085-compressor-performance-test-system

01-300 DOOR INTERLOCK OPEN：前门盖打开。

01-304 L/H INTERLOCK OPEN：L/H盖打开或没关紧。

02-282 EDIT F AD F AIL：1、UI PWB及EDITOR UIPWB检测到PAD CONTROL 板之间无通信。

2、UI PWB检测到UI PWB及EDITOR 板之间无通信，EDIT PAD 不良。

02-310 UI PANEL F AIL：UI 板不良02-340 UI RAM F AIL：UI板上的内存出现异常。

03-285 SYS - EPC COMMUNICATION F AIL：SYS - EPC之间通信发生故障，通信失败。

03-311 IOT-SYS LOGIC F AIL：使用一定时间后，机器检测出IOT-SYS的软件出现逻辑错误。

03-315 IOT-IIT COMMUNICATION F AIL：PRE IPS板和IOT CPU板之间通信不正常或失败。

03-317 UI-IOT COMMUNICATION F AIL：自检系统检测出UI板至IOT板之间无法有效通信。

03-318 IOT-IPS COMMUNICATION F AIL：自检系统检测出IOT板至POST IPS板之间无法有效通信。

03-319 SORTER COMMUNICATION F AIL：分页器出现问题。

03-327 2ND DDI IOSS COMM FAIL：（VSEL EXT. 安装时的缺陷)IOT板检测出IOT板<-->ESS内PRINT板之不同间的通信异常.(PRINT板名称因连接的ESS不同而不同)。

03-328 DDI IOSS I/F FAIL:（VSEL EXT. 安装时的缺陷)IOT板检测出IOT板<-->ESS内PRINT板之不同间的通信异常.(PRINT板名称因连接的ESS不同而不同)。

03-329 DDI IOSS I/F FAIL:（VSEL EXT. 安装时的缺陷)IOT板检测出IOT板<-->ESS内Scan板之不同间的通信异常.(PRINT板名称因连接的ESS不同而不同)。

Release NotesOriginal InstructionsGuardmaster 440C-CR30 Safety Relay, Revision 11Catalog Number 440C-CR30-22BBBSummary of ChangesThis publication contains the following new or updated information. This list includes substantive updates only and is not intended to reflect all changes.About This PublicationThese release notes supplement the existing documentation supplied with your product. Read this document before using Guardmaster® 440C-CR30 safety relays.Firmware Revision HistoryAvailability of Enhancements and Anomaly FixesEnhancements are available in the safety relay only if it is at the required firmware revision or higher and the Connected Components Workbench™ or Studio 5000 Logix Designer® project contains a safety relay that is configured with the required firmware revision or higher. If the project contains a safety relay revision that is lower than the required revision for an enhancement, then the project is still valid but the enhancement will not be available until the project is upgraded to the minimum supported revision.Fixes for firmware anomalies are available as long as the safety relay firmware revision is at the minimum revision or higher. The configured safety relay revision must be of the same major revision.The following tables provide a list of enhancements, known anomalies, and corrected anomalies for the CR30 safety relay firmware revisions.EnhancementsTopicPage Updated Firmware Revision History 1Updated Table 22Updated image in step 23Revision Description6.004First revision release [safety firmware 0A.01]6.006Minor revision release [safety firmware 0A.02]7.006Major revision release [safety firmware 0A.02]8.013Major revision release [safety firmware 0A.02]9.004Major revision release [safety firmware 0A.02]10.004Major revision release [safety firmware 0A.03]10.009Minor revision release [safety firmware 0A.03]10.010Minor revision release [safety firmware 0A.03]10.011Minor revision release [safety firmware 0A.03]Table 1 - EnhancementsEnhancement (1)DescriptionAvailable From Firmware RevisionLock control function support New Lock Control function is now supported forissuing an unlock request to a safety gate withguard locking.10.004Mode selection function support New Mode Selection Safety Monitoring Function is now supported.10.004Mute function enhancements New Muting function block has been enhanced to support a mute enable input, a mute fault manual monitored reset and now offers a secondary output based on the override status.10.004Status function supportNew Status functions for monitoring andannunciating function block faults or ‘waiting for reset’ conditions.10.004Reusable feedback supportNew ability to apply feedback inputs to multiple Safety Output Functions.10.004Single input And withRestartenhancement New ability for the And with Restart logic function to support one input.10.004PanelView Plus Tag browsing support With release 8.00 of FactoryTalk® View Studio, PanelView™ Plus can communicate to CR30 safety relays using EDS parameter browsing over EtherNet/IP™.9.004Nesting of Logic Level Function blocksNew ability to use the output state of a logic block immediately above another logic block as an input condition.9.004Inverting of Logic Level Inputs/Outputs New ability to invert (logical NOT) of inputs and outputs of Logic Level function blocks.9.004Output Loop Safety Monitoring Function support New Output Loop Safety Monitoring Function that allows the logical state of a Safety Output Function to be used as an input condition.9.004RS Flip-Flop Logic Function support New RS Flip-Flop Logic function is now supported in the Logic level columns of the Logic Editor.9.004440C-ENET plug-in supportThe EtherNet/IP plug-in provides both I/O messaging and explicit messaging. The safety relay can now be configured over EtherNet/IP using either Connected Component Workbench or an Add-on Profile (AOP) in Studio 5000 Logix Designer application.8.013Standard Signal Safety Monitoring Function support New Standard Signal Safety Monitoring Function that allows the use of standard control signals from digital plug-ins or communication ports to be used in the logic of the safety relay.8.013Project Upgrade featureProjects developed for earlier versions of firmware can be automatically converted into the latest version of firmware supported.8.0132080-MEMBAK-RTC plug-in support Project backup and restore are supported on CR30 safety relays through the 2080-MEMBAK-RTC module.7.0062080-IQ4 plug-in supportThe 2080-IQ4 digital input plug-in provides 4-pt standard rated 12/24V DC digital input expansion. It can be used in slot 1 and/or slot 2 module bays.7.0062Rockwell Automation Publication 440C-RN001H-EN-P - December 2020Guardmaster 440C-CR30 Safety Relay, Revision 11 Release NotesAnomalies2080-OB4 plug-in support The 2080-OB4 digital output plug-in provides 4-pt standard rated 12/24V DC sourcing output expansion. It can be used in slot 1 and/or slot 2 module bays.7.0062080-OW4I plug-in supportThe 2080-OW4I relay output plug-in provides 4-pt standard rated relay output, individually isolated, 2A expansion. It can be used in slot 1 and/or slot 2 module bays.7.006Unique function block name supportUnique names can be assigned to the Safety Monitoring Function blocks and the Safety Output Function blocks. These names are stored in the project that is loaded to the safety relay and can be recovered by an upload.7.006Password protection Software connections including Upload, Download,and Connect can be restricted through passwordprotection.7.006(1)For more information, see publication 440C-UM001.Table 2 - Known and Corrected AnomaliesAnomalyDescriptionAffected Firmware Revisions Corrected Firmware Revision Discrepancy Fault on Power-upDevices with pulse testing outputs would sometimes cause a discrepancy fault in the CR30 safety relay upon power-up. On power-up, the Channel Test during the first logic scan when transitioning from self-test to run mode has been removed to help prevent the discrepancy fault.See publication 440C-UM001 for details.6.0046.0067.0068.0139.00410.00410.00910.01010.011Memory Module Incompatibility Safety relay fails to recognize 2080-MEMBAK-RTC memory modules that are manufactured on or after 2016/02/11.APBC000280011 6.0046.0067.0068.0139.00410.00410.00910.010Memory Module Update When updating a safety relay from a previous firmware revision to firmware 10 using thememory module the restore operation must be performed twice (the first process updates thefirmware, the second process restores the user configuration). 6.004 6.0067.0068.0139.004Configuration loss on power cycleDuring specific power down conditions, the safety relay could be interrupted while writing a fault condition to its nonvolatile memory. On power up, the memory is evaluated as corrupted and the user configuration is discarded.APBC00026898 6.0046.0067.0068.0139.00410.00410.009Connection failure with Add-on Profile (AOP) major revision 1The safety relay rejects an I/O connection that originates from the safety relay AOP (versions 1.013 and versions 1.014) when Compatible Keying and Major Revision 8 or later is configured.APBC000271569.00410.004Download faultA download could result in a major fault on the safety relay, Type 06, Code 20 – Configuration Fault.APBC000251087.0068.0139.00410.004Download over Ethernet faultA download over Ethernet to the safety relay could result in a Type 05, Code 00 – Internal Safety Synch Fault.APBC000236608.0139.00410.004Unexpected disconnect from safety relay Occasionally Connected ComponentsWorkbench software would unexpectedly disconnect while connected to a password protected safety relay.APBC000248668.0139.004Table 1 - Enhancements (Continued)Enhancement (1)DescriptionAvailable From Firmware RevisionLocked by another connection error Attempts to connect to the safety relay arerejected and erroneously reports “CR30 has been locked by another, new connection is not allowed.”APBC000248678.0139.004No reconfiguration after EEPROM fault After the safety relay experiences a memory fault (Type 5 Code 00), the safety relay does not accept a new download.APBC00024866 6.0046.0067.0068.0139.004Muting L-Type reports incorrect fault description Under specific configuration conditions, the Muting T Type function block incorrectly reports a mute sensor timing fault when actually a sequence fault occurred.APBC000237318.0139.004Network address changes require power cycle Changes to the 440C-ENET Ethernet portsettings, duplicate IP address detection, and DHCP vs. static IP address settings may require a power cycle to take effect.APBC000241338.0139.004Power-up faultVariations in 24V DC supply power to the CR30 safety relay during power-up could lead to power fault: Type 04, Code 01.APBC000244266.0046.0067.0068.013Discrepancy fault after power-upVariations in 24V DC supply power to the CR30 safety relay during power-up could lead to adiscrepancy fault on any dual channel Safety Monitoring Function: “One channel open after reset” 6.0046.0067.0068.013Empty fault logModbus reporting of the fault log always returns 0, indicating no fault, even if faults are present in the log.APBC00025011 6.0046.0067.0068.013Incorrect Mode The safety relay will return to Run Mode after downloading a valid configuration to a unit that has experienced a nonrecoverable fault.APBC000257716.0046.0067.0068.013Modbus fault state cleared in Program Mode The safety relay does not report faultinformation over Modbus once the safety relay is placed in Program Mode.6.0046.0067.0068.013Memory module firmware update failure The memory module is unable to upgrade a firmware revision 7 safety relay to version 8 or later 7.006L-Type muting override conditionOverride for L-Type muting cannot be initiated when only the light curtain is interrupted (no mute sensors).6.0046.0067.006Two Hand Control at power up Two Hand Control does not fault at power up if buttons are pressed. 6.0046.0067.006Override conditionsFor muting applications, mute sensor interrupted or timing faults should be only conditions that allow override to be initiated.6.0046.0067.006Serial port doesnot shutdownWhen the serial port is configured as shutdown,it still responds to Modbus messages.APBC00020590 6.0046.0067.006Input filters greater than 200 ms create nonrecoverable fault When an input filter of greater than 200 ms is configured on any Safety Monitoring function, a nonrecoverable fault is generated when the configuration is downloaded to the safety relay.APBC00020589 6.0046.0067.006Missing plug-in slot 1 without fault log entry A missing plug-in module configured in slot 1 and not actually present results in a fault but no fault log entry is created.APBC00018493 6.0046.0067.006Plug-inmismatch with duplicate fault log entriesA mismatch between the plug-in present on slot 1 and the actual plug-in present results in duplicate entries in the fault log.APBC000205086.0046.0067.006Plug-in outputs fail to configure When Plug-in outputs terminals are selected asoutputs for Safety Output Functions, they fail toturn on when the corresponding Safety OutputFunction turns on.APBC000201036.004 6.006Table 2 - Known and Corrected Anomalies (Continued)AnomalyDescriptionAffected Firmware Revisions Corrected Firmware RevisionRockwell Automation Publication 440C-RN001H-EN-P - December 20203Guardmaster 440C-CR30 Safety Relay, Revision 11 Release NotesUse DMK FilesFirmware for the CR30 safety relay beginning with firmware revision 10.009 uses a new file format called *.DMK. These files are named for easy identification, for example: 440C-CR30-22BBB_10.009.dmk.ControlFLASH™ software, version 13 or later, supports the format. ControlFLASH software is automatically installed as part of Studio 5000 Logix Designer application installation, version 28 or later. You can download ControlFLASH software from the Rockwell Automation Product Compatibility and Download Center (PCDC - rok.auto/pcdc ) separately, if necessary.You are not required to install the new firmware file format. When you download *.DMK files from the Rockwell Automation PCDC, ControlFLASH softwareautomatically saves the folder location where the *.DMK files were downloaded. As a result, ControlFLASH software can easily locate *.DMK files.You can use the Browse option to access and configure the folders that ControlFLASH software monitors as shown:Upgrade Safety Relay FirmwareThis procedure shows you how to update the firmware in a CR30 safety relay using ControlFLASH. To download the latest CR30 safety relay firmware revision, go to the PCDC (PCDC - rok.auto/pcdc ) and select your desired revision.On CR30 safety relays, you can upgrade your safety relays through the Ethernet port on the 440C-ENET plug-in module and the USB.Through USB1.Verify successful RSLinx® Classic communications with you CR30 safety relay by USB using RSWho. The CR30 safety relay uses the AB_VBP-x driver.2.Start ControlFLASH (Start > All Programs > FLASH Programming Tools > ControlFlash) and click Next >.3.Select the catalog number of the CR30 safety relay (440C-CR30-22BBB) that you are updating and click Next >.4.Select the safety relay in the browse window and click OK.Communication fault without fault log entryIf the host microprocessor within the CR30safety relay loses communication with the safety processors a fault is generated but no fault log entry is createdAPBC00020302 6.0046.006Fault log index changes after power cycleAfter a power cycle of the safety relay,previously detected faults index by one within the fault log.APBC000186376.004 6.006Inverted image of downloadprogram notcompared After performing a download, the inverted datais sent back from the safety relay to Connected Components Workbench software but not compared as an additional diagnostic check.APBC00020430 6.004 6.006Download through virtual image failsDownload of a program to the safety relay occasionally fails due to connection timeout when downloading through a virtual image.6.004 6.006ATTENTION: All Ethernet settings are reverted to factory default after a ControlFLASH firmware update.Table 2 - Known and Corrected Anomalies (Continued)AnomalyDescriptionAffected Firmware Revisions Corrected Firmware Revision IMPORTANTTo update your safety relay successfully, it must be in Program Mode or BOOT Loader mode. The safety relay can be placed into Program Mode from the Graphic Overview screen in Connected Component Workbench software, the Logic Configuration tab in the Logix Designer module profile or placed in BOOT Loader mode by holding the MEM/ID button located below the USB port on the safety relay during power-up.Publication 440C-RN001H-EN-P - December 2020 | Supersedes Publication 440C-RN001G-EN-P - April 2016Copyright © 2020 Rockwell Automation, Inc. All rights reserved. Printed in the U.S.A.Rockwell Otomasyon Ticaret A.Ş. Kar Plaza İş Merkezi E Blok Kat:6 34752 İçerenköy, İstanbul, Tel: +90 (216) 5698400 EEE Yönetmeliğine UygundurAllen-Bradley, Connected Components Workbench, ControlFLASH, expanding human possibility, FactoryTalk, Guardmaster, PanelView,Rockwell Automation, RSLinx, and Studio 5000 Logix Designer are trademarks of Rockwell Automation, Inc.EtherNet/IP is a trademark of ODVA, Inc.Trademarks not belonging to Rockwell Automation are property of their respective companies.Your comments help us serve your documentation needs better. If you have any suggestions on how to improve our content, complete the form at rok.auto/docfeedback .For technical support, visit rok.auto/support.Waste Electrical and Electronic Equipment (WEEE)Rockwell Automation maintains current product environmental compliance information on its website at rok.auto/pec .At the end of life, this equipment should be collected separately from any unsorted municipal waste.5.Verify the revision, and click Next > to continue.6.Click Finish.7.Click Yes to initiate the update.The next screen shows the download progress.If you see the following error message, verify that the safety relay is in Run mode. If so, change to Program or BOOT Loader mode by pressing theMEM/ID switch during power-up of the CR30 safety relay, click OK, and try again.When the update is complete, you see a screen similar to the following.Click OK to complete the update.。

大管轮面试问题及参考答案大管轮是轮机部非常重要的管理人员，因此船东对大管轮的面试和挑选非常重视。

大管轮的面试一船集中在日常部门管理能力和轮机长的配合能力、服从意识，以及关于主、辅机、舵机以及甲板机械等机器设备的管理和保养等方面。

同时，还要大管轮了解《国际安全管理规则》(ISM)的相关知识。

1. What are the responsibilities of the First Engineer on board a ship?The First Engineer is under the leadership of the Chief Engineer. He is responsible for the following.(1) Day-to-day running of the Engine room.(2) Management of the Engine department personnel.(3) Safety matters in the Engine room.(4) All maintenance and repair jobs on board ship(5) The main engine and its auxiliary equipment, steering gears, emergency equipments in engine room, etc.(6) Making and implementing the PMS (Planned Maintenance System)(7) Requisition for, receipt and control of spare parts and stores(8) Supervision of the jobs of engine crew.(9) Keeping watch from 0400 to 0800 and from 1600 to 2000 except for UMS operation.2. What is your emergency position on the Muster List on your last vessel?I control and operate the main engine except for the abandon-ship and fire in engine room emergency situations.3. Can you describe an emergency situation you ever encountered on board ships?No, I have never met any emergency situation before now.4. Which machineries and space parts should be under your charge?I should be responsible for the main engine, the service pumps for main engine, steering gear, accommodation air condition, provision of refrigerator and the emergency equipments. I should also prepare maintenance reports, fuel oil and lubrication oil samples analysis, inventory report of spare parts, store and spare parts requisitions, etc.5. Describe the procedure to start a fresh water generator, boiler, emergency generator?In case of fresh water generator:(1) Check the valves to make sure that they are in the normal position(2) Open the sea water valves of condenser and supply sea water to heating chamber(3) Start the sea water ejector pump to draw out the vacuum until the heating chamber vacuum reaches 93% (about 700 mmHg)(4) Open the water heating valves and keep the heating chamber temperature around 45 degrees Centigrade(5) When the condensed water reaches a certain level, start the distilled water pump, and keep its pressure no less than 0.2MPa.(6) Start chemical liquid feed pump.In case of automatic boiler:(1) Check the water level to make sure there is normal volume of water inside(2) Open the vent valve on top of the boiler (if it is first time to raise pressure from cold condition)(3) Confirm the boiler water supply pumps are in “Auto” condition(4) Switch on the power supply(5) Put the boiler control switch in “Auto” condition(6) Automatically start the boiler, close the air vent valve while the boiler steam pressure reaches 0.02 MPa.(7) Confirm the boiler can auto stop while it pressure reaches “high limit” (e.g. 0.7MPa)In case of manual boiler(1) Check the water level to make sure there is normal volume of water inside and put the feed water pump in “Auto” position(2) Open the vent valve on top of the boiler (if it is first time raise pressure from cold condition)(3) Put the draft fan in “Manual” position, and make preventive blow to avoid any possible explosion(4) Put the fuel oil pump in “Manual” position(5) Ignite fire by pressing the manual button, if the fire “On”, put valve(6) When the steam pressure reaches to 0.1MPa, close the air vent valve(7) After making sure that everything is in order, the normal burning can be done to make the steam pressure reach required levelIn case of emergency generator(1) Check the lube oil level in the crankcase and fuel oil level in the tank all in normal level(2) Check to see if there is any leakage(3) Check the air pressure if the generator is the air-started model; or check the battery voltage to see whether it is normal if the generator is of the battery start model(4) Also make sure there aren’t any obstacles around the machine.(5) Put the test switch in “Manual” position, and manually start it after maki ng sure that above-mentioned items in order(6) If you use “Auto test” model, or “Black out” model to test the emergency generator, you must inform bridge duty officer and Chief Engineer. And you cannot carry it until you get the permit from both of them. Otherwise, you must wait(7) “Auto test” must be carried out once every month. “Blackout” test must be carried out once every 3 months6. When the main engine cannot started by the compressed air, what are the possible causes? There may be the following causes(1) Air pressure is too low(2) The turning gear is still engaged(3) There may be operational fault(4) Some of the high injection pumps are sticked(5) No fuel oil due to the fact that the fuel valve is not open or the fuel pump is not running(6) Relative locked due to some safety device actions(7) Air distributor timing has been wrongEtc.7. When main engine stops after running a while, what are the possible causes?The following reasons may lead to the problem:(1) Some of the high injection pumps are sticked(2) There is no fuel oil because valve is not open or the fuel pump is not running(3) Lube oil pressure is too low, or control air pressure is too low8. What is the purpose of taking lube oil samples for analysis?By analyzing the lube oil sample, we want to know whether the lube oil meets the stipulated standards in viscosity, TBN (total base number), flash point, water contents, mechanic impurities etc.. If impurities (i.e. metals) are found, it means something wrong with the bearing and crankshaft. If the viscosity is lower than the standard, it may mean that fuel oil may have leaked into the lube oil system. Too much fuel oil in the lube oil system can lower the flash point of the lube and also may lead to possible explosion. The important figure is TBN. If the TBN is lower than the standard, itmeans the loss of the anti-acid ability and this will lead to the moving parts corrosive in the near future.9. What are the things you need to take note during the handover (before you sign off)?The outgoing First Engineer shall prepare a set of handover notes for the incoming First Engineer and shall ask the incoming First Engineer be familiar with the note contents. One copy of the handover notes with their signatures shall be given to the Chief Engineer for file. In general the handover procedure shall include the following(1) A tour of the engine room, with view of the engines, documents and equipments(2) Discussion on current and future engine and machine’s operation problems, spare part requirement(3) Information on the maintenance work and program(4) Dry dock repair list, if there if any(5) Discussion on the junior engineers or crew’s capacity and personalities(6) Survey status and requirements(7) Store and status of the ship’s safety equipment and machines(8) Current status of the ship’s safety equipments and machines(9) Safety and environment protection procedures and any special requirement by the company and in some areas in the world(10) Disciplinary procedures and management practice in the Engine department(11) Any other matters that the outgoing First Engineer thinks necessary and importantAfter the handover, the two First Engineers should sign all the Handover Checklist as evidence and for files.大管轮也是船上特别是轮机部非常重要的职位，所以交接班非常重要。

3-TERMINAL POSITIVE VOLTAGE REGULATOR LM7805 TO-220Plastic PackageThe Voltages Available allow these Regulators to be used in Logic Systems, Instrumentation, Hi-Fi Audio Circuits and other Solid State Electronic Equipment ABSOLUTE MAXIMUM RATINGS UNIT V W W ºC ºC ºCELECTRICAL CHARACTERISTICS (T j =25ºC unless specified otherwise)VI =10V, I O =500mA DESCRIPTION SYMBOLMINTYPMAXUNIT Output VoltageV OT j =25ºC4.805.20V I O =5mA ~ 1AV I =7V ~ 20V, P< 15W Line Regulation R EGV V I =7.0 ~ 25V T j =25ºC 100mV V I =8.0 ~ 12V50mV Ripple Rejection R R V I =8.0 ~ 18V, f=120HzT j =0 ~ 125ºC 62dB Load RegulationR EGL I O =5mA ~ 1.5A T j =25ºC100mV I O =250mA ~ 750mA50mV Output Resistance R O f=1KHz T j =0 ~ 125ºC 0.017ΩOutput Voltage Drift ∆V O /∆T I O =5mA T j =0 ~ 125ºC - 1.1mV/ºC Output Noise Voltage V NO f=10Hz ~ 100KHzT j =25ºC40µV Dropout Voltage V d I O =1AT j =25ºC 2.0V Quiescent CurrentI Q T j =25ºC8.0mA Quiescent Current Change ∆I Q V I =7.0 ~ 25V T j =0 ~ 125ºC 1.3mA I O =5mA ~ 1A0.5mA Short Circuit Output Current I SC T j =25ºC 750mA Peak Output CurrentI PKT j =25ºC2.2ATEST CONDITIONV T j =0 ~ 125ºC4.755.25Storage Temperature RangeT stg - 65 to +150Lead Temperature 1.6mm (1/16 inch) from Case for 10 seconds T L260Continuous Total Dissipation at T c =25ºC case TemperatureP D 15Operating free-air, case, or Virtual Junction Temperature Range T OPR 0 to 150DESCRIPTION SYMBOL VALUE Input VoltageV IN 35Continuous Total Dissipation at T a =25ºC free air TemperatureP D2.0Continental Device India LimitedAn ISO/TS 16949, ISO 9001 and ISO 14001 Certified CompanyTO-220Leaded PlasticPackageMRegulatorsPin 1: In Pin 2: Ground Pin 3: OutPackaging dimensions, tube dimensions and quantity/tube are approximate and subject to change.TO-220 Series Packaging TubeLM7805 TO-220Plastic PackageCustomer Notes LM7805TO-220Plastic PackageDisclaimerThe product information and the selection guides facilitate selection of the CDIL's Semiconductor Device(s)best suited for application in your product(s)as per your requirement.It is recommended that you completely review our Data Sheet(s)so as to confirm that the Device(s)meet functionality parameters for your application.The information furnished in the Data Sheet and on the CDIL Web Site/CD are believed to be accurate and reliable.CDIL however,does not assume responsibility for inaccuracies or incomplete information.Furthermore,CDIL does not assume liability whatsoever,arising out of the application or use of any CDIL product;neither does it convey any license under its patent rights nor rights of others.These products are not designed for use in life saving/support appliances or systems.CDIL customers selling these products(either as individual Semiconductor Devices or incorporated in their end products),in any life saving/support appliances or systems or applications do so at their own risk and CDIL will not be responsible for any damages resulting from such sale(s).CDIL strives for continuous improvement and reserves the right to change the specifications of its products without prior notice.CDIL is a registered Trademark ofContinental Device India LimitedC-120 Naraina Industrial Area, New Delhi 110 028, India.Telephone + 91-11-2579 6150, 4141 1112 Fax + 91-11-2579 5290, 4141 1119*****************。

Bulletin 280/281ArmorStart™ Distributed Motor ControllerSpecificationsElectrical Ratings UL/Nema IEC Power Circuit Rated Operation Voltage200V...480Y/277V200 (500V)Rate Insulation Voltage600V600 VRated Impulsed Voltage 6 kV 6 kVDielectric Withstand2200V AC2500V ACOperating Frequency50/60 Hz50/60 HzUtilization Category N/A AC-3Protection Against Shock N/A IP2XRated Operating Current Max.2.5 A 5.5 A 16 AShort Circuit ProtectionSCPD performance Type 2 0.5…2.5 A range 65 kA@480Y/277V 0.5…2.5 A range 65 kA1.1…5.5 A range 65 kA@480Y/277V 1.1…5.5 A range 65 kA 3.2…16 A range 25 kA@480Y/277V 3.2…16 A range 25 kASCPD List Size per NEC Group Motor—Control CircuitRated Operation Voltage 24V DC A2 (should be grounded at voltage source) 120V AC A2 (should be grounded at voltage source) 240V AC A2 (should be grounded at voltage source)Rate Insulation Voltage250V 250VRated Impulsed Voltage— 4 kVDielectric Withstand1500V AC2000V ACOvervoltage Category—IIIOperating Frequency50/60 HzPower Requirements24V DC Status Only 77 W pickup 1 W holding24V DC HOA/HOA Reversing 87 W pickup 11 W holding120V/240V AC Status Only70 VA Pickup 9 VA Holding120V/240V AC HOA/HOA Reversing80 VA Pickup 19 VA HoldingInput Ratings Rated Operation Voltage24V DCInput On-State Voltage Range10…26V DCInput On-state Current 3.0 mA @ 10V DC 7.2 mA @ 24V DCInput Off-state Voltage Range0…5V DCInput Off-state Current<1.5 mAInput Filter — Software SelectableOff to On Settable from 0…64 ms in 1 ms incrementsOn to Off Settable from 0…64 ms in 1 ms incrementsInput Compatibility N/A IEC 1+Number of inputs4Sensor SourceVoltage Status Only11…25V DC from DeviceNetVoltage with HOA or HOA reversing24V DC ±15% from Control VoltageCurrent Available50 mA MAX per Input, 200 mA TotalOutput Ratings Rated Operation Voltage240V AC / 30V DC240V AC / 30V DCRate Insulation Voltage250V250VDielectric Withstand1500V AC2000V ACOperating Frequency50/60 Hz50/60 HzType of control circuit Electromechanical RelayKind of Current AC/DCConventional Thermal Current I th Total of both outputs ≤ 2 AType of Contacts Normally Open (N.O.)Number of Contacts2Bulletin 280/281ArmorStart™ Distributed Motor ControllerSpecifications, ContinuedEnvironmental Operating Temperature Range0…40°C (32…104°F)Storage and Transportationtemperature range–25….85°C (–13…185°F)Altitude2000 mHumidity5…95% (non-condensing)Pollution Degree3Mechanical Resistance to ShockOperational 5GNon-Operational 10GResistance to VibrationOperational 5GNon-Operational 10GControl Power Terminal Cable Size#22 AWG…#10 AWG0.5 mm2…6 mm2Tightening Torque 5.6…6.8 lb-in0.7 N·mLine Power Terminal cable size#22 AWG…#10 AWG0.5 mm2…6 mm2Tightening Torque 5.6…6.8 lb-in0.7 N·mGround Terminal cable size#22 AWG…#10 AWG0.5 mm2…6 mm2Tightening Torque 5.6…6.8 lb-in0.7 N·mEnclosure Ratings NEMA 4/12IP67Other Rating EMC Emission levelsConducted Radio Frequency Emissions Class ARadiated Emissions Class AEMC immunity levelsElectrostatic Discharge 4 kV contact and 8 kV AirRadio Frequency Electromagnetic Field10 V/mFast Transient 2 kVSurge Transient 1 kV (12) L-L, 2 kV (2) L-N (Earth)Overload CharacteristicsOverload Current Range 0.5…2.5 A1.1…5.5 A 3.2…16 AT rip Classes10, 15, 20Trip Rating 120% of FLC setting Number of poles3DeviceNet SpecificationsDeviceNet Supply Voltage Rating Range 11…25V DC, 24V DC NominalDeviceNet Input Current 125 mA plus total of Input currents 325 mA Max at 24V DC Status Only 125 mA at 24V DCHOA/HOA ReversingDeviceNet Input Current Surge15 A for 250 µsDeviceNet CommunicationsBaud Rates125, 250, 500 kbpsDistance Maximum 500 m (1630 ft) @ 125 kbps 200 m (656 ft) @ 250 kbps 100 m (328 ft) @ 500 kbpsApprovalscULus (File No. 3125)UL 508EEN/IEC 60947-4-1CE Marked per Low Voltage Directive 73/23/EEC and EMC Directive 89/336/EEC。

JBL Incorporated, 8500 Balboa Boulevard, P .O.Box 2200, Northridge, California 91329 U.S.A.J B L M R X 525 R E V HPACKAGE WIRING DIAGRAM03-12T echnical ManualJBL MRX525SPECIFICATIONSACOUSTIC & ELECTRICAL SPECIFICATIONS:•Nominal Impedance: 4 Ohms •Power Capacity:800W / 1600W / 3200W, 2 hrs.(Cont/ Prog/Peak):700W / 1400W / 2800W, 100 hrs • Frequency Range:40 Hz - 20 kHz (-10 dB)•Frequency Response:57 Hz – 20 kHz (±3 dB) •Maximum SPL:129 dB SPL continuous (135 dB SPL peak)•System Sensitivity:100 dB SPL (1 watt @ 1 meter)•Crossover Frequency:1.8 kHzSYSTEM COMPONENTS:•Cabinet:Enclosure (Not for Sale)•Grille:362524-001•Low Frequency 265H-1, 380 mm (15 in) Differential Transducer:Drive woofer •DC Resistance: 5.0 ohm ±10%•High Frequency 2408H, 37.5 mm (1.5 in) annularTransducer:polymer diaphragm, neodymium compression driver•DC Resistance:4.8 ohm +/- 0.2 ohmSYSTEM COMPONENTS:(CONT’D) • Crossover Network:364969-001AURAL SWEEP TEST SPECIFICATIONS:A.System Aural Sweep T est:7.0V Input, 50 Hz to 20 kHzB.L.F .Aural Sweep Test:7.0V Input, 10 Hz to 300 HzC.H.F .Aural Sweep Test:0.75V Input, 200 Hz to 1.5 kHz PHYSICAL SPECIFICATIONS:•Enclosure Dimensions:1240 x 535 x 460 mm D (H x W x D)(48.75 x 21.0 x 18.0 in D)•Net Weight (ea):84.0 lb (38.2 kg)WARRANTY INFORMATION:•Refer to Warranty Statement packed with each product.Warranty 59660Manual362053-001Carton362293-001Fillers (2)362294-002Pkg, Microfoam (8) 49790PPop Sticker 362896-001NETWORK SCHEMATIC - (364969-001)Driver, High Freq 2408H(361549-001X) Driver Repl D8R2408Driver,Low Freq (2)265H(362048-001X)Cone Repl C8R265 265H-1 (2)(363837-003X)Cone Repl C8R265-1Network Assembly 364969-001YEL YEL/BLKGRN GRN/BLKWH/BLK WH NOTE:INDIVIDUAL PARTS FOR THE ABOVE CROSSOVER ARE NOT AVAILABLE.A COMPLETE REPLACEMENT ASSEMBL Y SHOULD BE ORDERED.JBL MRX525804-11110-1610-32 x 1, FLT, PH,BLK OXIDE, LCSNetwork, Input364969-001Screw (6)882-41110-106 x 5/8, PAN, PH,BLK ZINC, LCSNameplate 362051-001Grille Assembly w/ Screen362524-001 Screw (26)882-51110-12Foot (4)353445-001Screw (4)884-41110-1210 x 3/4, PAN, PH,PB, BLK ZINC, LCSDriver, Low Freq (2)265H(362048-001X)Cone ReplC8R265265H-1(363837-003X)Cone ReplC8R265-1Network, Input362292-001Screw (2)882-41110-106 x 5/8, PAN, PH,BLK ZINC, LCS。

Engine resetsThis section contains information about cold reset, NVRAM initialization, hard diskinitialization, calibration bypass, and calibrating the printer.Cold resetA cold reset unlocks menus that have been locked and resets variables in the control panel.However, it does not clear the values in the Service menu (such as the serial number andpage counts).To perform a cold reset1.Turn the printer on.2.As the printer performs its power-on sequence, press and hold until all three lights onthe control panel are lit.3.When Select A Language appears on the display, press until COLD RESET appearson the display.4.Press . The printer will perform a cold reset and then continue its power-on sequence.NVRAM initializationCAUTION Initializing NVRAM will reset the serial number, the event log, the page counts, thecalibration settings, and the EIO card. Use the Service menu to restore the serial numberand page counts. You will also need to reconfigure any computers that print to this printer torecognize the printer. Initialize NVRAM only when absolutely necessary. In most situations,use a Cold reset to reset printer variables but still retain the needed values in the Servicemenu.Before initializing NVRAM, print a configuration page and a supplies status page to gatherthe following information:●Total page count and color page count●Transfer kit count●Fuser kit count●Serial numberTo initialize NVRAM1.Turn the printer on and watch the control panel display.2.When the display begins showing the memory count, press and hold until all threelights on the control panel are lit.3.Press .4.Press P AUSE/R ESUME for the HP Color LaserJet 5500 or press S TOP for the HP ColorLaserJet 5550. The display should show SKIP DISK LOAD.5.Press until NVRAM INIT is highlighted.6.Press . The printer will initialize NVRAM and then continue its power-on sequence.416Chapter7 Troubleshooting ENWW。

3GPP TS 36.521-1 V14.4.0 (2017-09)Technical Specification3rd Generation Partnership Project; Technical Specification Group Radio Access Network; Evolved Universal Terrestrial Radio Access (E-UTRA);User Equipment (UE) conformance specification;Radio transmission and reception;Part 1: Conformance Testing(Release 14)The present document has been developed within the 3rd Generation Partnership Project (3GPP TM) and may be further elaborated for the purposes of 3GPP.KeywordsUMTS LTE3GPPPostal address3GPP support office address650 Route des Lucioles - Sophia AntipolisValbonne - FRANCETel.: +33 4 92 94 42 00 Fax: +33 4 93 65 47 16InternetCopyright NotificationNo part may be reproduced except as authorized by written permission.The copyright and the foregoing restriction extend to reproduction in all media.© 2017, 3GPP Organizational Partners (ARIB, ATIS, CCSA, ETSI, TSDSI, TTA, TTC).All rights reserved.UMTS™ is a Trade Mark of ETSI registered for the benefit of its members3GPP™ is a Trade Mark of ETSI registered for the benefit of its Members and of the 3GPP Organizational Partners LTE™ is a Trade Mark of ETSI registered for the benefit of its Members a nd of the 3GPP Organizational Partners GSM® and the GSM logo are registered and owned by the GSM AssociationContentsForeword (92)Introduction (92)1Scope (93)2References (94)3Definitions, symbols and abbreviations (96)3.1Definitions (96)3.2Symbols (98)3.3Abbreviations (100)4General (103)4.1Categorization of test requirements in CA, UL-MIMO, ProSe, Dual Connectivity, UE category 0, UEcategory M1, UE category 1bis, UE category NB1 and V2X Communication (104)4.2RF requirements in later releases (105)5Frequency bands and channel arrangement (106)5.1General (106)5.2Operating bands (106)5.2A Operating bands for CA (108)5.2B Operating bands for UL-MIMO (116)5.2C Operating bands for Dual Connectivity (116)5.2D Operating bands for ProSe (117)5.2E Operating bands for UE category 0 and UE category M1 (118)5.2F Operating bands for UE category NB1 (118)5.2G Operating bands for V2X Communication (118)5.3TX–RX frequency separation (119)5.3A TX–RX frequency separation for CA (120)5.4Channel arrangement (120)5.4.1Channel spacing (120)5.4.1A Channel spacing for CA (121)5.4.1F Channel spacing for UE category NB1 (121)5.4.2Channel bandwidth (121)5.4.2.1Channel bandwidths per operating band (122)5.4.2A Channel bandwidth for CA (124)5.4.2A.1Channel bandwidths per operating band for CA (126)5.4.2B Channel bandwidth for UL-MIMO (171)5.4.2B.1Channel bandwidths per operating band for UL- MIMO (171)5.4.2C Channel bandwidth for Dual Connectivity (171)5.4.2D Channel bandwidth for ProSe (171)5.4.2D.1Channel bandwidths per operating band for ProSe (171)5.4.2F Channel bandwidth for category NB1 (172)5.4.2G Channel bandwidth for V2X Communication (173)5.4.2G.1Channel bandwidths per operating band for V2X Communication (173)5.4.3Channel raster (174)5.4.3A Channel raster for CA (175)5.4.3F Channel raster for UE category NB1 (175)5.4.4Carrier frequency and EARFCN (175)5.4.4F Carrier frequency and EARFCN for category NB1 (177)6Transmitter Characteristics (179)6.1General (179)6.2Transmit power (180)6.2.1Void (180)6.2.2UE Maximum Output Power (180)6.2.2.1Test purpose (180)6.2.2.4Test description (182)6.2.2.4.1Initial condition (182)6.2.2.4.2Test procedure (183)6.2.2.4.3Message contents (183)6.2.2.5Test requirements (183)6.2.2_1Maximum Output Power for HPUE (185)6.2.2_1.1Test purpose (185)6.2.2_1.2Test applicability (185)6.2.2_1.3Minimum conformance requirements (185)6.2.2_1.4Test description (185)6.2.2_1.5Test requirements (186)6.2.2A UE Maximum Output Power for CA (187)6.2.2A.0Minimum conformance requirements (187)6.2.2A.1UE Maximum Output Power for CA (intra-band contiguous DL CA and UL CA) (189)6.2.2A.1.1Test purpose (189)6.2.2A.1.2Test applicability (189)6.2.2A.1.3Minimum conformance requirements (189)6.2.2A.1.4Test description (189)6.2.2A.1.5Test Requirements (191)6.2.2A.2UE Maximum Output Power for CA (inter-band DL CA and UL CA) (192)6.2.2A.2.1Test purpose (192)6.2.2A.2.2Test applicability (192)6.2.2A.2.3Minimum conformance requirements (192)6.2.2A.2.4Test description (192)6.2.2A.2.5Test Requirements (194)6.2.2A.3UE Maximum Output Power for CA (intra-band non-contiguous DL CA and UL CA) (196)6.2.2A.4.1UE Maximum Output Power for CA (intra-band contiguous 3DL CA and 3UL CA) (196)6.2.2A.4.1.1Test purpose (196)6.2.2A.4.1.2Test applicability (196)6.2.2A.4.1.3Minimum conformance requirements (196)6.2.2A.4.1.4Test description (196)6.2.2A.4.1.5Test Requirements (198)6.2.2A.4.2UE Maximum Output Power for CA (inter-band 3DL CA and 3UL CA) (198)6.2.2A.4.2.1Test purpose (199)6.2.2A.4.2.2Test applicability (199)6.2.2A.4.2.3Minimum conformance requirements (199)6.2.2A.4.2.4Test description (199)6.2.2A.4.2.5Test Requirements (201)6.2.2B UE Maximum Output Power for UL-MIMO (201)6.2.2B.1Test purpose (201)6.2.2B.2Test applicability (202)6.2.2B.3Minimum conformance requirements (202)6.2.2B.4Test description (204)6.2.2B.4.1Initial condition (204)6.2.2B.4.2Test procedure (205)6.2.2B.4.3Message contents (205)6.2.2B.5Test requirements (205)6.2.2B_1HPUE Maximum Output Power for UL-MIMO (207)6.2.2B_1.1Test purpose (207)6.2.2B_1.2Test applicability (207)6.2.2B_1.3Minimum conformance requirements (207)6.2.2B_1.4Test description (207)6.2.2B_1.5Test requirements (208)6.2.2C 2096.2.2D UE Maximum Output Power for ProSe (209)6.2.2D.0Minimum conformance requirements (209)6.2.2D.1UE Maximum Output Power for ProSe Discovery (209)6.2.2D.1.1Test purpose (209)6.2.2D.1.2Test applicability (209)6.2.2D.1.3Minimum Conformance requirements (209)6.2.2D.2UE Maximum Output Power for ProSe Direct Communication (211)6.2.2D.2.1Test purpose (211)6.2.2D.2.2Test applicability (211)6.2.2D.2.3Minimum conformance requirements (211)6.2.2D.2.4Test description (211)6.2.2E UE Maximum Output Power for UE category 0 (212)6.2.2E.1Test purpose (212)6.2.2E.2Test applicability (212)6.2.2E.3Minimum conformance requirements (212)6.2.2E.4Test description (212)6.2.2E.4.3Message contents (213)6.2.2E.5Test requirements (213)6.2.2EA UE Maximum Output Power for UE category M1 (215)6.2.2EA.1Test purpose (215)6.2.2EA.2Test applicability (215)6.2.2EA.3Minimum conformance requirements (215)6.2.2EA.4Test description (216)6.2.2EA.4.3Message contents (217)6.2.2EA.5Test requirements (217)6.2.2F UE Maximum Output Power for category NB1 (218)6.2.2F.1Test purpose (218)6.2.2F.2Test applicability (218)6.2.2F.3Minimum conformance requirements (218)6.2.2F.4Test description (219)6.2.2F.4.1Initial condition (219)6.2.2F.4.2Test procedure (220)6.2.2F.4.3Message contents (220)6.2.2F.5Test requirements (220)6.2.2G UE Maximum Output Power for V2X Communication (221)6.2.2G.1UE Maximum Output Power for V2X Communication / Non-concurrent with E-UTRA uplinktransmission (221)6.2.2G.1.1Test purpose (221)6.2.2G.1.2Test applicability (221)6.2.2G.1.3Minimum conformance requirements (221)6.2.2G.1.4Test description (222)6.2.2G.1.4.1Initial conditions (222)6.2.2G.1.4.2Test procedure (222)6.2.2G.1.4.3Message contents (222)6.2.2G.1.5Test requirements (223)6.2.2G.2UE Maximum Output Power for V2X Communication / Simultaneous E-UTRA V2X sidelinkand E-UTRA uplink transmission (223)6.2.2G.2.1Test purpose (223)6.2.2G.2.2Test applicability (223)6.2.2G.2.3Minimum conformance requirements (223)6.2.2G.2.4Test description (224)6.2.2G.2.4.1Initial conditions (224)6.2.2G.2.4.2Test procedure (225)6.2.2G.2.4.3Message contents (226)6.2.2G.2.5Test requirements (226)6.2.3Maximum Power Reduction (MPR) (226)6.2.3.1Test purpose (226)6.2.3.2Test applicability (226)6.2.3.3Minimum conformance requirements (227)6.2.3.4Test description (227)6.2.3.4.1Initial condition (227)6.2.3.4.2Test procedure (228)6.2.3.4.3Message contents (228)6.2.3.5Test requirements (229)6.2.3_1Maximum Power Reduction (MPR) for HPUE (231)6.2.3_1.1Test purpose (231)6.2.3_1.4Test description (232)6.2.3_1.5Test requirements (232)6.2.3_2Maximum Power Reduction (MPR) for Multi-Cluster PUSCH (232)6.2.3_2.1Test purpose (232)6.2.3_2.2Test applicability (232)6.2.3_2.3Minimum conformance requirements (233)6.2.3_2.4Test description (233)6.2.3_2.4.1Initial condition (233)6.2.3_2.4.2Test procedure (234)6.2.3_2.4.3Message contents (234)6.2.3_2.5Test requirements (234)6.2.3_3Maximum Power Reduction (MPR) for UL 64QAM (235)6.2.3_3.1Test purpose (236)6.2.3_3.2Test applicability (236)6.2.3_3.3Minimum conformance requirements (236)6.2.3_3.4Test description (236)6.2.3_3.4.1Initial condition (236)6.2.3_3.4.2Test procedure (237)6.2.3_3.4.3Message contents (237)6.2.3_3.5Test requirements (238)6.2.3_4Maximum Power Reduction (MPR) for Multi-Cluster PUSCH with UL 64QAM (240)6.2.3_4.1Test purpose (240)6.2.3_4.2Test applicability (240)6.2.3_4.3Minimum conformance requirements (240)6.2.3_4.4Test description (241)6.2.3_4.4.1Initial condition (241)6.2.3_4.4.2Test procedure (242)6.2.3_4.4.3Message contents (242)6.2.3_4.5Test requirements (242)6.2.3A Maximum Power Reduction (MPR) for CA (243)6.2.3A.1Maximum Power Reduction (MPR) for CA (intra-band contiguous DL CA and UL CA) (243)6.2.3A.1.1Test purpose (243)6.2.3A.1.2Test applicability (243)6.2.3A.1.3Minimum conformance requirements (244)6.2.3A.1.4Test description (245)6.2.3A.1.5Test Requirements (248)6.2.3A.1_1Maximum Power Reduction (MPR) for CA (intra-band contiguous DL CA and UL CA) for UL64QAM (250)6.2.3A.1_1.1Test purpose (251)6.2.3A.1_1.2Test applicability (251)6.2.3A.1_1.3Minimum conformance requirements (251)6.2.3A.1_1.4Test description (252)6.2.3A.1_1.5Test requirement (254)6.2.3A.2Maximum Power Reduction (MPR) for CA (inter-band DL CA and UL CA) (255)6.2.3A.2.1Test purpose (255)6.2.3A.2.2Test applicability (255)6.2.3A.2.3Minimum conformance requirements (255)6.2.3A.2.4Test description (256)6.2.3A.2.5Test Requirements (260)6.2.3A.2_1Maximum Power Reduction (MPR) for CA (inter-band DL CA and UL CA) for UL 64QAM (263)6.2.3A.2_1.1Test purpose (263)6.2.3A.2_1.2Test applicability (263)6.2.3A.2_1.3Minimum conformance requirements (263)6.2.3A.2_1.4Test description (264)6.2.3A.2_1.5Test Requirements (266)6.2.3A.3Maximum Power Reduction (MPR) for CA (intra-band non-contiguous DL CA and UL CA) (267)6.2.3A.3.1Test purpose (267)6.2.3A.3.2Test applicability (267)6.2.3A.3.3Minimum conformance requirements (268)6.2.3A.3.4Test description (268)6.2.3A.3_1Maximum Power Reduction (MPR) for CA (intra-band non-contiguous DL CA and UL CA) forUL 64QAM (270)6.2.3A.3_1.1Test purpose (270)6.2.3A.3_1.2Test applicability (270)6.2.3A.3_1.3Minimum conformance requirements (270)6.2.3A.3_1.4Test description (271)6.2.3A.3_1.5Test Requirements (272)6.2.3B Maximum Power Reduction (MPR) for UL-MIMO (272)6.2.3B.1Test purpose (272)6.2.3B.2Test applicability (272)6.2.3B.3Minimum conformance requirements (273)6.2.3B.4Test description (273)6.2.3B.4.1Initial condition (273)6.2.3B.4.2Test procedure (274)6.2.3B.4.3Message contents (275)6.2.3B.5Test requirements (275)6.2.3D UE Maximum Output Power for ProSe (277)6.2.3D.0Minimum conformance requirements (277)6.2.3D.1Maximum Power Reduction (MPR) for ProSe Discovery (278)6.2.3D.1.1Test purpose (278)6.2.3D.1.2Test applicability (278)6.2.3D.1.3Minimum conformance requirements (278)6.2.3D.1.4Test description (278)6.2.3D.1.4.1Initial condition (278)6.2.3D.1.4.2Test procedure (279)6.2.3D.1.4.3Message contents (279)6.2.3D.1.5Test requirements (280)6.2.3D.2Maximum Power Reduction (MPR) ProSe Direct Communication (281)6.2.3D.2.1Test purpose (282)6.2.3D.2.2Test applicability (282)6.2.3D.2.3Minimum conformance requirements (282)6.2.3D.2.4Test description (282)6.2.3D.2.4.1Initial conditions (282)6.2.3D.2.4.2Test procedure (282)6.2.3D.2.4.3Message contents (282)6.2.3D.2.5Test requirements (282)6.2.3E Maximum Power Reduction (MPR) for UE category 0 (282)6.2.3E.1Test purpose (282)6.2.3E.2Test applicability (282)6.2.3E.3Minimum conformance requirements (282)6.2.3E.4Test description (282)6.2.3E.4.1Initial condition (282)6.2.3E.4.2Test procedure (283)6.2.3E.4.3Message contents (283)6.2.3E.5Test requirements (283)6.2.3EA Maximum Power Reduction (MPR) for UE category M1 (284)6.2.3EA.1Test purpose (284)6.2.3EA.2Test applicability (284)6.2.3EA.3Minimum conformance requirements (284)6.2.3EA.4Test description (285)6.2.3EA.4.1Initial condition (285)6.2.3EA.4.2Test procedure (287)6.2.3EA.4.3Message contents (287)6.2.3EA.5Test requirements (287)6.2.3F Maximum Power Reduction (MPR) for category NB1 (290)6.2.3F.1Test purpose (290)6.2.3F.2Test applicability (290)6.2.3F.3Minimum conformance requirements (290)6.2.3F.4Test description (291)6.2.3F.4.1Initial condition (291)6.2.3F.5Test requirements (292)6.2.3G Maximum Power Reduction (MPR) for V2X communication (292)6.2.3G.1Maximum Power Reduction (MPR) for V2X Communication / Power class 3 (293)6.2.3G.1.1Maximum Power Reduction (MPR) for V2X Communication / Power class 3 / Contiguousallocation of PSCCH and PSSCH (293)6.2.3G.1.1.1Test purpose (293)6.2.3G.1.1.2Test applicability (293)6.2.3G.1.1.3Minimum conformance requirements (293)6.2.3G.1.1.4Test description (293)6.2.3G.1.1.4.1Initial condition (293)6.2.3G.1.1.4.2Test procedure (294)6.2.3G.1.1.4.3Message contents (294)6.2.3G.1.1.5Test Requirements (294)6.2.3G.1.2 2956.2.3G.1.3Maximum Power Reduction (MPR) for V2X Communication / Power class 3 / SimultaneousE-UTRA V2X sidelink and E-UTRA uplink transmission (295)6.2.3G.1.3.1Test purpose (295)6.2.3G.1.3.2Test applicability (295)6.2.3G.1.3.3Minimum conformance requirements (295)6.2.3G.1.3.4Test description (295)6.2.3G.1.3.4.1Initial conditions (295)6.2.3G.1.3.4.2Test procedure (296)6.2.3G.1.3.4.3Message contents (297)6.2.3G.1.3.5Test requirements (297)6.2.4Additional Maximum Power Reduction (A-MPR) (297)6.2.4.1Test purpose (297)6.2.4.2Test applicability (297)6.2.4.3Minimum conformance requirements (298)6.2.4.4Test description (310)6.2.4.4.1Initial condition (310)6.2.4.4.2Test procedure (339)6.2.4.4.3Message contents (339)6.2.4.5Test requirements (344)6.2.4_1Additional Maximum Power Reduction (A-MPR) for HPUE (373)6.2.4_1.2Test applicability (374)6.2.4_1.3Minimum conformance requirements (374)6.2.4_1.4Test description (375)6.2.4_1.5Test requirements (376)6.2.4_2Additional Maximum Power Reduction (A-MPR) for UL 64QAM (378)6.2.4_2.1Test purpose (378)6.2.4_2.2Test applicability (378)6.2.4_2.3Minimum conformance requirements (378)6.2.4_2.4Test description (378)6.2.4_2.4.1Initial condition (378)6.2.4_2.4.2Test procedure (392)6.2.4_2.4.3Message contents (392)6.2.4_2.5Test requirements (392)6.2.4_3Additional Maximum Power Reduction (A-MPR) with PUSCH frequency hopping (404)6.2.4_3.1Test purpose (404)6.2.4_3.2Test applicability (404)6.2.4_3.3Minimum conformance requirements (405)6.2.4_3.4Test description (405)6.2.4_3.5Test requirements (406)6.2.4A Additional Maximum Power Reduction (A-MPR) for CA (407)6.2.4A.1Additional Maximum Power Reduction (A-MPR) for CA (intra-band contiguous DL CA and ULCA) (407)6.2.4A.1.1Test purpose (407)6.2.4A.1.2Test applicability (407)6.2.4A.1.3Minimum conformance requirements (407)6.2.4A.1.3.5A-MPR for CA_NS_05 for CA_38C (411)6.2.4A.1.4Test description (413)6.2.4A.1.5Test requirements (419)6.2.4A.1_1Additional Maximum Power Reduction (A-MPR) for CA (intra-band contiguous DL CA and ULCA) for UL 64QAM (425)6.2.4A.1_1.1Test purpose (425)6.2.4A.1_1.2Test applicability (425)6.2.4A.1_1.3Minimum conformance requirements (426)6.2.4A.1_1.3.5A-MPR for CA_NS_05 for CA_38C (429)6.2.4A.1_1.3.6A-MPR for CA_NS_06 for CA_7C (430)6.2.4A.1_1.3.7A-MPR for CA_NS_07 for CA_39C (431)6.2.4A.1_1.3.8A-MPR for CA_NS_08 for CA_42C (432)6.2.4A.1_1.4Test description (432)6.2.4A.1_1.5Test requirements (437)6.2.4A.2Additional Maximum Power Reduction (A-MPR) for CA (inter-band DL CA and UL CA) (443)6.2.4A.2.1Test purpose (443)6.2.4A.2.2Test applicability (444)6.2.4A.2.3Minimum conformance requirements (444)6.2.4A.2.4Test description (444)6.2.4A.2.4.1Initial conditions (444)6.2.4A.2.4.2Test procedure (457)6.2.4A.2.4.3Message contents (458)6.2.4A.2.5Test requirements (461)6.2.4A.3Additional Maximum Power Reduction (A-MPR) for CA (intra-band non-contiguous DL CAand UL CA) (466)6.2.4A.3.1Minimum conformance requirements (466)6.2.4A.2_1Additional Maximum Power Reduction (A-MPR) for CA (inter-band DL CA and UL CA) forUL 64QAM (466)6.2.4A.2_1.1Test purpose (466)6.2.4A.2_1.2Test applicability (466)6.2.4A.2_1.3Minimum conformance requirements (467)6.2.4A.2_1.4Test description (467)6.2.4A.2_1.4.1Initial conditions (467)6.2.4A.2_1.4.2Test procedure (479)6.2.4A.2_1.4.3Message contents (480)6.2.4A.2_1.5Test requirements (480)6.2.4B Additional Maximum Power Reduction (A-MPR) for UL-MIMO (484)6.2.4B.1Test purpose (484)6.2.4B.2Test applicability (485)6.2.4B.3Minimum conformance requirements (485)6.2.4B.4Test description (485)6.2.4B.4.1Initial condition (485)6.2.4B.4.2Test procedure (508)6.2.4B.4.3Message contents (508)6.2.4B.5Test requirements (508)6.2.4E Additional Maximum Power Reduction (A-MPR) for UE category 0 (530)6.2.4E.1Test purpose (530)6.2.4E.2Test applicability (531)6.2.4E.3Minimum conformance requirements (531)6.2.4E.4Test description (531)6.2.4E.4.1Initial condition (531)6.2.4E.4.2Test procedure (535)6.2.4E.4.3Message contents (535)6.2.4E.5Test requirements (536)6.2.4EA Additional Maximum Power Reduction (A-MPR) for UE category M1 (542)6.2.4EA.1Test purpose (542)6.2.4EA.2Test applicability (542)6.2.4EA.3Minimum conformance requirements (543)6.2.4EA.4Test description (544)6.2.4EA.4.1Initial condition (544)6.2.4EA.4.2Test procedure (552)6.2.4G Additional Maximum Power Reduction (A-MPR) for V2X Communication (562)6.2.4G.1Additional Maximum Power Reduction (A-MPR) for V2X Communication / Non-concurrentwith E-UTRA uplink transmissions (562)6.2.4G.1.1Test purpose (562)6.2.4G.1.2Test applicability (562)6.2.4G.1.3Minimum conformance requirements (563)6.2.4G.1.4Test description (563)6.2.4G.1.4.1Initial condition (563)6.2.4G.1.4.2Test procedure (564)6.2.4G.1.4.3Message contents (564)6.2.4G.1.5Test Requirements (564)6.2.5Configured UE transmitted Output Power (564)6.2.5.1Test purpose (564)6.2.5.2Test applicability (564)6.2.5.3Minimum conformance requirements (564)6.2.5.4Test description (594)6.2.5.4.1Initial conditions (594)6.2.5.4.2Test procedure (595)6.2.5.4.3Message contents (595)6.2.5.5Test requirement (596)6.2.5_1Configured UE transmitted Output Power for HPUE (596)6.2.5_1.1Test purpose (596)6.2.5_1.2Test applicability (597)6.2.5_1.3Minimum conformance requirements (597)6.2.5_1.4Test description (597)6.2.5_1.4.1Initial conditions (597)6.2.5_1.4.2Test procedure (597)6.2.5_1.4.3Message contents (597)6.2.5_1.5Test requirement (598)6.2.5A Configured transmitted power for CA (599)6.2.5A.1Configured UE transmitted Output Power for CA (intra-band contiguous DL CA and UL CA) (599)6.2.5A.1.1Test purpose (599)6.2.5A.1.2Test applicability (599)6.2.5A.1.3Minimum conformance requirements (599)6.2.5A.1.4Test description (601)6.2.5A.1.5Test requirement (602)6.2.5A.2Void (603)6.2.5A.3Configured UE transmitted Output Power for CA (inter-band DL CA and UL CA) (603)6.2.5A.3.1Test purpose (603)6.2.5A.3.2Test applicability (603)6.2.5A.3.3Minimum conformance requirements (603)6.2.5A.3.4Test description (605)6.2.5A.3.5Test requirement (606)6.2.5A.4Configured UE transmitted Output Power for CA (intra-band non-contiguous DL CA and ULCA) (607)6.2.5A.4.1Test purpose (607)6.2.5A.4.2Test applicability (607)6.2.5A.4.3Minimum conformance requirements (607)6.2.5A.4.4Test description (608)6.2.5A.4.5Test requirement (610)6.2.5B Configured UE transmitted Output Power for UL-MIMO (611)6.2.5B.1Test purpose (611)6.2.5B.2Test applicability (611)6.2.5B.3Minimum conformance requirements (611)6.2.5B.4Test description (612)6.2.5B.4.1Initial conditions (612)6.2.5B.4.2Test procedure (612)6.2.5B.4.3Message contents (613)6.2.5B.5Test requirement (613)6.2.5E Configured UE transmitted Output Power for UE category 0 (614)6.2.5E.4.1Initial conditions (614)6.2.5E.4.2Test procedure (614)6.2.5E.4.3Message contents (614)6.2.5E.5Test requirement (615)6.2.5EA Configured UE transmitted Power for UE category M1 (615)6.2.5EA.1Test purpose (615)6.2.5EA.2Test applicability (615)6.2.5EA.3Minimum conformance requirements (615)6.2.5EA.4Test description (616)6.2.5EA.4.1Initial condition (616)6.2.5EA.4.2Test procedure (617)6.2.5EA.4.3Message contents (617)6.2.5EA.5Test requirements (617)6.2.5F Configured UE transmitted Output Power for UE category NB1 (618)6.2.5F.1Test purpose (618)6.2.5F.2Test applicability (618)6.2.5F.3Minimum conformance requirements (618)6.2.5F.4Test description (619)6.2.5F.4.1Initial conditions (619)6.2.5F.4.2Test procedure (620)6.2.5F.4.3Message contents (620)6.2.5F.5Test requirement (620)6.2.5G Configured UE transmitted Output Power for V2X Communication (620)6.2.5G.1Configured UE transmitted Output Power for V2X Communication / Non-concurrent with E-UTRA uplink transmission (621)6.2.5G.1.1Test purpose (621)6.2.5G.1.2Test applicability (621)6.2.5G.1.3Minimum conformance requirements (621)6.2.5G.1.4Test description (622)6.2.5G.1.4.1Initial conditions (622)6.2.5G.1.4.2Test procedure (622)6.2.5G.1.4.3Message contents (622)6.2.5G.1.5Test requirements (622)6.2.5G.2Configured UE transmitted Output Power for V2X Communication / Simultaneous E-UTRAV2X sidelink and E-UTRA uplink transmission (622)6.2.5G.2.1Test purpose (623)6.2.5G.2.2Test applicability (623)6.2.5G.2.3Minimum conformance requirements (623)6.2.5G.2.4Test description (625)6.2.5G.2.4.1Initial conditions (625)6.2.5G.2.4.2Test procedure (626)6.2.5G.2.4.3Message contents (626)6.2.5G.2.5Test requirements (626)6.3Output Power Dynamics (627)6.3.1Void (627)6.3.2Minimum Output Power (627)6.3.2.1Test purpose (627)6.3.2.2Test applicability (627)6.3.2.3Minimum conformance requirements (627)6.3.2.4Test description (627)6.3.2.4.1Initial conditions (627)6.3.2.4.2Test procedure (628)6.3.2.4.3Message contents (628)6.3.2.5Test requirement (628)6.3.2A Minimum Output Power for CA (629)6.3.2A.0Minimum conformance requirements (629)6.3.2A.1Minimum Output Power for CA (intra-band contiguous DL CA and UL CA) (629)6.3.2A.1.1Test purpose (629)6.3.2A.1.4.2Test procedure (631)6.3.2A.1.4.3Message contents (631)6.3.2A.1.5Test requirements (631)6.3.2A.2Minimum Output Power for CA (inter-band DL CA and UL CA) (631)6.3.2A.2.1Test purpose (631)6.3.2A.2.2Test applicability (632)6.3.2A.2.3Minimum conformance requirements (632)6.3.2A.2.4Test description (632)6.3.2A.2.4.1Initial conditions (632)6.3.2A.2.4.2Test procedure (633)6.3.2A.2.4.3Message contents (633)6.3.2A.2.5Test requirements (633)6.3.2A.3Minimum Output Power for CA (intra-band non-contiguous DL CA and UL CA) (634)6.3.2A.3.1Test purpose (634)6.3.2A.3.2Test applicability (634)6.3.2A.3.3Minimum conformance requirements (634)6.3.2A.3.4Test description (634)6.3.2A.3.4.1Initial conditions (634)6.3.2A.3.4.2Test procedure (635)6.3.2A.3.4.3Message contents (635)6.3.2A.3.5Test requirements (635)6.3.2B Minimum Output Power for UL-MIMO (636)6.3.2B.1Test purpose (636)6.3.2B.2Test applicability (636)6.3.2B.3Minimum conformance requirements (636)6.3.2B.4Test description (636)6.3.2B.4.1Initial conditions (636)6.3.2B.4.2Test procedure (637)6.3.2B.4.3Message contents (637)6.3.2B.5Test requirement (637)6.3.2E Minimum Output Power for UE category 0 (638)6.3.2E.1Test purpose (638)6.3.2E.2Test applicability (638)6.3.2E.3Minimum conformance requirements (638)6.3.2E.4Test description (638)6.3.2E.4.1Initial conditions (638)6.3.2E.4.2Test procedure (639)6.3.2E.4.3Message contents (639)6.3.2E.5Test requirement (639)6.3.2EA Minimum Output Power for UE category M1 (639)6.3.2EA.1Test purpose (639)6.3.2EA.2Test applicability (640)6.3.2EA.3Minimum conformance requirements (640)6.3.2EA.4Test description (640)6.3.2EA.4.1Initial condition (640)6.3.2EA.4.2Test procedure (641)6.3.2EA.4.3Message contents (641)6.3.2EA.5Test requirements (641)6.3.2F Minimum Output Power for category NB1 (641)6.3.2F.1Test purpose (641)6.3.2F.2Test applicability (641)6.3.2F.3Minimum conformance requirements (642)6.3.2F.4Test description (642)6.3.2F.4.1Initial conditions (642)6.3.2F.4.2Test procedure (643)6.3.2F.4.3Message contents (643)6.3.2F.5Test requirements (643)6.3.3Transmit OFF power (643)6.3.3.5Test requirement (644)6.3.3A UE Transmit OFF power for CA (644)6.3.3A.0Minimum conformance requirements (644)6.3.3A.1UE Transmit OFF power for CA (intra-band contiguous DL CA and UL CA) (645)6.3.3A.1.1Test purpose (645)6.3.3A.1.2Test applicability (645)6.3.3A.1.3Minimum conformance requirements (645)6.3.3A.1.4Test description (645)6.3.3A.1.5Test Requirements (645)6.3.3A.2UE Transmit OFF power for CA (inter-band DL CA and UL CA) (646)6.3.3A.2.1Test purpose (646)6.3.3A.2.2Test applicability (646)6.3.3A.2.3Minimum conformance requirements (646)6.3.3A.2.4Test description (646)6.3.3A.2.5Test Requirements (646)6.3.3A.3UE Transmit OFF power for CA (intra-band non-contiguous DL CA and UL CA) (646)6.3.3A.3.1Test purpose (646)6.3.3A.3.2Test applicability (646)6.3.3A.3.3Minimum conformance requirements (647)6.3.3A.3.4Test description (647)6.3.3A.3.5Test Requirements (647)6.3.3B UE Transmit OFF power for UL-MIMO (647)6.3.3B.1Test purpose (647)6.3.3B.2Test applicability (647)6.3.3B.3Minimum conformance requirement (647)6.3.3B.4Test description (647)6.3.3B.5Test requirement (648)6.3.3C 6486.3.3D UE Transmit OFF power for ProSe (648)6.3.3D.0Minimum conformance requirements (648)6.3.3D.1UE Transmit OFF power for ProSe Direct Discovery (648)6.3.3D.1.1Test purpose (649)6.3.3D.1.2Test applicability (649)6.3.3D.1.3Minimum Conformance requirements (649)6.3.3D.1.4Test description (649)6.3.3D.1.5Test requirements (650)6.3.3E UE Transmit OFF power for UE category 0 (650)6.3.3E.1Test purpose (650)6.3.3E.2Test applicability (650)6.3.3E.3Minimum conformance requirement (650)6.3.3E.4Test description (651)6.3.3E.5Test requirement (651)6.3.3EA UE Transmit OFF power for UE category M1 (651)6.3.3EA.1Test purpose (651)6.3.3EA.2Test applicability (651)6.3.3EA.3Minimum conformance requirements (651)6.3.3EA.4Test description (651)6.3.3EA.5Test requirements (652)6.3.3F Transmit OFF power for category NB1 (652)6.3.3F.1Test purpose (652)6.3.3F.2Test applicability (652)6.3.3F.3Minimum conformance requirement (652)6.3.3F.4Test description (652)6.3.3F.5Test requirement (652)6.3.4ON/OFF time mask (652)6.3.4.1General ON/OFF time mask (652)6.3.4.1.1Test purpose (652)6.3.4.1.2Test applicability (653)。

OBD-II P-U故障码动力总成系统OBD故障码: P2开头的故障码适用于所有汽车制造商-&gt; 燃油，空气或排放控制故障码: P2000中文定义: 氮氧化物(NOx)的捕集器效率低于阈值(第1排)英文定义: NOx Adsorber Efficiency Below Threshold (Bank 1)范畴: 燃油，空气或排放控制故障码: P2001中文定义: 氮氧化物(NOx)的捕集器效率低于阈值(第2排)英文定义: NOx Adsorber Efficiency Below Threshold (Bank 2)范畴: 燃油，空气或排放控制故障码: P2002中文定义: 柴油机微粒过滤器效率低于阈值(第1排)英文定义: Diesel Particulate Filter Efficiency Below Threshold (Bank 1)范畴: 燃油，空气或排放控制故障码: P2003中文定义: 柴油机微粒过滤器效率低于阈值(第2排)英文定义: Diesel Particulate Filter Efficiency Below Threshold (Bank 2)范畴: 燃油，空气或排放控制故障码: P2004中文定义: 进气歧管通路控制卡在开的位置(第1排)英文定义: Intake Manifold Runner Control Stuck Open (Bank 1)范畴: 燃油，空气或排放控制背景知识: 进气歧管通路控制（IMRC）总成位于进气歧管和气缸盖之间。

为提高发动机性能，每个气缸对应两个进气通路，其中之一一直开通，另一个仅当转速高于一定值（比如说3000RPM）的时候才打开。

IMRC执行电机的作用是根据电控单元（ECU）的指令开/关进气通路的阀门翻板。

故障码: P2005中文定义: 进气歧管通路控制卡在开的位置(第2排)英文定义: Intake Manifold Runner Control Stuck Open (Bank 2)范畴: 燃油，空气或排放控制背景知识: 进气歧管通路控制（IMRC）总成位于进气歧管和气缸盖之间。

MIL-PRF-19500/547B 30 July 1999 SUPERSEDING MIL-S-19500/547A 20 January 1988PERFORMANCE SPECIFICATION SHEETSEMICONDUCTOR DEVICE, FIELD EFFECT TRANSISTOR, N-CHANNEL,SILICON TYPES 2N6660 AND 2N6661JAN, JANTX, JANTXV AND JANSThis specification is approved for use by all Depart-ments and Agencies of the Department of Defense.1. SCOPE1.1 Scope. This specification covers the performance requirements for a N-channel, enhancement-mode, low-threshold logic level,high frequency, high switching speed MOSFET, power transistor. Four levels of product assurance are provided for each encapsulated device type as specified in MIL-PRF-19500.1.2 Physical dimensions. See figure 1 (TO-205AD).1.3 Maximum ratings. Unless otherwise specified, T A = +25°C.TypeP T 1/T C = +25°C P T T A = +25°CV DSV DGR 3/V GSI D1 2/T C = +25°C I D2 2/T C = +100°CI SI DMT J and T STG 2N66602N6661W6.256.25mW 725725V dc 6090V dc 6090V dc ± 20± 20 A dc 0.990.86A dc 0.620.54A dc -0.99-0.86A(pk)33°C -65 to +1501/ Derate linearly 0.05 W/°C for T C > +25°C 2/ Derate above T C = +25 °C according to the formula Krated P I D )(=where P(rated) = 150 - (T C -25) (0.05) watts;K = max r DS(on) at T J =+150°C.3/ R GS ≤ 1 M ohm.AMSC N/AFSC 5961DISTRIBUTION STATEMENT A. Approved for public release; distribution is unlimited.The documentation and process conversion measures necessary to comply with this revision shall be completed by 30 October 1999INCH-POUND Beneficial comments (recommendations, additions, deletions) and any pertinent data which may be of use in improving this document should be addressed to: Commander, Defense Supply Center Columbus, ATTN: DSCC-VAC, 3990 East Broad St., Columbus, OH 43216-5000, by using the addressed Standardization Document Improvement Proposal (DD Form 1426) appearing at the end of this document or by letter.1.4 Primary electrical characteristics at T C = +25°C.Type Min V(BR)DSSV GS = 0 VI D = 10 µA dcV GS(th)1V DS≥ V GSI D = 1.0 mA dcMax I DSS1V GS = 0 VMax r DS(on) 1/V GS = 10 V dcRθJCMaxV DS = 80 percentofrated V DST J = +25°Cat I D1T J = +150°Cat I D22N6660 2N6661 V dc6090V dcMin Max0.8 2.00.8 2.0µA dc1.01.0Ohm3.04.0Ohm6.338.44°C/W20201/ Pulsed (see 4.5.1).2. APPLICABLE DOCUMENTS2.1 General. The documents listed in this section are specified in sections 3 and 4 of this specification. This section does not include documents cited in other sections of this specification or recommended for additional information or as examples. While every effort has been made to ensure the completeness of this list, document users are cautioned that they must meet all specified requirements documents cited in section 3 and 4 of this specification, whether or not they are listed.2.1.1 Specifications, standards, and handbooks. The following specifications, standards, and handbooks form a part of this document to the extent specified herein. Unless otherwise specified, the issues of these documents are those listed in the issue of the Department of Defense Index of Specifications and Standards (DODISS) and supplement thereto, cited in the solicitation (see 6.2).SPECIFICATIONDEPARTMENT OF DEFENSEMIL-PRF-19500 - Semiconductor Devices, General Specification for.STANDARDMILITARYMIL-STD-750 - Test Methods for Semiconductor Devices.(Unless otherwise indicated, copies of the above specifications, standards, and handbooks are available from the Defense Automated Printing Service, Building 4D (DPM-DODSSP), 700 Robbins Avenue, Philadelphia, PA 19111-5094.)2.2 Order of precedence. In the event of a conflict between the text of this specification and the references cited herein, the text of this specification takes precedence. Nothing in this document, however, supersedes applicable laws and regulations unless a specific exemption has been obtained.3. REQUIREMENTS3.1 Associated specification. The individual item requirements shall be in accordance with MIL-PRF-19500 and as specified herein.3.2 Abbreviations, symbols, and definitions. Abbreviations, symbols, and definitions used herein shall be as specified in MIL-PRF-19500.3.3 Interface requirements and physical dimensions. The Interface requirements and physical dimensions shall be as specified in MIL-PRF-19500 and figure 1 (TO-205AD) herein.2FIGURE 1. Physical dimensions (TO-205AD).3Ltr Dimensions NotesInches MillimetersMin Max Min MaxCD0.3050.3357.758.51CH0.2400.260 6.10 6.60HD0.3350.3708.519.40TW0.0280.0340.710.862TL0.0290.0450.74 1.14 3LD0.0160.0210.410.537,8LL0.5000.75012.7019.057,8LC0.200 TP 5.08 TP6LU0.0160.0190.410.487,8L10.050 1.277,8L20.250 6.357,8P0.100 2.545Q0.050 1.274R0.0100.259α45 TP45 TP6NOTES:1.Dimensions are in inches. Metric equivalents are given for general information only.2.Beyond radius (r) maximum, TW shall be held for a minimum length of 0.011 (0.028 mm).3.Dimension TL measured from maximum HD.4.Outline in this zone is not controlled.5.Dimension CD shall not vary more than 0.010 (0.25 mm) in zone P. This zone is controlled for automatic handling.6.Leads at gauge plane 0.054 + 0.001, - 0.000 (1.37 +0.03, -0.00 mm) below seating plane shall be within 0.007 (0.18 mm)radius of true position (TP) at maximum material condition (MMC) relative to tab at MMC.7.LU applies between L1 and L2. LD applies between L2 and L minimum. Diameter is uncontrolled in L1 and beyond LLminimum.8.All three leads.9.Radius (r) applies to both inside corners of tab.10.Drain is electrically connected to the case.FIGURE 1. Physical dimensions(TO-205AD) Continued.43.3.1 Lead finish. Lead finish shall be solderable in accordance with MIL-PRF-19500, MIL-STD-750, and herein. Where a choice of lead finish is desired, it shall be specified in the acquisition document (see 6.2).3.3.2 Internal construction. Multiple chip construction shall not be permitted.3.4 Marking. Marking shall be in accordance with MIL-PRF-19500.3.5 Electrostatic discharge protection. The devices covered by this specification require electrostatic protection.3.5.1 Handling. MOS devices must be handled with certain precautions to avoid damage due to the accumulation of static charge. The following handling practices shall be followed:a.Devices shall be handled on benches with conductive handling devices.b.Ground test equipment, tools, and personnel handling devices.c.Do not handle devices by the leads.d.Store devices in conductive foam or carriers.e.Avoid use of plastic, rubber, or silk in MOS areas.f.Maintain relative humidity above 50 percent if practical.g.Care shall be exercised, during test and troubleshooting, to apply not more than maximum rated voltage to any lead.h.Gate must be terminated to source, R ≤ 100 k, whenever bias voltage is to be applied drain to source.3.6 Electrical performance characteristics. Unless otherwise specified herein, the electrical performance characteristics are as specified in 1.3, 1.4, and table I.3.7 Electrical test requirements. The electrical test requirements shall be the subgroups specified in table I herein.3.8 Qualification. Devices furnished under this specification shall be products that are authorized by the qualifying activity for listing on the applicable qualified manufacturer's list before contract award (see4.2 and 6.3 ).4. VERIFICATION4.1 Classification of Inspections. The inspection requirements specified herein are classified as follows:a. Qualification inspection (see 4.2).b. Screening (see 4.3).c. Conformance inspection (see 4.4).4.2 Qualification inspection. Qualification inspection shall be in accordance with MIL-PRF-19500 and herein. Alternate flow is allowed for qualification inspection in accordance with figure 4 of MIL-PRF-19500.4.2.1 Group E inspection. Group E inspection shall be conducted in accordance with MIL-PRF-19500 and herein.54.3 Screening (JANS, JANTX, and JANTXV levels only). Screening shall be in accordance with table IV of MIL-PRF-19500 and as specified herein. The following measurements shall be made in accordance with table I herein. Devices that exceed the limits of table I herein shall not be acceptable.Screen (see table IV ofMIL-PRF-19500)MeasurementJANS level JANTX and JANTXV levels 3Test condition G.Test condition G.1/Method 3161 (see 4.5.3)Method 3161 (see 4.5.3)9I GSS1, I DSS1, gate stress test (see 4.5.5),subgroup 2 of table I herein Gate stress test (see 4.5.5), subgroup 2 of table I herein10Method 1042, test condition B Method 1042, test condition B11Subgroup 2 of table I herein;I GSS1, I DSS1, r DS(on)1, V GS(th)1,∆I GSS1 = ± 10 nA dc or ±100 percent of initialvalue, whichever is greater.∆I DSS1 = ± 1 µA dc or ±100 percent of initialvalue, whichever is greater.Subgroup 2 of table I herein.I GSS1, I DSS1, r DS(on)1, V GS(th)112Method 1042, test condition A and test conditionC. (see 4.3.1)Method 1042, test condition A, (see 4.3.1)13Subgroups 2 and 3 of table I herein;∆I GSS1 = ± 10 nA dc or ±100 percent of initialvalue, whichever is greater.∆I DSS1 = ± 1 µA dc or ±100 percent of initialvalue, whichever is greater.∆r DS(on)1 = ± 20 percent of initial value or ± 0.5ohm, whichever is greater.∆V GS(th)1 = 4± 10 percent of initial value or ±0.3 V dc.Subgroup 2 of table I herein;∆I GSS1 = ± 10 nA dc or ±100 percent of initial value, whichever is greater.∆I DSS1 = ± 1 µA dc or ±100 percent of initial value, whichever is greater.∆r DS(on)1 = ± 20 percent of initial value or ± 0.5 ohm, whichever is greater.∆V GS(th)1 = ± 10 percent of initial value or ± 0.3 V dc.1/ Shall be performed anytime before screen 9.4.3.1 Power burn-in. Power burn-in conditions are as follows: MIL-STD-750, method 3161, condition C, T A = +25°C, -5°C, +10°C, V DS = 10 V min.; I D adjusted to meet a junction temperature of 140°C, - 0°C, + 10°C, t = 240 hours.4.4 Conformance inspection. Conformance inspection shall be in accordance with MIL-PRF-19500. Alternate flow is allowed for quality conformance inspection in accordance with figure 4 of MIL-PRF-19500.4.4.1 Group A inspection. Group A inspection shall be conducted in accordance with MIL-PRF-19500 and table I herein. Electrical measurements (end-points) shall be in accordance with the inspections of table I, subgroup 2 herein.64.4.2 Group B inspection. Group B inspection shall be conducted in accordance with the conditions specified for subgroup testing in table VIa of MIL-PRF-19500 (JANS) and 4.4.2.1 herein. Electrical measurements (end-points) shall be in accordance with group A, subgroup 2 herein. Delta measurements shall be in accordance with table II herein. See 4.4.2.2 herein and table VIb of MIL-PRF-19500 for JAN, JANTX, and JANTXV group B testing. Electrical measurements (end-points) requirements shall be in accordance with group A, subgroup 2 herein. Delta measurements shall be in accordance with table II herein.4.4.2.1 Group B inspection table VIa (JANS) of MIL-PRF-19500.Subgroup Method Conditions3 1051Test condition G.4 1042Test condition D; 2,000 cycles. The heating cycle shall be 1 minute minimum.V DS = 10 V dc, P T = See 1.4 at T A = +25°C ± 3°C.5 1042Accelerated steady-state operation life; test condition C; T A = + 25°C, - 5°C, + 10°C, V DS = 10 Vmin.; I D adjusted to meet a junction temperature of 140°C, - 0°C, + 10°C, t = 240 hours.5 2037Bond strength (Al-Au die interconnects only); test condition A.6 3161See 4.5.2.4.4.2.2 Group B inspection, table IVb (JAN, JANTX and JANTXV) of MIL-PRF-19500.Subgroup Method Condition2 1051Test condition G, 25 cycles.3 1027T J = P T (RθJA) + P T= V DS I D; V DS = 15 V dc; I D≤ 0.05 A dc; RθJA = 170°C/W;T A= 30 °C ± 5°C.4.4.3 Group C inspection. Group C inspection shall be conducted in accordance with the conditions specified for subgroup testing in table VII of MIL-PRF-19500 and as follows. Electrical measurements (end-points) shall be in accordance with table I, subgroup 2 herein. Delta measurements shall be in accordance with table II herein.Subgroup Method Condition2 2036Test condition E .6 1026T J = P T (RθJA) + P T= V DS I D; V DS = 15 V dc; I D≤ 0.05 A dc; RθJA = 170°C/W;T A= 30 °C ± 5°C.74.4.4 Group E inspection. Group E inspection shall be conducted in accordance with the conditions specified for subgroup testing in table IX of MIL-PRF-19500 and as follows. Electrical measurements (end-points) shall be in accordance with table I, subgroup 2 herein. Delta measurements shall be in accordance with table II herein. A separate sample may be pulled for each test.Subgroup Method Condition Sampling planE1 1051Test condition G, 500 cycles45 devices, c = 0Electrical measurementsSee table I, subgroup 2.E2 1042Test condition A, 1,000 hours.45 devices, c = 0Electrical measurementsSee table I, subgroup 2.E2 1042Test condition B, 1,000 hours.45 devices, c = 0Electrical measurementsSee table I, subgroup 2.E3Not applicableE4 3161RθJC see 1.4 herein. 5 devices, c = 0E5Not applicable4.5 Methods of inspection. Methods of inspection shall be as specified in the appropriate tables and as follows.4.5.1 Pulse measurements. Conditions for pulse measurement shall be as specified in section 4 of MIL-STD-750.4.5.2 Thermal impedance. Thermal impedance measurements shall be performed in accordance with method 3161 of MIL-STD 750. RθJC (max) = 20 °C/W.I M measuring current .......................................................10 mA.I M drain heating current.....................................................0.41 A.t H heating time..................................................................Steady state (see MIL-STD-750, method 3161 for definition).V H drain-source heating voltage.......................................10 V.t MD measurement time delay............................................10 to 80 µs.t SW sample window time.................................................10 µs (max).4.5.3 Thermal response (∆V SD measurements). The ∆V SD measurements shall be performed in accordance with MIL-STD-750, method 3161. The V SD conditions (I H and V H) and maximum limit shall be derived by each vendor from the thermal response curves and shall be specified in the certificate of conformance prior to qualification. The following parameter measurements shall apply.I M measuring current .......................................................10 mA.I M drain heating current.....................................................0.41 A.T H heating time.................................................................Steady state (see MIL-STD-750, method 3161 for definition).V H drain-source heating voltage.......................................10 V.t MD measurement time delay............................................10 to 80 µs.t SW sample window time.................................................10 µs (max).84.5.4 Unclamped inductive switching.a. Peak current (I D) (see 1.4 herein).b.Peak gate voltage (V GS)............................................................10 V.c.Gate to source resistor (R GS) ...................................................25Ω≤ R GS≤ 200Ω.d.Initial case temperature (T C) .....................................................+25°C, +10°C, -5°C.e.Inductance (L).............................................................................100 µH ±10 percent.f.Number of pulses to be applied..................................................1 pulse minimum.g.Pulse repetition rate....................................................................None.4.5.5 Gate stress test.V GS = ± 30 V minimum.t = 250 µs minimum.9TABLE I. Group A inspection.Inspection 1/MIL-STD-750Symbol Limits UnitMethod Conditions Min Max Subgroup 1Visual and mechanicalInspection2071Subgroup 2Breakdown voltage, drain to Source2N66602N66613407Bias condition C, V GS = 0 V;I D = 1.0 µA dcV(BR)DSS6090Gate to source voltage(threshold)3403V DS > V GS; I D = -1.0 mA dc V GS(th)10.8 2.0V dcGate current3411Bias condition C; V DS = 0 V;V GS = +20 and -20 V dcI GSS1±100nA dcDrain current3413V GS = 0; bias condition C;V DS = 80 percent of rated V DS (see1.3)I DSS1 1.0µA dcDrain to source on-state voltage 2N66602N66613405V GS = 10 V dc; condition A; pulsed(see 4.5.1), I D = -1.0 A dcV DS(on)13.04.0VDrain to source on-state voltage 2N66602N66613405V GS = 5 V dc; condition A; pulsed(see 4.5.1), I D = 0.3 A dcV DS(on)21.51.6VStatic drain to source on-state resistance2N66602N66613421V GS = 10 V dc; condition A; pulsed(see 4.5.1); I D = 1.0 A dcr DS(on)13.04.0ohmsStatic drain to source on-state resistance2N66602N66613421V GS = 5 V dc; condition A; pulsed(see 4.5.1); I D = 10.3 A dcr DS(on)25.05.3ohmsForward voltage (source drain diode)2N66602N66614011Pulsed (see 4.5.1); V GS = 0 VI S = 0.99 A dcI S = 0.86 A dcV SD0.70.71.61.4V (pk)See footnotes at end of table.10TABLE I. Group A inspection - Continued.Inspection 1/MIL-STD-750Symbol Limits UnitMethod Conditions Min Max Subgroup 2 continuedForward transconductance 2N66602N66613475Pulsed (see 4.5.1), V DS = V GS = 7.5V dcI D1 = 525 m A dcI D2 = 475 m A dcg FS170msSubgroup 3High temperature operation:T C = +125°CGate current3411Bias condition C, V DS = 0 V;V GS = +20 V dc and -20 V dcI GSS2± 500nA dcDrain current3413Bias condition C, V GS = 0 V,V DS = -80 percent of rated V DS (see1.3)I DSS2100µA dcDrain to source on-state voltage 2N66602N66613405V GS = 10 V dc; condition A; pulsed(see 4.5.1), I D = 1 A dcV DS(on)35.67.5VStatic drain to source on-state resistance2N66602N66613421V GS = 10 V dc; condition A; pulsed(see 4.5.1); I D = 1.0 A dcr DS(on)35.67.5ohmsGate to source voltage(threshold)3403V DS > V GS, I D = -1.0 mA dc V GS(th)20.3V dc Low temperature operation:T C = -55°CGate to source voltage(threshold)3403V DS > V GS; I D = 1.0 mA V GS(th)3 2.5V dc Subgroup 4Switching time test3472Rgen = 50 Ω; R GS = 50 Ω,Turn-on delay time V DD = 25 V dc; I D≅1 A dc t d(on)10ns Turn-off delay time V DD = 25 V dc; I D≅1 A dc t d(off)10ns See footnotes at end of table.11TABLE I. Group A inspection - Continued.Inspection 1/MIL-STD-750Symbol Limits UnitMethod Conditions Min Max Subgroup 4 - Continued.Small signal common source short-circuit input capacitance 3431V DS = 25 V dc; V GS; = 0 V; f = 1MHzC iss50pFSmall signal common source short-circuit output capacitance V DS = 25 V dc; V GS; = 0V; f = 1MHz,C oss40pFSmall signal common source short-circuit reverse transfer capacitance 3433V DS = 25 V dc; V GS; = 0 V; f = 1MHzC rss10pFSubgroup 5Safe operating area High voltage test Electrical measurements See figure 2V DS = 80 percent of rated V DS (see 1.3)See table I, subgroup 2.Subgroups 6 and 7Not applicable1/ For sampling plan, see MIL-PRF-19500.12TABLE II. Group B, C and E delta measurements. 1/ 2/ 3/ 4/Step Inspection 5/MIL-STD-750Symbol Limit UnitMethod ConditionsMin Max1.Gate current3411Bias condition C; VDS = 0 VV GS = +15 V dc and -15 V dc ∆I GSS± 10 nA dc or 100percent of initialvalue, whichever isgreater.2.Drain cutoff current3413Bias condition C; V GS = +15 V dcand -15 V dcV DS = 60 V for 2N6660V DS = 90 V for 2N6661∆I DSS± 1 µA dc or 100percent of initialvalue, whichever isgreater.3.Small signal, drain tosource on-stateresistance 3423VGS = 10 V dc; condition A,pulsed (see 4.5.1); I D = 1.0 A dcf = kHz∆r DS(on)± 0.5 ohm or ± 20percent of initialvalue , whicheveris greater.4.Gate to source voltage(threshold)3403VDS = V GS ; I D = 1.0 mA dc∆V GS(th)± 10 percent ofinitial value or± 0.3 V dc,whichever isgreater.5.Thermal resistance3161See 4.5.2RθJC20°C/W1/The delta measurements for table VIa (JANS) of MIL-PRF-19500 are as follows:a. Subgroup 3, see table II herein, step 1.b. Subgroup 4, see table II herein, step 5.2/The delta measurements for table VIb (JAN, JANTX and JANTXV) of MIL-PRF-19500 are as follows:a. Subgroup 3, see table II herein, step 5.3/The delta measurements for table VII of MIL-PRF-19500 are as follows:a. Subgroup 6, see table II herein, step 5.4/The delta measurements for table IX of MIL-PRF-19500 are as follows:a. Subgroup 1, see table II herein, step 1.b. Subgroup 2, see table II herein, step 1.5/See MIL-PRF-19500 for sampling plan.1314FIGURE 2. Maximum safe operating area.15FIGURE 2. Maximum safe operating area continued.5. PACKAGING5.1 Packaging. For acquisition purposes, the packaging requirements shall be as specified in the contract or order (see6.2). When actual packaging of material is to be performed by DoD personnel, these personnel need to contact the responsible packaging activity to ascertain requisite packaging requirements. Packaging requirements are maintained by the Inventory Control Points' packaging activity within the Military Department or Defense Agency, or within the Military Departments' System Command. Packaging data retrieval is available from the managing Military Departments' or Defense Agency's automated packaging files, CD-ROM products, or by contacting the responsible packaging activity.6. NOTES(This section contains information of a general or explanatory nature that may be helpful, but is not mandatory.)6.1 Notes. The notes specified in MIL-PRF-19500 are applicable to this specification.6.2 Acquisition requirements. Acquisition documents must specify the following:a.Issue of DODISS to be cited in the solicitation (see 2.2.1).b.The lead finish as specified (see 3.3.1).c.Type designation and quality assurance level.d.Packaging requirements (see 5.1).6.3 Qualification. With respect to products requiring qualification, awards will be made only for products which are, at the time of award of contract, qualified for inclusion in Qualified Manufacturer's QML-19500 whether or not such products have actually been so listed by that date. The attention of the contractors is called to these requirements, and manufacturers are urged to arrange to have the products that they propose to offer to the Federal Government tested for qualification in order that they may be eligible to be awarded contracts or purchase orders for the products covered by this specification. Information pertaining to qualification of products may be obtained from Defense Supply Center Columbus, DSCC-VQE, Columbus, OH 43216.6.4 Changes from previous issue. Asterisks are not used in this revision to identify changes with respect to the previous issue due to the extensiveness of the changes.Custodians:Preparing activity: Army - CR DLA - CCNavy - ECAir Force - 11(Project 5961- 2080)DLA - CCReview activities:Navy - TDAir Force - 13, 19, 9916STANDARDIZATION DOCUMENT IMPROVEMENT PROPOSALINSTRUCTIONS1. The preparing activity must complete blocks 1, 2, 3, and 8. In block 1, both the document number and revision letter should be given.2. The submitter of this form must complete blocks 4, 5, 6, and 7.3. The preparing activity must provide a reply within 30 days from receipt of the form.NOTE: This form may not be used to request copies of documents, nor to request waivers, or clarification of requirements on current contracts. Comments submitted on this form do not constitute or imply authorization to waive any portion of the referenced document(s) or to amend contractual requirements.I RECOMMEND A CHANGE: 1. DOCUMENT NUMBERMIL-PRF-19500/547B 2. DOCUMENT DATE (YYMMDD) 9907303. DOCUMENT TITLESEMICONDUCTOR DEVICE, FIELD EFFECT TRANSISTOR, N-CHANNEL, SILICON TYPES 2N6660 AND 2N6661 JAN, JANTX, JANTXV AND JANS4. NATURE OF CHANGE (Identify paragraph number and include proposed rewrite, if possible. Attach extra sheets as needed.)5. REASON FOR RECOMMENDATION6.SUBMITTERa. NAME (Last, First, Middle initial)b. ORGANIZATIONc. ADDRESS (Include Zip Code)d. TELEPHONE (Include Area Code)CommercialDSNFAXEMAIL7. DATE SUBMITTED(YYMMDD)8.PREPARING ACTIVITYa. Point of contact: Alan Barone,b. TELEPHONECommercial DSN FAX EMAIL614-692-0510 850-0510 614-692-6939 alan_barone@c. ADDRESS : Defense Supply Center Columbus, ATTN: DSCC-VAC, 3990 East Broad Street, Columbus, OH 43216-5000IF YOU DO NOT RECEIVE A REPLY WITHIN 45 DAYS, CONTACT: Defense Standardization Program Office (DLSC-LM)8725 John J. Kingman, Suite 2533, Fort Belvoir, VA 22060-6221Telephone (703) 767-6888 DSN 427-68880DD Form 1426, Feb 1999 (EG) Previous editions are obsolete WHS/DIOR, Feb 99。

F3 命令总结扬州飞浩数据处理服务中心硬盘维修系列命令总结：F3 2>F33FCDF0,A1F3 2>F33B8300,A1F3 T>m0,6,3，，，，，22F3系列加载坏道入表，现在MRT修盘中已经加入；希捷修改12代SN MODEL FIREWARE指令如需帮助请加qq 916169009 电话186********F3 T>J"ST3320318AS",15 // 修改MODEL号F3 T>J"ST3320318AS",16 // 再次输入你要修改的MODEL号F3 T>J"6VM12345",01 //输入你要修改的SN号F3 T>W,,22 //写入硬盘你的操作还原设置：F，，22代修复通病：m0,2,2,0,0,0,0,22重建译码表：m0,6,2,,,,,22恢复译码表：m0,2,1,,,,,22G转P表：/A 回车到A级下输入P回车磁头检查：/7 回车到7级下输入X回车清零：m0,8,2,1,1,,,22F3 T>m0,8,,10,8,0,14,22修前好后坏：m0,11,2,2,2,,,22 修坏道：m,10,,,,,22修复LBA为0：m,2,,,,,,22查看G表：T级下：V40查看P表：T级下：V10查看T表：T级下：V2查看SMART表：1级下：N5 清G表：i4,1,22清P表：i1,1,22清T表：i2,2,22清SMART：1级下N1,,22数据恢复常用命令；检查磁头LEV 7X显示系统磁道滑动缺陷LEV TV2显示用户磁道滑动缺陷LEV TV1LEV TV10显示Alt-ListLEV TV4清除SMARTALERT 此操作可能损坏用户数据，要继续吗？LEV 1N1清除Alt-list(重定向)ALERT 此操作可能损坏用户数据，要继续吗？LEV Ti4,1,22G表转P表ALERT 此操作可能损坏用户数据，要继续吗？LEV AP编译器重建ALERT 此操作重建编译器，并且不考虑增长缺陷表，它可能损坏用户数据，要继续吗？LEV T含增长缺陷编译器重建ALERT 此操作重建编译器，并且会处理增长缺陷表，它可能损坏用户数据，要继续吗？LEV Tm0,6,3,,,,,22格式化用户数据区ALERT 该操作将低级格式化用户数据区域，这将导致用户数据全部丢失，要继续吗？LEV Tm0,8,2,1,1,,,22显示伺服缺陷表LEV TV8显示段位表LEV 2x关闭SMART及安全子系统特性LEV TF"CommandSetSupported",6830还原Congen参数到默认值LEV TF,,22低级格式化(修盘专用)ALERT 该操作将低级格式化用户数据区域，这将导致用户数据全部丢失，要继续吗？LEV Tm0,8,3,,,,,22进入Boot Code模式LEV 1e,F进入串口二进制模式LEV T F3 T>01退出串口二进制模式LEV T F3 T>03扫描密码磁道中扫描：F3 T>O1Raw Binary Output Mode selected F3 T>/2F3 2>A0F3 2>S14,0,,,,1F3 2>r,,,,,1F3 2>/1F3 1>D6447400,,,800,1F3 1>D6447C00,,,800,1F3 1>D6448400,,,800,1F3 1>D6448C00,,,800,1F3 1>D6449400,,,800,1 F3 1>D6449C00,,,800,1 F3 1>D644A400,,,800,1 F3 1>D644AC00,,,800,1 F3 1>D644B400,,,800,1 F3 1>D644BC00,,,800,1 F3 1>D644C400,,,800,1 F3 1>D644CC00,,,800,1 F3 1>D644D400,,,800,1 F3 1>D644DC00,,,800,1 F3 1>D644E400,,,800,1F3 1>D644EC00,,,800,1 F3 1>D644F400,,,800,1 F3 1>D644FC00,,,800,1 F3 1>D6450400,,,800,1 F3 1>D6450C00,,,800,1 F3 1>D6451400,,,800,1 F3 1>D6451C00,,,800,1 F3 1>D6452400,,,800,1 F3 1>D6452C00,,,800,1 F3 1>D6453400,,,800,1 F3 1>D6453C00,,,800,1F3 1>D6454400,,,800,1F3 1>D6454C00,,,800,1F3 1>D6455400,,,800,1F3 1>D6455C00,,,800,1F3 1>D6456400,,,800,1F3 1>D6456C00,,,800,1F3 1>D6457400,,,800,1F3 1>D6457C00,,,800,1F3 1>D6458400,,,800,1F3 1> ................................F3 1> D64B9400,,,800,1扫描磁道前将波特率提高为460800MRT中读写磁道命令：F3 2>A0F3 2>A0 （定位0头）F3 2>S5,0,,,,1 （读写5磁道如果4 3 21 磁道那么就是S4 S3 S2 S1) F3 2>/1F3 1>D632E400,,,800,1F3 1>D632EC00,,,800,1F3 1>D632F400,,,800,1。

00000101 CR Motor life .00010000 PF Motor Encoder check error.00010001 PF Motor out of step .00010002 PF Motor over current .00010003 PF Motor in-position time-out.00010004 CR Motor Encoder check error .00010005 CR Motor out of step .00010006 CR Motor over current .00010007 CR Motor in-position time-out .00010008 Servo interrupt watchdog time-out . 00010009 System interrupt watchdog time-out . 0001000A CR axis detection error .0001000C PG axis detection error .0001000F CR Motor PWM output faulty .00010010 PF Motor PWM output faulty .00010012 CR overload (high sensitiv ity) error . 00010013 PR overload (high sensitivity) error . 0001001B Head driver (TG) temperature error . 0001001D CR servo parameter error .0001001E PF servo parameter error .00010020 CSIC reed/right error .00010022 Ink type error (setting on printer body side) . 00010023 RTC analysis error .00010025 CSIC ROM communication error . 00010026 RTC communication error .00010028 Head error .00010029 Unidentified NMI .0001002A CR ASIC ECU error .0001002B PF ASIC ECU error .0001002D Cleaning Unit work life error .0001002F 360 DPI writing time out error .00010030 Multi Sensor failure .00010031 ASF phase detection error .00010032 ASF drive switch error .00010033 Eject phase detection error .00010034 Eject movement error .00010035 Pump phase detection error .00010036 Type-B board installation error .00010037 Head thermistor error .00010038 Transistor thermistor error .00010039 PG adjustment value incorrect overwrite error . 0001003A PG adjustment value outside range error . 0001003B Cutter installation error 1 .0001003C Cutter installation error 2 .0001003D Cutter installation error 3 .00020000 NVRAM error .00020002 SDRAM error .00020003 BOOT program SUM error .00020009 Flash memory SUM error .0002000A Program load error .0002000B Internal memory shortage error . 100000E0 CPU address error (load misalignment) . 10000100 CPU address error (storage misalignment) . 10000180 CPU reserve command code exception。

系统特征错误确认需确认的错误代号会激活的报警(ALARM)灯。

错误代号划分成以下组别：∙ 组0∙ 组1∙ 组2∙ 组3∙ 组4∙ 组5∙ 组6∙ 组8∙ 组910.2 错误代码表错误代码描述确认帮助文本E002扭矩高不“Torque hight”E003编程故障、扭矩测量值可能无效不E102由于工具自锁不能拧紧不E103数字输入禁止工具正转(没拿或多拿了套筒)不E104数字输入禁止工具反转不E105Toolstalk 禁止工具反转不E106由于循环保持所以不能与拧紧不E107由于线体控制不能与拧紧，不能实现批次不E111主控制与拧紧超时不E112重复拧紧不E113达到电流极限-放弃与拧紧不E114开口扳手复位未找到是E115方向不明确E120主控制起马达自检失败是E121开口扳手自检失败是E125超时警报或扭矩丢失警报错误 MMI3000， E900-E999E100, 相关事件错误E000, 预拧紧错误通讯出错， E400-E499硬件错误，工具 E500-E599硬件错误，DC3000/MC3000 E600-E699软件错误， E800-E899错误代码以4位字符显示。

所有错误代码以E 开始以示错误，接着是3位数字，其中第一位定义为错误代码组。

所有的错误代码会传送到ToolsTalk 软件并附有短小解释。

某些错误需要用户确认。

在显示屏上会有闪烁的错误代码显示。

错误确认需按OK 键或回车键。

统计出错， E300-E399（统计错误不会在显示屏上显示，只传送到Toolstalk 。

）预拧紧出错， E000-E099相关事件出错， E100-E199用户输入错误， E200-E299E126多步拧紧操作退出E127 PVT关闭 在拧紧操作阶段驱动被关闭是E128 扳机过早释放不E129 扭矩低于目标值不E130 柱状视图扭矩关闭E131工具连接断开（扳手或电缆损坏）是E133Toolstalk禁止工具反转不E134主控制器目标输入在启动世激活不E135主控制器未从轴控制器处获得开始确认不E136 批处理完成，锁定1332430E137通过现场总线锁定工具不E138 错误的工具起动输入源（选择启动源后，只能从该输入源启动）不E139开放式协议锁定工具，通过协议锁定工具不E140插入用户ID卡释放工具不E141主控制器电流检测到扭矩波动是E142主控制器同步拧紧未同时停止E145由于启动工具的定时器锁定工具E146没有检测到工具电缆E147扭力扳手参数设置锁定工具E149拧紧合格时禁止松开功能锁定工具E150从站未响应（查从站的网络）是E151工作中参数通道不存在是E152没有可执行的程序不E153正在工作时选择了其他的工作任务不E154远程工作运行E155远程工作退出E156正在工作时网络断开不E157组工作基准控制器丢失E158选择了一个不存在的JOB号不E159选择的工作没有任何PsetE160用条码枪选择程序不E161在线控制报警1不E162在线控制报警2不E166工作中途终止不E167达到最大连续不合格拧紧数E175下次启动时所有配置将被删除E176需要 IPM 内存E177此等级RBU中没有该功能E178内存分配错误E179需要完全可配置内存E180Euchner欧确纳标识符系统只支持西门子3964R协议E181不能读出插入 euchner(欧确纳)的ID卡。