统出现重大故障而又无法恢复时，利用系统转储磁带，恢复系统盘卷。

如：IBCDASDI：用于初始化和分配一个直接存取卷上的可用道的实用程序。

IBCDUMPRS：是转储或再存储直接存取卷数据的实用程序。

3．6．2实用程序的调用实用程序的调用方法有两种，一种实在ISPF下用TSO的CALL命令调用，另一种是通过JCL语句调用，在本章中我们只讨论后一种调用方式。

PCI9030与PCI9052资料对比及热插拔功能1、首先在功能方面：PCI9030比PCI9052多了三个功能：支持热插拔、电源管理和支持重要数据VPD配置；但比PCI9052少了一项功能：支持ISA接口。

2、在引脚方面：由于PCI9030与PCI9052在功能上有差别，因此具体表现在以下管脚上：3、由于CPCI卡与主板的连接不再是通过PCI金手指连接，而是通过插针槽连接，在连接器上除了基本的PCI信号外，为了支持多出的功能，相应增加了一些引脚：灰色背景功能引脚暂时用不到!4、由于在功能上PCI9030与PCI9052有了差别，表现在配置空间上也相应有所变化，具体统计如下：9030PCI配置寄存器9030本地配置寄存器EEPROM中需要存储内容EEPROM中主要内容说明本地地址空间0范围寄存器本地地址空间1~3及本地扩展ROM范围寄存器的说明与本地地址空间0范围寄存器的说明类似本地地址空间0的本地基地址（重映射）寄存器本地地址空间1~3及扩展ROM的本地基地址（重映射）寄存器的说明与本地地址空间0的本地基地址（重映射）寄存器类似本地地址空间0总线区域描述符寄存器本地地址空间1~3及扩展ROM总线区域描述符寄存器的说明与本地地址空间0总线区域描述符寄存器的说明类似片选0基地址寄存器片选1~3基地址寄存器的说明与片选0基地址寄存器的说明类似中断控制/状态寄存器PCI目标应答、串行EEPROM、初始化控制寄存器5、热插拔技术概要插拔有三个过程：物理连接过程，包括热插入（在系统运行中插入单板）和热拔出（在系统运行中拔出单板）；硬件连接过程，即系统在硬件层上的连接与断开；软件连接过程，即系统在软件层上的连接与断开。

这些过程可以用一组状态进一步描述，这些状态虽属于系统的不同连接层但彼此关联，如图1所示。

例如，当物理连接层不存在时，硬件连接层就不能产生电气连接；当单板从运行中的系统拔出时，软件连接和硬件连接自动断开。

变电站综合自动化系统软件系列DVPS-3000系统管理生成使用说明书V 4.3北京德威特电力系统自动化有限公司目录第一部分DVPS3000系统管理 (1)第一章概述 (1)1.1系统组成 (1)1.2系统运行环境 (7)第二章历史库管理 (9)2.1数据库压缩整理 (11)2.2数据转储 (11)2.3数据备份 (11)2.4数据库初始化 (12)第三章数据库管理 (14)3.1任务参数定义 (14)3.2网络任务配置 (15)3.3网络任务及通信管理 (15)附录一系统定义库清单 (17)附录二日记录库清单 (22)附录三日转储库清单 (22)附录四月转储库清单 (23)附录五事件记录库清单 (23)第二部分DVPS3000系统生成 (1)第一章概述 (1)1.1基本功能 (1)1.2信息定义指导步骤------新增区域 (2)第二章系统设置 (5)2.1收/发RTU配置 (5)2.2分时电度时段 (9)2.3运行考核时段 (10)2.4功率因数考核指标 (10)第三章信息（对象）定义 (11)3.1厂站结构定义 (11)3.2区域及设备组定义 (13)3.3 测量配置 (14)3.4设备及测量定义 (15)3.5遥控点定义 (16)3.6开关编号定义 (17)3.7统计量及生成量定义 (18)3.8统计分量定义 (19)3.9自定义计算量定义 (20)3.10自动装置定义 (27)3.11信息定义注意事项 (29)第四章信息维护 (30)4.1信息（对象）库查询及打印 (30)4.2信息（对象）属性设置 (30)第五章对象（代码）维护 (37)5.1设备组对象 (37)5.2设备对象 (38)5.3测量对象 (39)5.4接线方式 (41)5.5自动装置对象 (42)第六章网络连接维护 (45)6.1缺省连接设置 (45)6.2自动连接 (47)6.3连接维护 (47)6.4连接生成 (48)第七章防误规则生成及配置 (49)7.1防误规则分类 (49)7.2间隔防误规则定义 (50)7.3防误规则配置 (50)7.4防误规则查询 (52)第八章其它定义 (53)8.1转发信息 (53)8.2上屏信息 (53)8.3实时图形 (54)8.4用户安全管理 (55)第九章系统工具 (57)9.1索引重载 (57)9.2数据库压缩整理或重建实时备份库 (57)9.3域名字典库维护 (58)9.4系统对象录音 (58)9.5测点参数引入 (59)9.6生成实时库初始映像文件 (59)9.7打印输出 (60)第十章常见问题解答 (61)附录一域名表 (62)附录二厂站结构定义单 (63)附录三RTU远动信息定义单 (63)附录四间隔定义单 (64)附录五变压器参数定义单 (65)附录六测量配置单 (66)注：本文档适用于DVPS3000版本4.3第一部分DVPS3000系统管理第一章概述DVPS3000是一个按照面向对象设计方法，贯穿面向对象分析（OOA）、面向对象设计（OOD）及面向对象编程（OOP）全过程的全新的面向电力系统对象设计的电网信息管理系统平台，它包含从数据采集、数据库管理、系统管理到图形界面在内的作为支撑系统的所有功能。

As shipped, the S/390 and zSeries processors provide three methods of initializing the cryptographic adapters with Master Keys. Until the imbedded adapters (CCF’s) or add-on PCIXCC (z990) CEX2C (z890/z990/z9) are initialized, no cryptographic functions can occur. The three provided methods of initialization are:1.Clear Master Key entry via ISPF/ICSF panels.2.Clear Master Key entry via a Trusted Key Entry (TKE) workstation.3.Pass Phrase Initialization (ISPF or batch JCL based)For those that do not have the optional TKE installed, Master Key entry for the first time provides some perplexing nuances.Ideally, a random key value should be chosen and this value should be held until joint custody (key parts) of two or more key administration officers.When Clear Master Key entry via ISPF panels is selected, it quickly becomes apparent that two strategic values are required:1.The actual key part2.It’s associated Check SumNow as mentioned, ideally a random number should be used, but until the cryptographic processors are initialized, they cannot be used to generate random numbers.Classic “Catch-22”.A viable alternative is to generate random numbers at another cryptographic subsystem and use those.What about the Check Sum?Even though the adapters are not initialized, the ISPF panels can still be used to generate the Check Sum for the selected random numbers.So, to make use of this, a functioning system must be available to at least generate random numbers, and if this happens to be your first installation of a cryptographic subsystem, again an apparent “Catch-22”.For this reason, many have chosen to utilize the Pass Phrase Initialization.Let’s look at this option in more detail as well as all of it’s implications.The Pass Phrase process can only be used if no keys have been loaded to the cryptographic adapters (z800/z900), but can be used on a PCIXCC or CEX2C that has been loaded. Typically, this implies at first time startup (z800/z900) after loading the Enablement Diskette and aPower-On-Reset.It can not be used to change an existing Master Key. By CHANGE, this is the process of loading a new Master Key and re-enciphering the existing keys. Replacing an existing Master Key(z890/z990/z9) can be done, but all prior CKDS/PKDS entries are lost.The Pass Phrase process allows only one field entry (no split custody).This implies that the person entering the Pass Phrase is in sole possession of the “Keys to the Kingdom”.And how many of those Kingdoms choose a sample phrase such as “Mary had a little lamb”Or some other all too simple value. Persons name, birth date etc. The person tasked with entering the Pass Phrase should also be aware that should a compromise of keys occur, suspicion may fall onto this sole owner of the Keys.Knowledge of the Pass Phrase and access to the encrypted key data set (CKDS) can allow the person with that knowledge to decipher the key values and completely compromise that system. The Pass Phrase process is content dependent.Upper versus lower case matters. Blanks and punctuation matter. Any variances will result in a different set of Master Keys.Reliance solely on the Pass Phrase process (without exploring other options) and subsequent loss of the Pass Phrase value can result in a complete cryptographic outage during a failure with no possibility of a recovery in the short term.Reliance solely on the Pass Phrase process precludes changing the Master Key at suggested intervals.Moving workload during an outage or disaster recovery requires that the target system be also then initialized with the same Pass Phrase before the cryptographic key data set can be used.If that target system already has a set of Master Keys, this may imply a reload of the Enablement Diskette and a Power-On-Reset (z800/z900).For systems that will never support user keys and have no requirement for secure key processing (as in systems that will only run Web Sphere or SMP/E secure gets), Pass Phrase can be a valid solution, keeping in mind that should processing change to later use secure keys, Pass Phrase may no longer be appropriate.Although the Pass Phrase Initialization is a viable short term means to an end, in the long run it can lead to disaster.Suggestions:Two viable Master Key initialization processes exist for users without a Trusted Key Entry workstation.e the Clear Key Entry Panels to enter a startup key that then allows execution of theRandom Number generator.2.Enter two key parts, all zeroes, Check Sum also zero (z800/z900).ŸUse one of the sample key entry values documented in screen captures from the ICSF Administrators Guide and a key part of all zeroes as above.ŸUse Master Key (SYM-MK) value 0123456789ABCDEF FEDCBA9876543210 with CheckSum 3F and a key part of all zeroes as above.ŸUse PKA Master Key (ASYM-MK) value 0123456789ABCDEF FEDCBA9876543210 0101010101010101 with CheckSum 94 and a key part of all zeroes as above.e the current DES Master Key to Initialize the CKDS.4.Invoke the ISPF Random Number Generator (each Key custodian does this)5.Generate the associated Check Sum6.Enter the Key parts7.Select Change Master Key. This will require a new, empty CKDS8.Update the ICSF parameter file to point to this new CKDS9.Enter production keys as required.10. Generate and enter PKA Master KeysThis technique provides split knowledge of the key parts as well as setting the base process for when the Master Key needs to be changed at its required interval.Secondly, Pass Phrase can be used, but only to replace the entry of a Master Key of zeroes or the above examples.1.Invoke Pass Phrase Initialization2.Invoke the ISPF Random Number Generator (each Key custodian does this)3.Generate the associated Check Sum4.Enter the Key parts5.Select Change Master Key. This will require a new, empty CKDS6.Update the ICSF parameter file to point to this new CKDS7.Enter production keys as required.8.Generate and enter PKA Master KeysAgain, this process sets the basis for later Master Key changes as well as providing split knowledge of the Master Keys.。