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SLI Batteries for 12 V Electric Systems General Test ConditionsPrevious issuesVW 75073: 1958-09, 1970-08, 1984-09, 1986-01, 1994-05, 1998-08, 2001-08, 2010-04ChangesThe following changes have been made compared with VW 75073: 2010-04:–Section 6 "Test sequence" and Table 3 to Table 6 revised –Section 7.3 "Exhaustive discharge test" revised–Section 7.6 "Cycles with 50% depth of discharge at (40 ± 2) °C in water bath" revised –Section 7.7 "Cycles with 17,5% depth of discharge at (27 +0-2) °C" revised –Section 7.10 "Cycles with 17,5% depth of discharge at (60 ± 3) °C" revised–Section 7.13 "Cycle test at low temperature (only for unsealed, deep-cycle batteries)" changed –Section 7.14 "Cycles with 17,5% depth of discharge on the rocker in air at (25 ± 2) °C " added –Section 9.2 "Durability under random shaking load" changed –Appendix addedContentsPageScope .........................................................................................................................3Requirements . (3)General requirements ................................................................................................3Voltage .......................................................................................................................3Terms .........................................................................................................................3Rated voltage in V ......................................................................................................3Test currents for low temperature in A as per EN and DIN . (3)122.12.233.13.2Group StandardVW 75073Issue 2012-07Class. No.:8MA10; 69110Descriptors:battery, starting, SLI battery, 12 V electric systemsVerify that you have the latest issue of the Standard before relying on it.This electronically generated Standard is authentic and valid without signature.The English translation is believed to be accurate. In case of discrepancies, the German version is alone authoritative and controlling.Page 1 of 34Confidential. All rights reserved. No part of this document may be provided to third parties or reproduced without the prior consent of the Standards Department of a Volkswagen Group member.This Standard is available to contracting parties solely via the B2B supplier platform .© Volkswagen AktiengesellschaftVWNORM-2011-08gBattery capacity in Ah ................................................................................................4Rated discharge current in A ......................................................................................4Current I 20 ACT in A .......................................................................................................4Deep-cycle battery .....................................................................................................4Maintenance-free battery (cool installation location) ..................................................4Maintenance-free battery (hot installation location) ...................................................4Sealed battery ............................................................................................................4Heat-tolerant sealed battery .......................................................................................5Battery resistant to shaking ........................................................................................5Equipment ..................................................................................................................5Electrical measuring instruments ...............................................................................5Voltmeters ..................................................................................................................5Ammeters ...................................................................................................................5Battery internal resistance measuring instrument ......................................................5Battery tester ..............................................................................................................5Thermometer ..............................................................................................................5Acid density measuring instruments ..........................................................................5Scale ..........................................................................................................................5Leak tightness testing device .....................................................................................5Pre-conditions for performing the tests ......................................................................6Sampling ....................................................................................................................6Charging .....................................................................................................................6Charging as per IU characteristic curve .....................................................................6Measurement of residual charging current and acid density ......................................6Test sequence ............................................................................................................8Electrical tests ..........................................................................................................11Capacity test ............................................................................................................11Cold start test ...........................................................................................................12Exhaustive discharge test ........................................................................................12Static current draw ...................................................................................................13Corrosion (applies only to unsealed batteries) .........................................................13Cycles with 50% depth of discharge at (40 ± 2) °C in water bath ............................14Cycles with 17,5% depth of discharge at (27 +0-2) °C ....................................................14Overcharging at constant voltage ............................................................................15Dynamic current draw ..............................................................................................16Cycles with 17,5% depth of discharge at (60 ± 3) °C ...............................................17Start/stop test ...........................................................................................................17Cell connector test ...................................................................................................18Cycle test at low temperature (only for unsealed, deep-cycle batteries) ..................19Cycles with 17,5% depth of discharge on the rocker in air at (25 ± 2) °C ...............19Freezing test ............................................................................................................20Evaluation and test results .......................................................................................20Production deviation .................................................................................................20Physical tests ...........................................................................................................20Durability under harmonic shaking load ...................................................................20General information ..................................................................................................20Test sequence ..........................................................................................................21Permissible bracing methods for the shaking test ....................................................21Durability under random shaking load ......................................................................21General information ..................................................................................................21Preparation of specimens ........................................................................................21Resonance search (22)3.33.43.53.63.73.83.93.103.1144.14.1.14.1.24.1.34.24.34.44.54.655.15.25.2.15.2.2677.17.27.37.47.57.67.77.87.97.107.117.127.137.147.1588.199.19.1.19.1.29.1.39.29.2.19.2.29.2.3Page 2VW 75073: 2012-07Impact test ................................................................................................................22Noise test .................................................................................................................22Special regulations for pure truck types ...................................................................24Applicable documents ..............................................................................................24Bibliography .............................................................................................................24Documentation .........................................................................................................25Standard test report .................................................................................................26Guideline for creating the findings for batteries .. (33)9.2.49.2.5101112Appendix A Appendix B Appendix C ScopeThis standard contains the minimum requirements and tests for new SLI batteries for commercial and industrial vehicles with 12 V or 24 V electric system voltage. This standard applies to lead-acid bat‐teries. All values refer to the rated voltage of 12 V; for a deviating rated voltage, the specified voltage values must be converted according to the number of cells.Requirements General requirementsApproval of first supply and changes as per VW 01155.For release and evaluation, further tests might be necessary, e.g., additional functional tests and road tests.These especially include tests:–of the interaction between battery and battery sensors–of the mechanical load-bearing capacity of batteries on the hydropulse test bed –in the durability road test and fleet tests –to determine component temperatures.This list is not exhaustive.VoltageIf tolerances are not specified for voltages, a tolerance of ±0,04 V applies.TermsRated voltage in VThe rated voltage is determined from U = 2,0 V multiplied by the number of cells connected in series.Test currents for low temperature in A as per EN and DINThe test currents for low temperature as per EN (DIN EN 50342-1) and DIN (DIN EN 60095-1:2000-11[1]) are two high discharge amperages that are associated with the battery type and can be used, above all, to evaluate the starting behavior at low temperatures and under given discharge conditions. They are based on test specifications as per DIN EN 50342-1.12 2.12.23 3.13.2Page 3VW 75073: 2012-07Battery capacity in AhThe battery capacity K 20 is the amount of electricity in ampere-hours (Ah) associated with a battery.The battery must be able to supply this capacity at a specified current I 20 (rated discharge current) in 20 h down to a specified discharge voltage of 10,5 V at (27 +0-2) °C.K 20 = I 20 × 20 (with K in Ah; I in A)(1)Rated discharge current in AThe rated discharge current I 20 is the discharge current that is associated with the battery capacity and that is output during the specified discharge duration of the battery. I 20 is defined by the equationI 20 = K 20/20(2)Current I 20 ACT in AThe current I 20 ACT is the discharge current that is associated with the determined ACTUAL capacity and that is output during the specified discharge duration of the battery. I 20 ACT is defined by the equa‐tionI 20 ACT = K 20 max /20(3)K 20 max is the highest capacity determined for the particular battery in the first three capacity tests as per section 6 "Test sequence".Deep-cycle batteryA battery is called a "deep-cycle" battery if the increased requirements as per section 7.6 point 4,section 7.7 point 7, section 7.10, section 7.11, and section 7.13 are fulfilled in addition to the general requirements.Maintenance-free battery (cool installation location)A battery is called a "maintenance-free battery for a cool installation location" if the total water con‐sumption (after 42 days) determined as per section 7.8 is no more than 6 g/Ah of the battery capacity.Maintenance-free battery (hot installation location)A battery is called a "maintenance-free battery for a hot installation location" if the total water con‐sumption (after 42 days) determined as per section 7.8 is no more than 3 g/Ah of the battery capacity.Sealed batteryA battery is called a "sealed" battery if the following conditions are met:–Maintenance-free for a hot installation location–Sealed leak-tight in the normal state – blow-off function through valves in the event of internalover-pressure–Leak-proof over the service life and in any position, even if the housing is damaged or the batteryis overcharged3.3 3.43.53.63.73.83.9Page 4VW 75073: 2012-07Heat-tolerant sealed batteryA battery is called a "heat-tolerant sealed" battery if all requirements as per section 3.9 are fulfilled,the total water consumption (after 84 days) determined as per section 7.8 is no more than 3 g/Ah of the battery capacity, and also the requirements as per section 7.10 and section 7.11 are fulfilled.Battery resistant to shakingA battery is called a "resistant to shaking" battery if it fulfills the additional requirements as per section 9.2.EquipmentElectrical measuring instrumentsThe measurement range of the voltmeters and ammeters used must be matched to the values to be measured.VoltmetersMeasuring instruments of class 0,5 with an internal resistance of at least 300 Ω/volt of the voltage range are used.AmmetersMeasuring instruments of class 1 are used.Battery internal resistance measuring instrumentMeasuring instruments with a resolution of 0,01 mΩ and with a measurement range of up to 3 Ω are used, e.g., Hioki model 3554 (used in the Volkswagen Group), or comparable. Documentation of the comparability to instruments used at Volkswagen must be provided.Battery testerThe standard workshop tester VAS6161 (manufactured by Midtronics) normally used in the Volks‐wagen Group must be used in service mode with the latest software version.ThermometerThermometers as per DIN 12775 – E 0,5/-30/70 and 0,5/0/100 must be used.Acid density measuring instrumentsThe reading uncertainty may be ±0,005 kg/l.ScaleThe inaccuracy of the scale for determining the water loss must be no more than ±1 g.Leak tightness testing deviceMeasuring instruments of class 0,5 must be used.3.10 3.114 4.14.1.14.1.24.1.34.24.34.44.54.6Page 5VW 75073: 2012-07Pre-conditions for performing the tests SamplingThe tests must be performed with new, untested batteries.The following applies to these batteries:–Filled and charged batteries that were manufactured no more than 100 days ago.–Breaks between the individual tests must be no longer than required by weekends or holidays.–All voltages and internal resistances must be measured directly at the terminal posts of the bat‐tery.–All tests and storage times between the tests occur at an ambient temperature of (24 ± 5) °C,unless special temperatures are prescribed in the individual tests. For tests that are performed in a water bath, the height of the water level must be (140 ± 5) mm for LN boxes and (135 ±5) mm for LBN boxes, measured from the bottom of the battery.ChargingCharging as per IU characteristic curveThe battery is charged at (27 +0-2) °C in the water bath after a capacity test, current draw test, or exhaustive discharge test for 24 h at a voltage of 16 V (table 1) and I max = 5 x I 20.For sealed batteries, the maximum charging voltage is 14,8 V a). After a cold start test, the charging time is shortened to 16 h (table 1).Table 1a)The charging voltage may be adapted to the technology following consultation with Research and Development.Measurement of residual charging current and acid densityThe residual charging current is measured:–at the end of the charging after the second cold start (charging at a voltage of 16 V (14,8 V) fora duration of 16 hours)–at the end of the charging after the cold start test after the exhaustive discharge The acid densities are measured as per the specifications in table 2.Table 25 5.15.2 5.2.15.2.2 Page 6VW 75073: 2012-07ConditionDesired acid density kg/l at 27 °C In the exhaustive discharge test after the 7-day discharge with a 10 W bulb No specificationIn the exhaustive discharge test after the charging after exhaustive dis‐chargeNo specification Before the start of "cycles with 50% depth of discharge"No specification After the end of "cycles with 50% depth of discharge"No specification Before the "cycles with 17,5% depth of discharge" test No specification After the "cycles with 17,5% depth of discharge" test No specification Before corrosion testNo specification If possible, after corrosion testNo specificationa)Max. density difference between the cells of a battery is 0,01 kg/l.Inaccessible wet batteries must be spot-drilled in order to measure the acid density. The drill holes must then be sealed leak-tight to continue the testing.Measurement of the acid density is omitted for sealed batteries and for batteries 2 and 7 as per table 3 and table 4 for unsealed batteries.The density measured at other temperatures T must be corrected as per the following formula:Density (27 °C) = reading + 0,0007 (T - 27)Page 7VW 75073: 2012-07Test sequenceThe tests are performed in the following sequence (as per table 3, table 4, table 5, and table 6). Unless otherwise stated, all tests are performed in a water bath.When selecting the specimens for the individual tests, the following order applies to the weight (light‐est to heaviest): 1 – 2 – 7 – 5 – 6 – 11 – 8 – 9 – 10 – 3 – 4.Table 3 – Test sequence for unsealed, non-deep-cycle batteriesa)May be omitted after consultation with Research and Developmentb)Usually omitted, unless otherwise agreed upon by Research and Development6 Page 8VW 75073: 2012-07Page 9VW 75073: 2012-07 Table 4 – Test sequence for unsealed, deep-cycle batteriesa)Usually omitted, unless otherwise agreed upon by Research and Developmentb)Reference sample without stratification-reducing measurec)May be omitted after consultation with Research and DevelopmentPage 10VW 75073: 2012-07Table 5 – Test sequence for sealed batteriesa)Usually omitted, unless otherwise agreed upon by Research and Developmentb)May be omitted after consultation with Research and DevelopmentTable 6 – Test sequence for heat-tolerant sealed batteriesa)Usually omitted, unless otherwise agreed upon by Research and Development b)May be omitted after consultation with Research and Development.Electrical tests Capacity testThe battery is not charged before the 1st capacity test (as per table 3, consec. no. 4, table 4, con‐sec. no. 4, table 5, consec. no. 4, and table 6, consec. no. 4).Battery 3 of table 3, table 4, table 5, and table 6 is also not charged before the initial cold start.However, the battery is charged as per section 5.2.1 after the cold start is performed.7 7.1No later than 1 week after charging as per section 5.2 is stopped, the battery is discharged at I 20.Before the start of the test, the acid temperature must be (27 ± 5) °C.The battery must be discharged in a water bath that is kept at a constant temperature of (27 +0-2) °C.The discharging must be stopped when the permissible cutoff voltage of 10,5 V is reached.After the discharging is stopped, the battery is charged as per section 5.2 (does not apply to battery no. 5 before the exhaustive discharge).Cold start testThe low-temperature aging starts at least 24 h, but at most 96 h after the charging is stopped. For cold start tests at the end of tests as per section 7.3, section 7.6, section 7.7, section 7.8, andsection 7.10, this time can be extended to a maximum of one week. The time (in hours) before the start of the low-temperature aging must be noted in the report in each case.The battery is stored in a room at a temperature of (-18 ± 1) °C until the acid temperature in a center cell has reached (-18 ± 1) °C, but for at least 16 h.Afterwards, the battery is discharged at the associated test current for low temperature as per EN for a duration of 10 s at an initial battery temperature of (-18 ± 1) °C. After a break of 10 s, the battery is discharged at the associated test current for low temperature as per DIN without interruption down to a cutoff voltage of 6 V. 10 s after the start of discharge at the test current for low temperature as per EN, the terminal voltage must be at least 7,5 V. 20 s after the start of discharge at the test current for low temperature as per DIN, the terminal voltage must be at least 9,0 V. The duration of the discharge down to 6 V at the associated test current for low temperature as per DIN must be at least 150 s - (IEN/IDIN) × 10 s.Computation of the discharge time at the test current for low temperature as per DIN using the 60 Ah 280 A DIN, 480 A EN battery as an example:Duration of the second part of the discharge down to 6 V at the test current for low temperature as per DIN:150 s - (480 A/280 A) × 10 s = 133 sAfter the cold start test ends and an electrolyte temperature of at least 0 °C is reached, the battery is charged as per section 5.2. The battery must stand in the water bath at (27 +0-2) °C for at least 2 h to ensure that the electrolyte reaches a temperature of 0 °C.Exhaustive discharge testBattery no. 5 is used; this battery is not charged after the 1st capacity test.–The battery is discharged at a temperature of (+27 +0-2) °C for a duration of 7 days with a 10 Wbulb.–Afterwards, measure the acid density in cells 2 and 5.–Charging as per section 5.2, the current draw after exhaustive discharge (current limit 5 × I 20,see section 5.2) must have at least the following (table 7) rise over time:Table 71 min 5 min 10 min Current draw after exhaustive discharge≥ 2 × I 20≥ 3 × I 20= 5 × I 207.27.3It must be recorded whether buffering was necessary for the current draw after exhaustive discharge.Buffering means that in order to start the charging unit in the first few seconds, due to the low voltage of the discharged test battery, a second battery must be connected to the first test battery so that the charging unit begins charging.–Measure the acid density in cells 2 and 5.–Capacity test as per section 7.1The capacity determined after one exhaustive discharge must be at least 90% of the battery capacity.–Charging as per section 5.2–Cold start as per section 7.2The cold start discharging time determined after one exhaustive discharge must be recorded but the requirement as per section 7.2 does not apply.–Charging as per section 5.2The residual charging current after the last charge and the charging amount with which the battery is charged during recharging after exhaustive discharge must be documented in the report. For sealed batteries, the charging amount with which the battery is charged must be no more than twice the actual capacity after exhaustive discharge.Following the exhaustive discharge test, the "Cycles with 50% depth of discharge" test is performed as per section 7.6.Static current drawBattery no. 4 is discharged for 5 h at 2 I 20 ACT , which was determined in the test sequence section 6.Afterwards, the battery is cooled in a room at a temperature of (0 ±1) °C at least until the acid tem‐perature of a center cell has reached (0 ± 1) °C.Immediately afterwards, the battery is charged for 10 minutes at (14,4 ± 0,05) V in air at 23 °C to 25 °C .After 10 minutes, the charging current must be at least 5 × I 20. The maximum current supply is 100 A.The charging amount with which the battery is charged must be recorded.Then, the battery is charged as per section 5.2.Corrosion (applies only to unsealed batteries)NOTE 1 Warning! The battery can explode as a result of the consequences of corrosion!This test is performed with battery no. 1 after the capacity test (as per section 7.1) and charging as per section 5.2. Before the test is started, the battery stands for at least 24 h for electrolyte leveling due to rising gas bubbles. The standing time must be noted in the report.1.Sution out electrolyte so that the electrolyte level in all cells is 1 cm below the upper plate edge.The electrolyte is suctioned out from above down to the level to be set. Electrolyte is first suc‐tioned out at the start of the standing time. The level must be checked again on the next day and adjusted if necessary. Afterwards, weigh the outwardly dry battery and measure the acid density in all cells, the internal resistance, and the reaction of the battery tester. Before the test, also mark the acid level on the outside of the box and document this with a photograph.2.Charge the battery at 14,4 V and I max = 2 × I 20 in the water bath at (60 ± 3) °C for two weeks. Thewater level of the water bath is between the max. and min. markings of the acid level.3.Discharge the battery at 1 × I 20 to 12,5 V.7.47.54.Let the battery stand in the water bath at (60 ± 3) °C for three weeks.5.Charge the battery at 14,4 V and 2 × I 20 in the water bath at (60 ± 3) °C for three weeks.6.Let the battery cool down. Weigh the outwardly dry battery, enter the weight loss in the report,measure the acid density in all cells, the internal resistance, and the reaction of the battery tester.Also mark the electrolyte level on the outside of the box and document this with a photograph.Open the battery carefully (remove plugs). Explosion hazard!7.Findings after opening the battery: the corrosion and the growth of the positive electrode (incl.dishing) are evaluated. Excessive damage leads to rejection. More precise criteria will be spec‐ified at a later time. For the negative electrodes, the corrosion of the lugs and bridges in particular is evaluated. Significant corrosion or interruptions lead to rejection.Cycles with 50% depth of discharge at (40 ± 2) °C in water bathThe test must be performed within one week of the exhaustive discharge test as per section 7.3.The test consists of the following:1.Weigh the outwardly dry battery and measure the acid density in all cells, the internal resistance,and the reaction of the battery tester.2.Discharge for 2 h at 5 × I 20, switch-off criterion: battery voltage ≤10 V.3.Charge for 5 h at (16 ± 0,1) V [sealed battery (14,4 ± 0,05) V 1), deep-cycle unsealed battery (15,6± 0,05) V 1)].4.Perform points 1 and 2 a total of 120 times; the test must be performed 270 times for deep-cycle unsealed batteries and 360 times for deep-cycle sealed batteries without reaching the switch-off criterion for both types of battery.5.3-day standing time (72 hours) at (40 ± 2) °C.6.Measure the internal resistance and reaction of the battery tester.Weigh the battery, note the weight loss in the report, measure the acid density, and perform a cold start as per section 7.2 without prior recharging. 10 s after the start of discharge at the test current for low temperature as per EN, the terminal voltage must be at least 6,0 V. 20 s after the start of discharge at the test current for low temperature as per DIN, the terminal voltage must be at least 7,2 V. Afterwards, the battery is recharged for 5 h as per section 7.6 point 3.Then, an OK/not OK evaluation is performed after opening the battery.Water must not be added during the entire test.Cycles with 17,5% depth of discharge at (27 +0-2) °C1.The test must be performed within one week of the capacity test as per section 7.1.2.Weigh the outwardly dry battery and measure the acid density in all cells, the internal resistance,and the reaction of the battery tester.3.Discharge for 2,5 h with 4 × I 20 at (27 +0-2) °C. Switch-off criterion: battery voltage ≤10 V, sealed batteries 11,5 V.4.Perform the following cycles a total of 85 times at (27 +0-2) °C:Charge for 40 minutes at 7 × I 20 and (14,4 ± 0,05) V,Discharge for 30 minutes at 7 × I 20.Switch-off criterion: battery voltage ≤ 10 V, sealed batteries 11,5 V.7.67.7 1)The charging voltage may be adapted to the technology following consultation with Research and Development.。

HEAVY-DUTY INDUSTRIAL SWITCHESSINgLE oR DUAL SETPoINT,PSW-700 SeriesDual external setpoint calibrationadjustment PSW-700 Series pressure switches are built for the rugged industrial setting. The internal setpoints allow adjustments while keeping the electrical component isolated from the environment. Both the internal and external setpoints have a range scale, allowing fast, easy setup.PSW-722, ±10 inH 2O range, shown much smaller than actual size.U Division 1 RatingU Single or Dual Setpoints, Tamper ResistantU Heavy-Duty Enclosure U Rated NEMA 4X, 7, 9 (IP66)U Terminal Block Wiring U High-TemperatureOperation to 200°C (392°F) Process Temperature (Stainless Steel Model Only)PSW-710, 715-7171/4 NPT1/4 NPT (F)PSW-731-7351/2 NPTPSW-702-704, 708, 709SPECIFICATIONSApprovals: UL listed; Class I, Division 1 and 2, Groups B, C and D; Class II, Groups E, F and G; Class III Repeatability: ±1% range Process Temperature:Stainless Steel: -57 to 204°C (-70 to 400°F)Brass: -40 to 149°C (-40 to 300°F) Buna-N: -23 to 93°C (-10 to 200°F)Ambient Temperature:-50 to 71°C (-58 to 160°F), except for models 703 to 705, which are -18 to 71°C (0 to 160°F). Setpoint typically shifts less than 1% of range for a 28°C (50°F) ambient temperature change.Shock: Setpoint repeats after 15 g, 10 ms durationVibration: Setpoint repeats after 2.5 g at 5 to 500 HzOutput: 1 SPDT or 2 SPDT 15 A 125/250/480 VacEnclosure: Low copper-cast epoxy-coated aluminumElectrical Connection: 3⁄4 NPT conduit; internal screw terminals Dimensions:psi Ranges:230 (max) H x 125 W x 108 mm D (9 x 4.9 x 4.3") H 2O Ranges:W and D = 153 mm (6") Weight: Approx. 1.7 kg (4 lb)PSW-721-72INDUSTRIAL SWITCHES PSW-707, 0 to 500 psirange, shown smallerthan actual size。

Z-Active™Differential Probe FamilyP7313•P7380A •P7360A •P7340A DataSheetFeatures &Bene fitsSignal Fidelity>12.5GHz Bandwidth (P7313,Typical)>8.0GHz Bandwidth (P7380A,Typical)>6.0GHz Bandwidth (P7360A,Typical)>4.0GHz Bandwidth (P7340A,Typical)Extended Linear Dynamic Range 1.25V p-p at 5x Attenuation (P7313)4V p-p at 25x Attenuation (P7313)2V p-p at 5x Attenuation (P7380A,P7360A,P7340A)5V p-p at 25x Attenuation (P7380A,P7360A,P7340A)Low Probe Loading DC Input Resistance 100k ΩDifferential 50k ΩSingle Ended AC LoadingZ min >200Ωout to 10GHz (P7313)Z min >290Ω,4GHz to 8GHz (P7380A,P7360A,P7340A)VersatilityMake Differential or Single-ended (Ground-referenced)Measurements*1Solder-down CapabilityHandheld Probing with Variable Spacing and Compliance Fixtured Probing Interchangeable Tip-Clip™Assemblies Connect to a Variety of Devices Economical TekConnect ®InterfaceApplicationsExamples Include,but are not Limited To:PCI-Express I and II,Serial ATA II,USB 2.0,DDRII,DDRIII,Fireware 1394b,Rambus,XAUI*1For details,please see application note 60W-18344-0,“Making Single-ended Measurements with DifferentialProbes.”1981Data SheetZ-Active™Probing Architecture Leads the Way for High-speed Probing Applications Tektronix has created a revolutionary Z-Active probe architecture that sets the industry benchmark for signalfidelity.Tektronix active probe architecture preserves high bandwidth while providing improved connectivity with low loading.The Z-Active architecture is a hybrid approach composed of a distributed attenuator topology feeding an active probe amplifier.The Z-Active probes use a tiny passive probe tip element that is separate from the amplifier,extending the usable reach of the probe.In traditional active probes,adding this much length can introduce signalfidelity problems.However this architecture maintains high DC input resistance and presents a higher AC impedance than previous probe architectures.It accomplishes this while providing significant length between the probe body and the probe attachment point to the DUT.This architecture provides the best of both worlds:high DC impedance like existing active probes and the stable high-frequency loading of Z0probes.Signal FidelityYou can be confident in the signalfidelity of your measurements because the Z-Active architecture provides:High BandwidthExcellent Step ResponseLow LoadingHigh CMRRExtended Linear Dynamic RangeExtended Linear Dynamic RangeMany of today’s logic signals and serial bus signals require the capabilityto measure up to several volts peak to peak.These voltage levels may easily be viewed with the Z-Active architecture probes(P7380A,P7360A, and P7340A)with the extended linear dynamic range.With a2.0V p-p linear dynamic input range at the5x attenuation setting,you can accurately measure DDR II and III,Firewire1394b,and PCI-Express I and II signals at reduced noise levels.In addition the25x attenuation setting’s linear dynamic input voltage range can be used up to5.0V p-p for accessing even larger signal swings found during transition times.ConnectivityThe Z-Active probe design allows the probe to easily switch between soldered,handheld,orfixtured applications.This family of probes uses Tip-Clip™assemblies,an interchangeable probe tip system that enables customers to configure their probe with the optimal tip for their application.These detachable assemblies make it possible to replace a tip for a fraction of the cost formerly associated with such hardware changes.The several lengths and variable spacing of the assemblies provideflexibility for adapting to vias and other test points of differing sizes.With Tektronix Tip-Clip assemblies,Monday’s solder-in probe can become Tuesday’s handheld tool,simply by switching tips. ValueThe combination of the Z-Active architecture and the Tip-Clip assemblies provide superior signalfidelity at a cost-effective price.The inexpensive Tip-Clip assemblies enable full-performance solder connections at a very low price per connection.Over the life of a probe this can add up to significant savings in the cost of operation.Performance You Can Count OnDepend on Tektronix to provide you with performance you can count on.In addition to industry-leading service and support,this product comes backed by a one-year warranty as standard.Z-Active™Differential Probe Family—P7313•P7380A•P7360A•P7340ACharacteristicsCharacteristic P7340A P7360A P7380A P7313Bandwidth(Typical)>4GHz>6GHz>8GHz>12.5GHzRise Time(10%-90%)(Guaranteed)<100ps<70ps<55ps<40psRise Time(20%-80%)(Typical)<70ps<50ps<35ps<25psAttenuation5x or25x,user selectableDifferential Input Range±1.0V(5x)±2.5V(25x)±0.625V(5x)±2.0V(25x)Linearity Error for Differential Input Dynamic Range(Typical)±0.5%for-0.5V to+0.5V(5x)±1.0%for-0.75V to+0.75V(5x)±2.0%for-1.0V to+1.0V(5x)±0.5%for-1.5V to+1.5V(25x)±1.0%for-2.5V to+2.5V(25x)±2.0%for-3.0V to+3.0V(25x)±0.25%for-0.5V to+0.5V(5x)±0.75%for-0.625V to+0.625V(5x)±0.5%for-1.6V to+1.6V(25x)±1.0%for-2.0V to+2.0V(25x)Operating Voltage Window+5.0V to-3.0V+4.0V to-3.0V Offset Voltage Range+4.0V to-3.0VDC Input Resistance100kΩAC Loading(Differential Z min)>290Ω>200ΩNoise<31nV/√Hz(5x)<75nV/√Hz(25x)CMRR>50dB at1MHz>35dB at1GHz>20dB at4GHz >50dB at1MHz>35dB at1GHz>20dB at6GHz>50dB at1MHz>35dB at1GHz>20dB at8GHz>50dB at1MHz>35dB at1GHz>20dB at6GHz>15dB at12.5GHzNondestructive Input Range±15VInterface TekConnect®Cable Length 1.5m 1.5m 1.2m 1.2m Ordering InformationP7313>12.5GHz Z-Active Differential Probe for TekConnect®Interface. P7380A>8.0GHz Z-Active Differential Probe for TekConnect®Interface.P7360A>6.0GHz Z-Active Differential Probe for TekConnect®Interface.P7340A>4.0GHz Z-Active Differential Probe for TekConnect®Interface.All Include:One-year warranty,plus see Standard Accessories table.3Data SheetStandard AccessoriesDescriptionP7340AP7360AP7380AP7313Reorder Part NumberPouch,Nylon Carrying Case with Inserts1each 1each 1each 1each 016-1952-xx Qty 1Accessory Performance Summary and Reorder Sheet1each 1each 1each 1each 001-1389-xx Qty 1020-2640-xx Qty 1–Opt.L0020-2648-xx Qty 1–Opt.L5User Manual -Printed.Includes Reply Card and CD 1each1each1each1each040-2649-xx Qty 1–Opt.L7BNC (M)-to-Minigrabber Adapter 1each 1each 1each 1each 013-0342-xx Qty 1Anti-static Wrist Strap 1each 1each 1each 1each 006-3415-xx Qty 1Magnifying Glasses 1each 1each 1each 1each 378-0486-xx Qty 1Calibration Data Report 1each 1each 1each 1each Opt.D1Handheld Probe Adapter 1each 1each 1each1each 015-0717-xx 1eachP7313:020-2636-xx 1eachP7380A:020-2557-xx 1eachP7360A:020-2690-xx Accessory Box and Contents1each P7340A:020-2690-xx Attachment Kit1each 1each 1each 1each 016-1953-xx Qty 1Velcro Fastening Strap 10each 10each 10each 10each –Velcro Fastening Dots 10each 10each 10each 10each –Adhesive Tip-Clip Tape*2(Strip of 10)3each 3each 3each 3each –Color Band Kit (2ea.of 5colors)1each 1each 1each 1each 016-1948-xx Qty 1Short Flex,Small Resistor Tip-Clip Assembly 2each 2each 3each 3each 020-2600-xx Qty 10Medium Flex,Small Resistor Tip-Clip Assembly 2each 2each 3each 3each 020-2602-xx Qty 10Long Flex,Small Resistor Tip-Clip Assembly 2each 2each 3each 3each 020-2604-xx Qty 10Variable Spacing Tip-Clip Kit 3each 3each 3each 3each 020-2596-xx (Kit of 3)Square Pin Adapter Tip-Clip 1each 1each 1each 1each 020-2701-xx (Kit of 3)Tip-Clip Ejector*23each 3each 3each 3each –020-2639-xx Qty 10HBW Straight Flex Tip-Clip Assembly –––3each020-2657-xx Qty 5020-2638-xx Qty 10HBW Right-Angle Flex Tip-Clip Assembly –––3each 020-2656-xx Qty 5Wire Replacement Kit–––1each 020-2644-xx Qty 1Short Flex,Large Resistor 1/8W Tip-Clip Assembly––3each –020-2601-xx Qty 10Long Flex,Large Resistor 1/8W Tip-Clip Assembly––3each –020-2605-xx Qty 10Medium Flex,Large Resistor 1/8W Tip-Clip Assembly2each2each3each–020-2603-xx Qty 10*2Tip-Clip Ejectors and Tip-Clip Tape are shipped standard with the 020-xxxx-xx Tip-Clip Assembly Kits.Recommended AccessoriesDescriptionP7360P7380P7313Part NumberProbe Positioner Yes Yes Yes PPM100Probe PositionerYes Yes Yes PPM203B PPM203B,PPM100Adapter Fixture Yes Yes Yes 013-0339-xx P7340A:067-0419-xx P7360A:067-0419-xx P7380A:067-0419-xx Calibration Fixture Yes Yes YesP7313:067-1616-xxDSA8200Series TekConnect ®Probe Interface Yes Yes Yes 80A03Deskew FixtureYes Yes Yes 067-1586-xx Real-time Spectrum Analyzer TekConnect Probe AdapterYes Yes YesRTPA2AZ-Active™Differential Probe Family—P7313•P7380A•P7360A•P7340AService OptionsOpt.CA1–Single Calibration or Functional Verification.Opt.C3–Calibration Service3Years.Opt.C5–Calibration Service5Years.Opt.D3–Calibration Data Report3Years(with Opt.C3).Opt.D5–Calibration Data Report5Years(with Opt.C5).Opt.G3–Complete Care3Years(includes loaner,scheduled calibration and more). P7360A,P7380A onlyOpt.G5–Complete Care5Years(includes loaner,scheduled calibration and more). P7360A,P7380A onlyOpt.R3–Repair Service3Years.Opt.R5–Repair Service5Years.Language OptionsOpt.L0–English Manual.Opt.L5–Japanese Manual.Opt.L7–Simplified Chinese Manual.Additional Service Products Available During Warranty (DW)or Post Warranty(PW)P7313-CA1–Single Calibration or Functional Verification.P7313-R1PW–Repair Service Coverage1-year Post Warranty.P7313-R2PW–Repair Service Coverage2-year Post Warranty.P7313-R3DW–Repair Service Coverage3Years(includes product warranty period); 3-year period starts at time of customer instrument purchase.P7313-R5DW–Repair Service Coverage5Years(includes product warranty period); 5-year period starts at time of customer instrument purchase.P7340A-CA1–Single Calibration or Functional Verification.P7340A-R1PW–Repair Service Coverage1-year Post Warranty.P7340A-R2PW–Repair Service Coverage2-year Post Warranty.P7340A-R3DW–Repair Service Coverage3Years(includes product warranty period);3-year period starts at time of customer instrument purchase.P7340A-R5DW–Repair Service Coverage5Years(includes product warranty period);5-year period starts at time of customer instrument purchase.P7360A-CA1–Single Calibration or Functional Verification.P7360A-R1PW–Repair Service Coverage1-year Post Warranty.P7360A-R2PW–Repair Service Coverage2-year Post Warranty.P7360A-R3DW–Repair Service Coverage3Years(includes product warranty period);3-year period starts at time of customer instrument purchase.P7360A-R5DW–Repair Service Coverage5Years(includes product warranty period);5-year period starts at time of customer instrument purchase.P7380A-CA1–Single Calibration or Functional Verification.P7380A-R1PW–Repair Service Coverage1-year Post Warranty.P7380A-R2PW–Repair Service Coverage2-year Post Warranty.P7380A-R3DW–Repair Service Coverage3Years(includes product warranty period);3-year period starts at time of customer instrument purchase.P7380A-R5DW–Repair Service Coverage5Years(includes product warranty period);5-year period starts at time of customer instrumentpurchase.Tektronix is registered to ISO9001and ISO14001by SRI Quality SystemRegistrar.Product(s)complies with IEEE Standard488.1-1987,RS-232-C,and with TektronixStandard Codes and Formats.5Data SheetZ-Active™Differential Probe Family—P7313•P7380A•P7360A•P7340A7Data Sheet Contact Tektronix:ASEAN/Australasia(65)63563900Austria0080022554835*Balkans,Israel,South Africa and other ISE Countries+41526753777Belgium0080022554835*Brazil+55(11)37597627Canada180********Central East Europe and the Baltics+41526753777Central Europe&Greece+41526753777Denmark+4580881401Finland+41526753777France0080022554835*Germany0080022554835*Hong Kong4008205835India0008006501835Italy0080022554835*Japan81(3)67143010Luxembourg+41526753777Mexico,Central/South America&Caribbean52(55)56045090Middle East,Asia,and North Africa+41526753777The Netherlands0080022554835*Norway80016098People’s Republic of China4008205835Poland+41526753777Portugal800812370Republic of Korea00180082552835Russia&CIS+7(495)7484900South Africa+41526753777Spain0080022554835*Sweden0080022554835*Switzerland0080022554835*Taiwan886(2)27229622United Kingdom&Ireland0080022554835*USA180*********European toll-free number.If not accessible,call:+41526753777Updated10February2011For Further Information.Tektronix maintains a comprehensive,constantly expandingcollection of application notes,technical briefs and other resources to help engineers workingon the cutting edge of technology.Please visit Copyright©Tektronix,Inc.All rights reserved.Tektronix products are covered by U.S.and foreign patents,issued and rmation in this publication supersedes that in all previously published material.Specification and price change privileges reserved.TEKTRONIX and TEK are registered trademarks ofTektronix,Inc.All other trade names referenced are the service marks,trademarks,or registered trademarksof their respective companies.02Oct201151W-17891-12。

Your success is our futureSulzer Textil P7300hp Projectile Weaving Machine –Top performance and versatility in fabric production22000-02022002-01462000-0138The P7300hp high-performance projectile weaving machine: increase your competitive advantageWith the Sulzer TextilP7300hp you can fulfil your customers’ varyingrequirements precisely and individually. The mature projectile weft insertion technology is suitable for any weft material: spun yarns made of natural and manmade fibres, filaments,The P7300hp is a high-performance, all-purpose projectile weaving machine. Compared to the proven P7300, its performance is up to twenty per cent higher. Optimized motion sequences and direct projectile acceleration with thrust shoe result in a maximum weft insertion rate of 1570 m/min.or tapes. Whether weaving them to simple standard fabrics, fashion materials or wide, heavy technical textiles, the P7300hp is in its element.For decades, projectile weav-ing machines have been used to produce countless technical textiles, from the finest filter fabrics to densely woven and tear-resistant special fabrics for balloons and even ultra-heavycoating fabrics – all in out-standing quality.Denim fabrics are produced worldwide and withgreat success on projectile weaving machines. In the production of fabrics from polypropylene tapes, for Big Bags,geotextiles or agrotextiles,the projectile weaving machine excels withunparalleled economy andquality.32001-00809094-0161Cost-efficient and geared to your needsThe perfect interaction of a technologically mature design and cutting-edge computer technology puts the P7300hp in a class of its own. Its versatility and fast adaptability make it your company’s new success factor.Curtains and drapes inlarge widths can be woven best and most easily on the P7300hp .You can only gain from the multi-facetted benefits of the P7300hp :•lowest specific power consumption of all weaving systems•tucked selvedges withoutcostly raw material wastage•quick warp and style changing •low spare parts consumption and low-maintenance operation•super-easy operation combined with high reliability•oil bath-immersed,practically maintenance-free sub-units.The P7300hp combines top productivity – thanks to quick style changing, easy programming and high speed – with outstanding reliability.On models with large working widths, its efficien-cy is further increased by its ability to weave several fabric runs of the same or different widths simultane-ously. As a result, the maxi-mum weft insertion rate is attained at low machine rpm. That reduces machine wear and building stresses,lowers space requirementsand helps save electricity.42004-00542002-00982004-0103Projectile weft insertion –reliable and controlledThe weft is guided in a controlled manner in every phase of weft insertion: from weft transfer to the projectile, through insertion into the shed, to beat-up.Worldwide, there are mil-lions of projectiles in operation 24 hours a day The projectiles grip reliably a wide variety of threads,tapes or monofilaments and insert them in the shed.Reflecting the varying requirements for different weft yarns, projectile grip-pers with various clamping forces and surface areas are available. One outstand-ing feature of projectile technology is that the weft is inserted without central transfer, i.e. withoutadditional acceleration and braking. With this unique insertion technology,the P7300hp inserts all weft yarns in a controlled manner and with lowyarn strain, thus helping to ensure maximum reliability in the production of quality fabrics.The picking lever with the thrust shoe for directacceleration plays a key role in achieving the high weft insertion rate.The electronic warp let-off control guarantees constant warp tension frombeginning to end of the warp.Optionally, the P7300hp projectile weaving machine can be equipped with a control system for two, four or six weft colours.Unique weaving widths up to 540 cmThe P7300hp is available in nine working widths, from 190 cm to 540 cm. It is the only weaving machine for which 540 cm is a standard width. This has crucial advantages in the produc-tion of technical textiles.For instance, it enables agro- and geotextiles to be produced in large widths so that fewer seams are required.Minimizing yarn wastage –every selvedge the way you need itIn both single- and multi-panel weaving, everyselvedge can be tucked by standard or intermediate tucking units. The width of the tucked selvedges can be set from 18 to 25 mm and even to 35 mm. Accurate weft length measurement ensures that there is no yarn wastage. Instead of tucking units, the P7300hp can be equipped with devices for producing leno or melted selvedges. In the case of leno selvedges the Selvedge Saver eliminates auxiliary selvedges, thus economizing warp and weft yarn – a saving thattranslates into hard cash.52001-00572004-0072No compromises on fabric qualityIn developing the P7300hp , top fabric quality was our paramount goal. We achieved it with a new shed geometry.Premium fabrics,flawless qualityThe interplay of shed for-mation and warp and weft run is crucial for a flawless appearance of the cloth. In the P7300hp this principle has beenconsistently applied. By entering just a few data at the terminal, the cloth take-up, shed levelling and warp let-off are optimally coordinated. In this waysensor systems. A variety of back rest roller and cloth take-up systems are avail-able to suit the density and type of the fabric being woven. The weft density is adjustable in steps of 0.1pick per cm.No limits to fabric patterning A tappet motion with up to 14 heald shafts or an elec-tronically controlled dobby for a maximum of 18 heald shafts can be fitted for shed formation.In combination with the colour selector, which can handle up to 6 weft colours,there are practically no re-strictions on the designer's imagination.Perfect control of warptension is achieved with the new force sensors on the fabric support, where fabric quality is decided. Thisconfiguration is suitable for both warp tensioner and whip roller systems.A cloth take-up with a take-up and press roller isstandard equipment on the P7300hp . The floating take-up roller (photo) ensures reliable take-up even of heavy fabrics.starting marks are reliably and effectively avoided,even with delicate fabrics.Warp let-off and clothtakeup are electronicallycontrolled. With wideweaving machines or when using two half warp beamsthe machine is equippedwith two warp let-offdevices. The warp tensionof each warp let-off iscontrolled by separate624-6Projectile technology for top resultsGeared to the future, with mature mechanical systems and the latest computer technology, the P7300hp fulfils the requirements of today’s and tomorrow’s weaving rooms.The P7300hp helps ensure high productivity, user-friendly operation and high fabric quality. The machine’s modular design means that it can be adapted to meet future needs at any time. So even in the long term it remains a sound invest-ment.79099-0065The Sulzer Textil P7300hp produces fabrics in supreme quality, from all raw materials and for all applications.With a weft insertion rate of up to 1570 m/min it isoutstandingly cost-efficient.82004-00102001-00162001-00562003-0077The weaving machine for tomorrow’s needsThe versatility of the P7300hp is clear – in itsequipment and in the many optional extras available.With accessories tailored to the application it can be customized to meet your exact needs.With the P7300hp you are investing in a future-oriented, upgradeableweaving system. Thanks to its modular design, the machine can be adapted at low cost to meet new requirements. Thus it is a machine that can “grow”with your customers’ needs.Expanding the colourselector from two to four or even six weft colours is just as simple as switch-ing from tappet motion to dobby for shed formation.With the new machine-coupled pick findingfunction, operation of the weaving machine has been substantially improved.The P7300hp can be equip-ped with tappet motions for four to 14 heald shafts.The built-in levelling device facilitates operation.Whether equipped with a dobby for up to 18 shafts or a tappet motion for up to 14shafts, setting of the shed isquick and easy.92004-0080The P7300hp fulfils thehighest quality standards in the production of high-quality jacquard fabrics.Maintenance costs minimized –benefit maximizedIn servicing and mainte-nance, the P7300hp sets new standards. Substan-tially longer servicing and oil change intervals reflect the machine’s outstanding reliability and cost-efficiency. The reduced number of different lubri-cants saves costs through simplified logistics. All joints in the shaft drive have permanently lubri-cated ball bearings.The lifting levers are lubri-cated with grease. The new casing prevents accumu-lation of dust and is easy toLow-maintenance shaft drives with permanently lubricated ball bearingsbring an additional benefit –high flexibility for quick and easy style changes.clean. Practical mechanical and electronic safety com-ponents provide maximum protection for operatingpersonnel.1020040-07520040-07620040-0772004-0095-1Integration in networks to optimize the weaving processCorporate integration in local and global networks is also a major challenge in the textile industry.Sultex’s answer: state-of-the-art control systems architecture in its weaving machines.Reacting and supplying fast while maintaining high fabric quality are theessential preconditions for gaining advantages in the marketplace. In order to satisfy these demanding criteria the new projectile weaving machine has been equipped with a ground-breaking weaving machine control system.In the P7300hp , latest-generation microprocessors control, monitor and regu-late all major machine functions, thus ensuring consistently high quality in the weaving process.A touch-screen terminal is the clear, user-friendly man-machine interface.This user interface is based on Internet browsertechnology: the P7300hp thus anticipates the future of the textile industry.They include:•automatic adjustment of the weft detector•optimal adjustment of the projectile brake•semi-automatic warppull-through with synchronized drives•extended statistical functions •simple, accurate diagnoses•additional help functions.Besides machineparameters and pattern data which can be pro-grammed at the terminal or transferred viaproduction management systems and memory cards,statistical, help and diagnosis functions are available to simplify operation.Maximum user-friendliness and pioneering browser technology – twocharacteristic features of the terminal on the newprojectile weaving machine.Thanks to ergonomically arranged keys with clear,easy-to-understand symbols,operation of the P7300hpis simplicity itself.112004-0074-13World-class weaving machines –worldwide after sales service tailored to your needsProject consultingIf desired, our experts will draw up plans for optimal positioning of your weaving machines, and advise you on the modernization of an existing production facility or the planning of a new one.Production economics Our broad-basedknowledge of weaving processes is a safe founda-tion for investment and profitability analyses on any scale. The results are a dependable guide for rational investment decisions reflecting a genuine need.Weaving trialsOur Textile Centres inSwitzerland, Japan and the USA make the large body of weaving knowledge ob-tained from research,development and pro-cessing available to you.At Sultex, you can test any yarn on any machine you want. The results will guide you to the most suitable weaving system.Training Correct training is crucial for optimal utilization of our weaving systems. We train your operating personnel on the spot at your facility, in special courses at Sultex, or at one of the training centres we operate around the world.Besides the basic courses we offer, we can collaborate with you to develop training concepts to suit your organization or to meet other specific puter Based Training Sultex’s Computer Based Training is the key to independent, on-the-spot basic and further training.Based on the “learning on the job” principle, it teaches how to carry out settings,adjustments and checks, via clear, easy-to-understand videos, animations and illustrations.With regard to both content and method the course is professionally designed and makes learning a pleasure.AVANTI services / Textile Technical Consulting Increase the efficiency of your weaving mill and strengthen your position in the market. Sultex can assist you by running and maintaining your facility for you, partially or completely.Tailor-made options are available for the entire production process from warping to weaving, on request with guarantees according to your requirements.Our experts from Textile Technical Consulting can provide professional support in developing new fabrics and optimizing entire production processes.In this way you can achieve optimal fabric quality and ensure maximum cost-efficiency for your facility.Customer Support Services Supplying you quickly and reliably with spare parts,components andaccessories is one of the most important servicesoffered by Sultex. With “ELSPACEnet” (Electronic Spare Part Catalogue via Internet) and “EDOSnet”(Electronic Direct Ordering System via Internet), our spare parts logistics are continuously adapted to customers’ and market requirements, thus ensuring fast,comprehensive availability and supply.Upgrading Thanks to their modular design, our weavingmachines can be upgradedat any time to meet changing market require-ments. Our specialists will be glad to advise you.Based on close customer contacts, Sultex ensures that support for its partners and customers continues after they purchase their weaving machines. Sultex service is not limited to merely commissioning the machines. It also ensures that they remain fully functional and available throughout their service lives, to give the usercomplete satisfaction.Your success is our future24-19-2995-984PrintedinSwitzerlande/35.6.9BodSultex LimitedHead OfficeCH-8630 Ruti ZH, SwitzerlandPhone+41 (0)55 250 21 21Fax+41 (0)55 250 21 01******************Outstanding featuresof the Sulzer Textil P7300hp:•uncompromisingimplementation of customers’requirements•high flexibility for rapid responseto changing market trends•logical technological concept forexcellent fabric quality•designed for exceptionally cost-efficient production of a broad range of fabrics•low operating costs thanks to low service requirement.Specifications subject tochange without notice.。

PRODUCT DATA31-00075-01SmartVFD COMPACTGENERALSmartVFD COMP ACT variable frequency drives provide step less speed control for various applications:•Pumps •Fans•Compressors •Conveyors, etc.FEATURES•Compact size - saves space in your equipment cabinet •Flexible side-by-side mounting with screws or DIN-rail as standard •Single rating suitable for both pump and fan or machine applications •Maximum ambient temperature: + 122 °F •Integrated RFI-filters•Wide input and output connection possibilities •Configurable inputs and outputs •30 second Start-Up Wizard•Easy “keypad to remote” change with 1 button •Parameter upload/download even without main power to the drive with HVFDCABLE accessory •Quiet motor operation with 4 kHz switching frequency•Overtemperature ride-through •Power ride-through •Automatic restart •Integrated PI controller •Optional NEMA 1 enclosureSPECIFICATIONSMains ConnectionInput voltage U in:115Vac, -15%...+10% 1~208…240 Vac (-15…+10%), 1~208…240 Vac (-15…+10%), 3~380…480 Vac (-15…+10%), 3~600Vac (-15…+10%), 3~Input frequency: 45…66 HzConnection to mains : Once per minute or lessBrake chopper:Available on MI2 and MI3, with 3-phase units: 100% *TN with brake option; 30% *TN without brake option.Motor ConnectionOutput voltage: 0 - U in , 3~Output current:I N : Continuous output current with max. +50 °C ambient tem-perature, overloadability 1.5 x I N (1min/10min)Starting current: 2 x I N 2s/20s Output frequency: 0…320 Hz Frequency resolution: 0.01 HzControl CharacteristicsControl method:Frequency Control U/f Open Loop Sensorless Vector Control Switching frequency: 1.5...16 kHz; default 6 kHz Field weakening point: 30…320 Hz Acceleration time:0.1…3000 secSMARTVFD COMP ACT31-00075—012Deceleration time: 0.1…3000 secBraking torque:100% *TN with brake option (only in 3~ drives sizes MI2 and MI3)30%*TN without brake optionAmbient ConditionsOperating temperature:+ 14 °F (-10 °C) (no frost)…+ 104/122 °F(40/50 °C) for 115 Vac, 460 Vac and 600 Vac and + 104 °F (40 °C), for 208 Vac/230 Vac, rated loadability I N Storage temperature: -40 °F (-40 °C)…+158 °F (+70 °C)Air quality :Chemical vapors:IEC 721-3-3, unit in operation, class 3C2Mechanical particles:IEC 721-3-3, unit in operation, class 3S2Altitude:100% load capacity (no derating) up to 1000 m1% derating for each 100 m above 1000 m; max. 2000 m Relative humidity:0…95% RH, non-condensing, non-corrosive, no dripping water Vibration: 3...150 HzEN50178, EN60068-2-6:Displacement amplitude 1(peak) mm at 3...15.8 Hz Max acceleration amplitude 1 g at 15.8...150 Hz ShockEN50178, IEC 68-2-27:UPS Drop T est (for applicable UPS weights)Storage and shipping: max 15 g, 11 ms (in package)Enclosure class: Open chassis, NEMA 1 kit optionalElectro Magnetic Compatibility (EMC)Immunity:Complies with EN50082-1, -2, EN61800-3, Category C2Emissions:115V: Complies with EMC category C4230V: Complies with EMC category C2; with an internal RFI filter400V: Complies with EMC category C2; with an internal RFI filter600V: Complies with EMC category C4All: No EMC emission protection (Honeywell level N): Without RFI filterSafety:For safety: CB, CE, UL, cULFor EMC: CE, CB, c-tick(see unit nameplate for more detailed approvals)Control connectionsAnalog input voltage:0...+10V , Ri = 200k Ω (min), Resolution 10 bit, accuracy ±1%, electrically isolated Analog input current:0(4)…20 mA, Ri = 200Ω differential resolution 0.1%, accuracy ±1%, electrically isolated Digital inputs: 6 positive logic; 0…+30 VDC Voltage output for digital inputs:+24V , ±20%, max. load 50 mA Output reference voltage :+10V , +3%, max. load 10 mAAnalog output :0(4)…20 mA; RL max. 500Ω; resolution 16 bit; accuracy ±1%Digital outputs :Relays:2 programmable relay outputs (1 NO/NC and 1 NO), Max.switching load: 250 Vac/2 A or 250 Vdc/0.4 A Open collector:1 open collector output with max. load 48 V/50 mAProtectionsOvervoltage protection:875VDC in HVFDCDXCXXXXXXX 437VDC in HVFDCDXBXXXXXXX Undervoltage protection:333VDC in HVFDCDXCXXXXXXX 160VDC in HVFDCDXBXXXXXXXEarth-fault protection:In case of earth fault in motor or motor cable, only the fre-quency converter is protected Unit overtemperature protection: YES Motor overload protection: YESMotor stall protection (fan/pump blocked): YES Motor underload protection(pump dry / belt broken detection): YES Short-circuit protection of +24V and +10V reference voltages: YESOvercurrent protection: T rip limit 4,0*I N instantaneouslySMARTVFD COMP ACT331-00075—01MODELSTable 1.Nominal Voltage Nom. HP (Nom. Current)EMC Filter Full IO (6DI, 2AI, 1AO,1DO, 3RO, Modbus)Frame Size: MI1Dimensions: 6.2" H x 2.6" W x 3.9" D460V3~in 3~out0.5 HP (1.3 A)No HVFDCD3C0005F00EMC HVFDCD3C0005F010.75 HP (1.9 A)No HVFDCD3C0007F00EMC HVFDCD3C0007F011 HP (2.4 A)No HVFDCD3C0010F00EMC HVFDCD3C0010F01208/230V 1~in 3~out 0.25 HP (1.7 A)EMC HVFDCD1B0003F010.5 HP (2.4 A)EMC HVFDCD1B0005F010.75 HP (2.8 A)EMC HVFDCD1B0007F01208/230V 3~in 3~out 0.25 HP (1.7 A)No HVFDCD3B0003F000.5 HP (2.4 A)No HVFDCD3B0005F00Frame Size: MI2 Dimensions: 7.7" H x 3.5" W x 4.0" D460V3~in 3~out1.5 HP (3.3 A)No HVFDCD3C0015F00EMC HVFDCD3C0015F012 HP (4.3 A)No HVFDCD3C0020F00EMC HVFDCD3C0020F013 HP (5.6 A)No HVFDCD3C0030F00EMC HVFDCD3C0030F01208/230V 1~in 3~out 1 HP (3.7A)EMC HVFDCD1B0010F011.5 HP (4.8 A)EMC HVFDCD1B0015F012 HP (7 A)EMC HVFDCD1B0020F01208/230V 3~in 3~out 1 HP (3.7A)No HVFDCD3B0010F002 HP (7 A)No HVFDCD3B0020F00115V/230V 1~in 3~out0.25 HP (1.7 A)No HVFDCD1A0003F000.5 HP (2.4 A)No HVFDCD1A0005F001 HP (3.7A)NoHVFDCD1A0010F00SMARTVFD COMP ACT31-00075—014PRODUCT IDENTIFICATION CODEFig. 1. Product Identification Code.Frame Size: MI3Dimensions: 10.2" H x 3.9" W x 4.3" D460V3~in 3~out4 HP (7.6 A)No HVFDCD3C0040F00EMC HVFDCD3C0040F015 HP (9 A)No HVFDCD3C0050F00EMC HVFDCD3C0050F017.5 HP (12 A)No HVFDCD3C0075F00EMC HVFDCD3C0075F01208/230V 1~in 3~out 3 HP (1 A)EMC HVFDCD1B0030F01208/230V 3~in 3~out 3 HP (11 A)No HVFDCD3B0030F00115V/230V 1~in 3~out 1.5 HP (4.8 A)No HVFDCD1A0015F00600V3~in 3~out1 HP (2 A)No HVFDCD3D0010F002 HP (3.6 A)No HVFDCD3D0020F003 HP (5 A)No HVFDCD3D0030F005 HP (7.6 A)No HVFDCD3D0050F007.5 HP (10.4 A)NoHVFDCD3D0075F00Nominal Voltage Nom. HP (Nom. Current)EMC Filter Full IO (6DI, 2AI, 1AO,1DO, 3RO, Modbus)SMARTVFD COMP ACT531-00075—01MECHANICAL DIMENSIONS AND MOUNTINGThere are two possible ways to mount the SmartDrive Compact onto the wall; either screw or DIN-rail mounting. The mounting dimensions are also given on the back of the inverter.Fig. 2. Mounting with screws or DIN-rail.Fig. 3. Dimensions in inches.Mechanical size H1H2H3W1W2W3D1D2MI1 6.2 5.8 5.4 2.6 1.50.2 3.90.3MI27.77.2 6.7 3.5 2.50.2 4.00.3MI310.39.99.53.93.00.24.30.3SMARTVFD COMP ACT31-00075—016COOLINGForced air flow cooling is used in all SmartDrive Compact drives. Enough free space shall be left above and below the inverter to ensure sufficient air circulation and cooling. SmartDrive Compact products can be mounted side by side. Y ou will find the required dimensions for free space and cooling air in the tables below:Table 2.Table 3.CABLING AND FUSESUse cables with heat resistance of at least +158 °F (+70 °C). The cables and the fuses must be dimensioned according to the following tables. The fuses function also as cable overload protection. These instructions apply only to cases with one motor and one cable connection from the inverter to the motor. In any other case, contact your Honeywell Sales Representative.Table 4.Table 5. Cable and fuse sizes for 208-240 V .Table 6. Cable and fuse sizes for 380-480 V .Mechanical size Free space above [inches]Free space below [inches]MI1 4.0 2.0MI2 4.0 2.0MI34.0 2.0Mechanical size Cooling air required [CFM]MI1 5.89MI2 5.89MI317.7Connection Cable typeMains cable Power cable intended for fixed installation and the specific mains voltage. Shielded cable not required. (NKCABLES/MCMK or similar recommended)Motor cablePower cable equipped with compact low-impedance shield and intended for the specific mains voltage. (NKCABLES /MCCMK, SAB/ÖZCUY -J or similar recommended). 360º grounding of both motor and FC connection required to meet the standards.Control cableScreened cable equipped with compact low-impedance shield (NKCABLES /Jamak, SAB/ÖZCuY -O or similar).Size Type (power)I N [A]Fuse [A]Mains cable Cu[AWG]Terminals cable size (min/max)Main terminal [AWG]Earth terminal [AWG]Control terminal [AWG]Relayterminal [AWG]MI1P25 - P751,7 – 3,710 2 x 15 + 1515 - 1115 - 1120 - 1520 - 15MI21P1 - 1P54,8 – 7,020 2 x 13 + 1315 - 1115 - 1120 - 1520 - 15MI32P211322 x 9 + 915 - 915 - 920 - 1520 - 15Size Type (power)I N [A]Fuse [A]Mains cable Cu[AWG]Terminals cable size (min/max)Main terminal [AWG]Earth terminal [AWG]Control terminal [AWG]Relayterminal [AWG]MI1P37 - 1P11,9 – 3,36 3 x 15 + 1515 - 1115 - 1120 - 1520 - 15MI21P5 - 2P24,3 – 5,610 3 x 15 + 1515 - 1115 - 1120 - 1520 - 15MI33P0 - 5P57,6 - 1220 3 x 13 + 1315 - 915 - 920 - 1520 - 15SMARTVFD COMP ACTFig. 4. SmartDrive Compact power connections.Fig. 5. SmartDrive Compact control connections wiring.Fig. 6. SmartVFD Compact control connection terminals.731-00075—01SMARTVFD COMP ACT31-00075—018The table below shows the SmartDrive Compact control connections with the terminal numbers.Fig. 7. Control inputs and outputs – API Full.FEATURES / FUNCTIONSEasy to set-up featuresTable 7.FeatureFunctionsBenefit30 second Start-up wizardSimple 4 step wizard for specific applications Activate wizard by pressing stop for 5 seconds Tune the motor nominal speed Tune the motor nominal currentSelect mode (0=basic, 1= Fan, 2 = Pump and 3 = Conveyor)Fully configured inverter for the application in question Ready to accept 0-10V analog speed signal in just 30 seconds“Keypad – Remote” OperationPush the navigation wheel for 5 seconds to move from remote control (I/O or Fieldbus) to manual mode and back.Single button operation to change the control tomanual (keypad) and back. Useful function whencommissioning and testing applicationsQuick Setup MenuOnly the most commonly used parameters are visible in basic view to provide easier navigation. The full view can be seen after P13.1 Parameter conceal is deactivated by changing the value to 0.Easy navigation through the most common parameters SmartVFD Commissioning Tool1.Parameter sets can be uploaded and downloaded with thistool.2.Easy to use PC-tool for commissioning the SmartVFD Invert-ers. Connection with HVFDCABLE and MCA adapter, (HVFD-CDMCAKIT/U), to the USB port of the PC. PC-tools available for download free of charge fromhttps:///en-US/support/commercial/software/vfds/Pages/default.aspxParameter copying easily from 1 inverter to another.Easy download of parameter sets created with PC-tool Parametering with PC Saving settings to PC Comparing parameter settingsSMARTVFD COMP ACT931-00075—01Compact and robust design with easy installationTable 8.Uninterruptible operation functionsTable 9.VFD and motor control featuresTable 10.OPTIONAL ACCESSORIESTable 11. SmartVFD COMPACT Accessories.FeatureFunctionsBenefitCompact size Minimum free space above and below the drive is required for cooling airflow.Minimum space requirementsIntegrated RFI-filtersThe units comply with EN61800-3 category C2 as standard. This level is the required level for public electricity networks such as buildings.Easy selection and installation of products.Space savingsCost savings Single power ratingSingle power suitable for both pump and fan or machine applicationsEasy selectionMax. ambient temperature + 122 °FHigh maximum ambient operating temperature Uninterruptible operationSide by side mounting with screws or DIN-rail asstandardSmartDrive Compact can be mounted side by side with no space between the units either with screws or on DIN-rail as standard.Dimensions for screw mounting can be found also on the back of the inverter.Easy installationSpace savings FeatureFunctionsBenefitOvertemperature ride-through Automatically adjusts switching frequency to adapt to unusual increase in ambientUninterruptible operationPower ride-through Automatically lowers motor speed to adapt to sudden voltage drop such as power lossUninterruptible operation Auto restart functionAuto restart function can be configured to make VFD restart automatically once fault is addressedUninterruptible operationFeatureFunctionsBenefitFlying startAbility to get an already spinning fan under speed control Improved performance Ease of application Inbuilt PI- controllerCapability to make a standalone system with sensor connected directly to the inverter for complete PI- control.Cost savingModel NumberDescriptionHVFDCABLE/U SmartVFD Commissioning Cable and USB Adaptor HVFDCDMCA/U Compact Commissioning Device HVFDCDMCAKIT/U Compact Commissioning Kit HVFDCDNEMA1FR1/U Compact NEMA 1 Kit Frame Size1HVFDCDNEMA1FR2/U Compact NEMA 1 Kit Frame Size2HVFDCDNEMA1FR3/U Compact NEMA 1 Kit Frame Size3HVFDCDTRAINER/UCompact Training Demonstration KitSMARTVFD COMP ACT31-00075—0110SMARTVFD COMP ACT 1131-00075—01SMARTVFD COMP ACTAutomation and Control Solutions Honeywell International Inc.1985 Douglas Drive North Golden Valley, MN 55422 ® U.S. Registered T rademark© 2015 Honeywell International Inc. 31-00075—01 M.S. 01-15 Printed in United StatesBy using this Honeywell literature, you agree that Honeywell will have no liability for any damages arising out of your use or modification to, the literature. You will defend and indemnify Honeywell, its affiliates and subsidiaries, from and against any liability, cost, or damages, including attorneys’ fees, arising out of, or resulting from, any modification to the literature by you.。

NTB75N03R, NTP75N03RPower MOSFET75 Amps, 25 VoltsN−Channel D2PAK, TO−220Features•Planar HD3e Process for Fast Switching Performance •Low R DS(on) to Minimize Conduction Loss•Low C iss to Minimize Driver Loss•Low Gate ChargeMAXIMUM RATINGS (T J = 25°C Unless otherwise specified)1.When surface mounted to an FR4 board using 1 inch pad size,(Cu Area 1.127 in2).2.When surface mounted to an FR4 board using minimum recommended padsize, (Cu Area 0.412 in2).75 AMPERES25 VOLTSR DS(on) = 5.6 mΩ (Typ) Device Package Shipping†ORDERING INFORMATIONNTP75N03R TO−220AB50 Units/Rail NTB75N03R D2PAK50 Units/Rail NTB75N03RT4D2PAK800/T ape & Reel†For information on tape and reel specifications, including part orientation and tape sizes, please refer to our Tape and Reel Packaging Specification Brochure, BRD8011/D.ELECTRICAL CHARACTERISTICS (T J= 25°C Unless otherwise specified)OFF CHARACTERISTICSON CHARACTERISTICS (Note 3)DYNAMIC CHARACTERISTICSSWITCHING CHARACTERISTICS (Note 4)SOURCE−DRAIN DIODE CHARACTERISTICS3.Pulse Test: Pulse Width = 300 m s, Duty Cycle = 2%.4.Switching characteristics are independent of operating junction temperatures.1.61.21.41.00.80.610,000100,0001042V DS , DRAIN−TO−SOURCE VOLTAGE (VOLTS)I D , D R A I N C U R R E N T (A M P S )V GS , GATE−TO−SOURCE VOLTAGE (VOLTS)Figure 1. On−Region CharacteristicsFigure 2. Transfer CharacteristicsI D , D R A I N C U R R E N T (A M P S )Figure 3. On−Resistance versus Drain Currentand TemperatureI D , DRAIN CURRENT (AMPS)R D S (o n ), D R A I N −T O −S O U R C E R E S I S T A N C E (Ω)R D S (o n ), D R A I N −T O −S O U R C E R E S I S T A N C E (Ω)Figure 5. On−Resistance Variation withTemperature T J , JUNCTION TEMPERATURE (°C)Figure 6. Drain−to−Source Leakage Currentversus VoltageV DS , DRAIN−TO−SOURCE VOLTAGE (VOLTS)R D S (o n ), D R A I N −T O −S O U R C E R E S I S T A N C E (N O R M A L I Z E D )I D S S , L E A K A G E (n A )−505025−2575125100231510255615045201001.86100081POWER MOSFET SWITCHINGSwitching behavior is most easily modeled and predicted by recognizing that the power MOSFET is charge controlled. The lengths of various switching intervals (∆t)are determined by how fast the FET input capacitance can be charged by current from the generator.The published capacitance data is difficult to use for calculating rise and fall because drain−gate capacitance varies greatly with applied voltage. Accordingly, gate charge data is used. In most cases, a satisfactory estimate of average input current (I G(A V)) can be made from a rudimentary analysis of the drive circuit so that t = Q/I G(A V)During the rise and fall time interval when switching a resistive load, V GS remains virtually constant at a level known as the plateau voltage, V SGP . Therefore, rise and fall times may be approximated by the following:t r = Q 2 x R G /(V GG − V GSP )t f = Q 2 x R G /V GSPwhereV GG = the gate drive voltage, which varies from zero to V GG R G = the gate drive resistanceand Q 2 and V GSP are read from the gate charge curve.During the turn−on and turn−off delay times, gate current is not constant. The simplest calculation uses appropriate values from the capacitance curves in a standard equation for voltage change in an RC network. The equations are:t d(on) = R G C iss In [V GG /(V GG − V GSP )]t d(off) = R G C iss In (V GG /V GSP )The capacitance (C iss ) is read from the capacitance curve at a voltage corresponding to the off−state condition when calculating t d(on) and is read at a voltage corresponding to the on−state when calculating t d(off).At high switching speeds, parasitic circuit elements complicate the analysis. The inductance of the MOSFET source lead, inside the package and in the circuit wiring which is common to both the drain and gate current paths,produces a voltage at the source which reduces the gate drive current. The voltage is determined by Ldi/dt, but since di/dt is a function of drain current, the mathematical solution is complex. The MOSFET output capacitance also complicates the mathematics. And finally, MOSFETs have finite internal gate resistance which effectively adds to the resistance of the driving source, but the internal resistance is difficult to measure and, consequently, is not specified.The resistive switching time variation versus gate resistance (Figure 9) shows how typical switching performance is affected by the parasitic circuit elements. If the parasitics were not present, the slope of the curves would maintain a value of unity regardless of the switching speed.The circuit used to obtain the data is constructed to minimize common inductance in the drain and gate circuit loops and is believed readily achievable with board mounted components. Most power electronic loads are inductive; the data in the figure is taken with a resistive load, which approximates an optimally snubbed inductive load. Power MOSFETs may be safely operated into an inductive load;however, snubbing reduces switching losses.GATE−TO−SOURCE OR DRAIN−TO−SOURCE VOLTAGE (VOLTS)C , C A P A C I T A N C E (p F )Figure 7. Capacitance VariationDRAIN−TO−SOURCE DIODE CHARACTERISTICSV SD , SOURCE−TO−DRAIN VOLTAGE (VOLTS)Figure 8. Gate−To−Source and Drain−To−SourceVoltage versus Total Charge I S , S O U R C E C U R R E N T (A M P S )Figure 9. Resistive Switching Time Variation versus Gate ResistanceR G , GATE RESISTANCE (OHMS)110100Figure 10. Diode Forward Voltage versus CurrentV G S , G A T E −T O −S O U R C E V O L T A G E (V O L T S )62Q G , TOTAL GATE CHARGE (nC)8412480.20.41.00.60.816SAFE OPERATING AREAThe Forward Biased Safe Operating Area curves define the maximum simultaneous drain−to−source voltage and drain current that a transistor can handle safely when it is forward biased. Curves are based upon maximum peak junction temperature and a case temperature (T C ) of 25°C.Peak repetitive pulsed power limits are determined by using the thermal response data in conjunction with the procedures discussed in AN569, “Transient Thermal Resistance −General Data and Its Use.”Switching between the off−state and the on−state may traverse any load line provided neither rated peak current (I DM ) nor rated voltage (V DSS ) is exceeded and the transition time (t r ,t f ) do not exceed 10 µs. In addition the total power averaged over a complete switching cycle must not exceed (T J(MAX) − T C )/(R θJC ).A Power MOSFET designated E−FET can be safely used in switching circuits with unclamped inductive loads. Forreliable operation, the stored energy from circuit inductance dissipated in the transistor while in avalanche must be less than the rated limit and adjusted for operating conditions differing from those specified. Although industry practice is to rate in terms of energy, avalanche energy capability is not a constant. The energy rating decreases non−linearly with an increase of peak current in avalanche and peak junction temperature.Although many E−FETs can withstand the stress of drain−to−source avalanche at currents up to rated pulsed current (I DM ), the energy rating is specified at rated continuous current (I D ), in accordance with industry custom.The energy rating must be derated for temperature as shown in the accompanying graph (Figure 12). Maximum energy at currents below rated continuous I D can safely be assumed to equal the values indicated.SAFE OPERATING AREAFigure 11. Maximum Rated Forward BiasedSafe Operating AreaV DS , DRAIN−TO−SOURCE VOLTAGE (VOLTS)11000I D , D R A I N C U R R E N T (A M P S )10100t, TIME (s)10.1r (t ), E F F E C T I V E T R A N S I E N T T H E R M A L R E S I S T A N C E (N O R M A L I Z E D )Figure 12. Thermal ResponseD2PAKCASE 418AA−01ISSUE OVIEW W−W VIEW W−W VIEW W−W 123TO−220CASE 221A−09ISSUE AASTYLE 5:PIN 1.GATE 2.DRAIN 3.SOURCE 4.DRAINON Semiconductor and are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC reserves the right to make changes without further notice to any products herein. SCILLC makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does SCILLC assume any liability arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation special, consequential or incidental damages.“Typical” parameters which may be provided in SCILLC data sheets and/or specifications can and do vary in different applications and actual performance may vary over time. All operating parameters, including “Typicals” must be validated for each customer application by customer’s technical experts. SCILLC does not convey any license under its patent rights nor the rights of others. SCILLC products are not designed, intended, or authorized for use as components in systems intended for surgical implant into the body, or other applications intended to support or sustain life, or for any other application in which the failure of the SCILLC product could create a situation where personal injury or death may occur. Should Buyer purchase or use SCILLC products for any such unintended or unauthorized application, Buyer shall indemnify and hold SCILLC and its officers, employees, subsidiaries, affiliates,and distributors harmless against all claims, costs, damages, and expenses, and reasonable attorney fees arising out of, directly or indirectly, any claim of personal injury or death associated with such unintended or unauthorized use, even if such claim alleges that SCILLC was negligent regarding the design or manufacture of the part. SCILLC is an Equal Opportunity/Affirmative Action Employer. This literature is subject to all applicable copyright laws and is not for resale in any manner.PUBLICATION ORDERING INFORMATION。

TEP7 常用功能块说明1. SFB0 "CTU" SFB1 "CTD" SFB2 "CTUD" SFB4 "TON" SFB5 TOF兼容IEC61131-3的计数和计时功能块2. SFB41 "CONT_C" SFB42 "CONT_S" SFB43 "PULSEGEN"用于PID控制41---连续42---离散43---用于将一个模拟量转化为与之对应的周期性开关量脉冲信号,该脉冲的占空比与模拟量的数值大小成正比.3. SFC0 "SET_CLK" SFC1 "READ_CLK"用于读写PLC中的系统时间4. SFC14 "DPRD_DAT" SFC15 "DPWR_DAT"用于读写DP从站中的一致性数据如:读写用DP通讯的变频器中的控制字5. SFC20 "BLKMOV" SFC21 "FILL"块拷贝,块填充6. SFC46 "STP" SFC47 "WAIT"SFC46 使PLC进入STOP状态,挺有用的:可以当软件陷阱,或利用上位控制PLC停机7. SFC60 "GD_SND" SFC61 "GD_RCV"MPI的GD通讯8.IEC Function BlocksFC22 "LIMIT" FC25 "MAX" FC27 "MIN"FC22 ---限幅输出FC25,FC27 --- 3个数比大小9.PID Control BlocksFB41/42/43 同SFB41 "CONT_C" SFB42 "CONT_S" SFB43 "PULSEGEN" FB58 "TCON_CP" FB59 "TCONT_S" 用于温度控制PID10.Ti-S7 Converting BlocksFC105 "SCALE" FC106 "UNSCALE"模拟量输入输出的比例和数据类型转换11、SFC1 读取系统时钟12、SFC3 启动/停止运行时间定时器13、OB1：主程序循环14、OB10--OB17：在设置的日期和时间启动15、OB20--OB23：延时后启动16、OB30--OB38：以设定的时间为周期17、OB40--OB47：检测到来自外部模块的中断请求时启动18、OB55：DPV1中断（PROFIBUS-DP中断）目录1 组织块1-11.1组织块(OB)概述................................................................................................1-11.2程序循环组织块(OB1).......................................................................................1-41.3 时钟中断组织块(OB10到OB17) .......................................................................1-61.4 时间延迟中断组织块(OB20到OB23)..............................................................1-101.5 周期性中断组织块(OB30 到OB38) .................................................................1-121.6 硬件中断组织块(OB40到OB47) .....................................................................1-141.7 状态中断OB(OB 55)........................................................................................1-161.8 更新中断OB(OB 56)........................................................................................1-171.9制造商特定中断OB(OB57)..............................................................................1-181.10多值计算中断组织块(OB60)............................................................................1-191.11 同步周期性中断OB(OB 61 到OB 64)...............................................................1-211.12I/O冗余出错OB(OB70)....................................................................................1-221.13CPU冗余出错OB(OB72).................................................................................1-241.14 通讯冗余出错OB(OB73) .................................................................................1-271.15时间出错组织块(OB80)...................................................................................1-281.16电源出错组织块(OB81)...................................................................................1-301.17诊断中断组织块(OB82)...................................................................................1-321.18 插入/删除模块中断组织块(OB83) ...................................................................1-341.19 CPU硬件故障组织块(OB84) ...........................................................................1-371.20 优先级出错组织块(OB85) ...............................................................................1-381.21机架故障组织块(OB86)...................................................................................1-421.22通讯出错组织块(OB87)...................................................................................1-451.23 处理中断OB(OB 88)........................................................................................1-471.24 后台组织块(OB90) ..........................................................................................1-481.25 启动组织块(OB100、OB101和OB102).......................................................... 1-501.26编程出错组织块(OB121).................................................................................1-551.27 I/O访问出错组织块(OB122) ............................................................................1-572 SFC的公共参数2-12.1通过输出参数RET_VAL判断出错......................................................................2-12.2异步SFC的REQ、RET_VAL和BUSY参数的含义............................................. 2-4目录用于S7-300/400系统和标准功能的系统软件x A5E00446508-013 复制功能和块功能3-13.1 使用SFC20“BLKMOV”复制存储区域...............................................................3-13.2 使用SFC81“UBLKMOV”不间断地复制变量.....................................................3-43.3 使用SFC21“FILL”初始化存储区.......................................................................3-63.4 使用SFC22“CREAT_DB”创建数据块...............................................................3-83.5 使用SFC23“DEL_DB”删除数据块..................................................................3-103.6 使用SFC24“TEST_DB”测试数据块................................................................3-123.7 使用SFC25“COMPRESS”压缩用户存储器....................................................3-133.8 使用SFC44“REPL_VAL”传送一个替换值到累加器1...................................... 3-153.9 使用SFC82“CREA_DBL”在装载存储器中生成数据块................................... 3-163.10 使用SFC83 “READ_DBL”从装载存储器的数据块中读取数据........................ 3-193.11 使用SFC84“WRIT_DBL”在装载存储器中写入数据块.................................... 3-213.12 使用SFC85“CREA_DB”创建数据块...............................................................3-234 用于控制程序执行的SFC 4-14.1 使用SFC43“RE_TRIGR”重新触发循环时间监视.............................................4-14.2 使用SFC46“STP”将CPU切换为STOP.............................................................4-14.3 使用SFC47“WAIT”延时用户程序执行..............................................................4-24.4 使用SFC35“MP_ALM”触发多处理器中断........................................................4-34.5 使用SFC104“CiR”控制CiR...............................................................................4-45 用于处理系统时钟的SFC 5-15.1 使用SFC0“SET_CLK”设定TOD.......................................................................5-15.2 使用SFC1“READ_CLK”读取时间....................................................................5-25.3 使用SFC48“SNC_RTCB”同步子时钟..............................................................5-35.4 使用SFC100“SET_CLKS”设定时间日期和TOD状态....................................... 5-46 用于处理运行系统计时器的SFC 6-16.1运行时间定时器.................................................................................................6-16.2 使用SFC101“RTM”控制运行时间定时器..........................................................6-26.3 使用SFC2“SET_RTM”设置运行时间定时器.....................................................6-46.4 使用SFC3“CTRL_RTM”启动和停止运行时间定时器....................................... 6-56.5 使用SFC4“READ_RTM”读取运行时间定时器..................................................6-66.6 使用SFC64“TIME_TCK”读取系统时间............................................................6-77 用于传送数据记录的SFC 7-17.1读写一条数据记录.............................................................................................7-17.2 使用SFC54“RD_DPARM”读取定义的参数......................................................7-37.3 使用SFC102“RD_DPARA”读取预定义参数.....................................................7-47.4 使用SFC55“WR_PARM”写动态参数...............................................................7-57.5 使用SFC56“WR_DPARM”写一条数据记录......................................................7-77.6 用SFC57 “PARM_MOD”将参数分配给模块..................................................... 7-87.7 使用SFC58“WR_REC”写入数据记录.............................................................7-117.8 使用SFC59“RD_REC”读一个数据记录..........................................................7-137.9 SFC55到59的进一步出错信息....................................................................... 7-18目录用于S7-300/400系统和标准功能的系统软件A5E00446508-01 xi8 符合PNO AK 1131的DPV1 SFB 8-18.1 使用SFB“RDREC”从DP从站读一个数据记录..................................................8-18.2使用SFB53“WRREC”将数据记录写入DP从站.................................................. 8-38.3 用SFB54“RALRM”STATUS[3]从DP从站接收中断.......................................... 8-58.4用SFB75“SALRM”向DP主站发送中断............................................................ 8-149 用于处理时钟中断的SFC 9-19.1处理时钟中断....................................................................................................9-19.2 SFC28到31的特征...........................................................................................9-29.3 使用SFC28“SET_TINT”设置日时钟中断..........................................................9-49.4 使用SFC29“CAN_TINT”取消时钟中断.............................................................9-59.5 使用SFC30“ACT_TINT”激活时钟中断.............................................................9-69.6 使用SFC31“QRY_TINT”查询日时钟中断.........................................................9-710 用于处理延时中断的SFC 10-110.1处理延时中断..................................................................................................10-110.2 使用SFC32“SRT_DINT”启动延时中断...........................................................10-310.3 使用SFC34“QRY_DINT”查询日时钟中断......................................................10-410.4 使用SFC33“CAN_DINT”取消延时中断..........................................................10-511 用于处理同步出错的SFC 11-111.1屏蔽同步出错..................................................................................................11-111.2 使用SFC36“MSK_FLT”屏蔽同步出错..........................................................11-1011.3 使用SFC37“DMSK_FLT”解除屏蔽同步出错................................................11-1111.4 使用SFC38“READ_ERR”读取出错寄存器...................................................11-1212 用于处理中断和异步出错的SFC 12-112.1延迟和禁用中断和异步出错.............................................................................12-112.2 使用SFC39“DIS_IRT”禁用新中断和异步出错的处理..................................... 12-312.3 使用SFC40“EN_IRT”启用新中断和异步出错的处理...................................... 12-512.4 使用SFC41 “DIS_AIRT”延迟更高优先级中断和异步出错的处理.................... 12-712.5 使用SFC42 “EN_AIRT”启用处理较高优先级的中断和异步出错..................... 12-813 用于诊断的SFC 13-113.1系统诊断......................................................................................................... 13-113.2 使用SFC6“RD_SINFO”读取OB启动信息.......................................................13-113.3 使用SFC51“RDSYSST”读取系统状态列表或部分列表.................................. 13-413.4 使用SFC52 “WR_USMSG”将自定义诊断事件写入诊断缓冲区................... 13-1013.5 使用SFC78“OB_RT”确定OB程序运行时间..................................................13-1413.6 使用SFC87“C_DIAG”诊断当前连接状态......................................................13-1813.7 使用SFC103 “DP_TOPOL”识别DP主站系统的总线拓扑.............................. 13-2314 用于更新过程映像和处理位域的SFC和SFB 14-114.1 使用SFC26“UPDAT_PI”更新过程映像输入表................................................14-114.2 使用SFC27“UPDAT_PO”更新过程映像输出表..............................................14-314.3 使用SFC79“SET”在I/O区域中设置位域.........................................................14-514.4 使用SFC 126 “SYNC_PI”在同步循环中更新过程映像分区输入表................. 14-614.5 使用SFC 127 “ISO_PO”在同步循环中更新过程映像分区输出表.................... 14-814.6 使用SFC80“RSET”复位I/O区域中的位域.....................................................14-1014.7 使用SFB 32“DRUM”实现一个操作序列.......................................................14-11目录用于S7-300/400系统和标准功能的系统软件xii A5E00446508-0115 用于寻址模块的系统功能15-115.1 使用SFC5“GADR_LGC”查询模块的逻辑基址................................................15-115.2 使用SFC49 “LGC_GADR”查询属于一个逻辑地址的模块插槽....................... 15-315.3 使用SFC50“RD_LGADR”查询模块的所有逻辑地址...................................... 15-516 用于分布式I/O的SFC 16-116.1 使用SFC7“DP_PRAL”在DP主站上触发硬件中断.......................................... 16-116.2 用SFC11“DPSYC_FR”同步DP从站组...........................................................16-416.3 用SFC12“D_ACT_DP”激活和取消激活DP从站...........................................16-1016.4 用SFC13 “DPNRM_DG”读取DP从站的诊断数据(从站诊断) ........................ 16-1416.5 使用SFC14 “DPRD_DAT”读取DP标准从站的连续数据................................ 16-1816.6 使用SFC15 “DPWR_DAT”将连续数据写入到DP标准从站........................... 16-2017 用于全局数据通讯的SFC 17-117.1 使用SFC60“GD_SND”发送一个GD信息包....................................................17-117.2 通过SFC61“GD_RCV”编程接受已接收到的GD信息包.................................. 17-418 通讯和S7基本通讯的概述18-118.1S7通讯块和S7基本通讯块之间的差别............................................................ 18-118.2数据的一致性..................................................................................................18-418.3S7通讯块概述.................................................................................................18-618.4用于S7基本通讯的功能块总览........................................................................ 18-819 S7通讯19-119.1用于S7通讯的SFB/FB和SFC/FC的公用参数.................................................. 19-119.2用于组态的S7连接的SFB启动例行程序.......................................................... 19-519.3SFB对故障如何反应........................................................................................19-719.4通过SFB8/FB8“USEND”进行无协调的数据发送.............................................19-919.5通过SFB/FB9“URCV”进行无协调的数据接收...............................................19-1219.6 通过SFB/FB12“BSEND”发送分段数据........................................................19-1519.7 通过SFB/FB13“BRCV”接收分段数据...........................................................19-1819.8通过SFB/FB15“PUT”向远程CPU写入数据................................................... 19-2119.9通过SFB/FB14GET”从远程CPU中读取数据................................................. 19-2419.10使用SFB16“PRINT”将数据发送到打印机...................................................... 19-2719.11 通过SFB 19“START”在远程设备上开始一个暖重启或冷重启...................... 19-3319.12 通过SFB20“STOP”将远程设备切换到STOP状态........................................ 19-3619.13 通过SFB21“RESUME”在远程设备上开始一个热重启.................................. 19-3819.14 使用SFB22“STATUS”查询远程伙伴的状态.................................................19-4019.15 通过SFB23“USTATUS”接收远程设备的状态改变....................................... 19-4219.16 通过SFC62 “CONTROL”查询属于SFB实例的连接状态............................... 19-4419.17 通过FC62“C_CNTRL”查询连接状态............................................................19-4619.18S7通讯SFB/FB的工作存储器要求................................................................. 19-48目录用于S7-300/400系统和标准功能的系统软件A5E00446508-01 xiii20 用于未组态S7连接的通讯SFC 20-120.1通讯SFC的公用参数.......................................................................................20-120.2用于未组态S7连接的通讯SFC的出错信息......................................................20.3 使用SFC65 “X_SEND”将数据发送给在本地S7站外的一个通讯伙伴.............. 20-720.4 通过SFC66 “X_RCV”从本地S7站以外的通讯伙伴中接收数据....................... 20-820.5 通过SFC68 “X_PUT”将数据写入本地S7站以外的通讯伙伴.......................... 20-1120.6 通过SFC67 “X_GET”从本地S7站以外的通讯伙伴中读取数据..................... 20-1320.7 通过SFC69 “X_ABORT”中止已存在的、到本地S7站以外的通讯伙伴的连接20-15 20.8 使用SFC72 “I_GET”从本地S7站内的一个通讯伙伴上读取数据.................... 20-1620.9 使用SFC73 “I_PUT”将数据写入到本地S7站内的一个通讯伙伴.................... 20-1820.10 通过SFC74 “I_ABORT”中止已存在的、到本地S7站内的通讯伙伴的连接.... 20-2021 PROFInet 21-121.1SFC112、113和114背景信息.........................................................................21-121.2 使用SFC112 “PN_IN”更新用于PROFInet组件的用户程序接口的输入........... 21-421.3 使用SFC113 “PN_OUT”更新用于PROFInet组件的用户程序接口的输出....... 21-521.4 使用SFC114“PN_DP”更新DP互连................................................................21-622 生成与块相关的消息22-122.1关于使用SFB生成块相关消息的介绍.............................................................. 22-122.2 使用SFB 36“NOTIFY”生成无需确认的块相关消息........................................ 22-522.3 使用SFB31 “NOTIFY_8P”生成无确认显示的块相关消息............................... 22-722.4 使用SFB 33“ALARM”生成需要确认的块相关消息....................................... 22-1022.5 使用SFB35 “ALARM_8P”生成针对八个信号的带有关联值的块相关消息..... 22-1322.6 使用SFB34 “ALARM_8”生成针对八个信号的不附带关联值的块相关消息.... 22-1622.7 使用SFB37“AR_SEND”发送归档数据.........................................................22.8 使用SFC10 “DIS_MSG”禁止与块相关的消息、与符号相关的消息以及组状态消息................................................................ 22-2022.9 使用SFC9 “EN_MSG”启用块相关、符号相关和组状态消息......................... 22-2222.10用于生成与块相关的消息的SFB的启动特性.................................................22-2422.11用于生成与块相关的消息的SFB如何响应故障..............................................22-2522.12使用SFC生成与块相关的消息简介................................................................ 22-2622.13 使用SFC17 “ALARM_SQ”生成可确认的与块相关的消息以及使用SFC18 “ALARM_S”生成永久确认的与块相关的消息................................................22-2922.14 使用SFC19 “ALARM_SC”查询上一ALARM_SQ/ALARM_DQ进入事件消息的确认状态.......................................................... 22-3222.15 使用SFC 107 “ALARM_DQ”和108 “ALARM_D”生成可确认和永久确认的块相关消息............................................................22-3322.16 使用SFC105“READ_SI”读取动态系统资源..................................................22-3522.17 使用SFC106“READ_SI”读取动态系统资源..................................................22-3823 IEC定时器和IEC计数器23-123.1 使用SFB3“TP”生成一个脉冲..........................................................................23-123.2 使用SFB4“TON”生成一个接通延迟................................................................23-323.3 使用SFB5“TOF”生成一个关闭延迟................................................................23-523.4 使用SFB 0“CTU”递增计数.............................................................................23-723.5 使用SFB 1“CTD”递减计数.............................................................................23-823.6 使用SFB2“CTUD”递增/递减计数...................................................................23-9目录用于S7-300/400系统和标准功能的系统软件xiv A5E00446508-0124 IEC功能24-124.1概述......................................................................................................... ........24-124.2IEC功能的技术数据.........................................................................................24-324.3日期和时间作为复杂数据类型......................................................................... 24-524.4时间功能......................................................................................................... 24-624.5比较DATE_AND_TIME变量......................................................................... 24-1024.6比较STRING变量..........................................................................................24-1324.7编辑数值....................................................................................................... 24-1624.8STL示例........................................................................................................ 24-1724.9STL示例........................................................................................................ 24-1824.10编辑STRING变量..........................................................................................24-1924.11转换数据类型格式.........................................................................................24-2425 用于集成控制的SFB 25-125.1 使用SFB41/FB41“CONT_C”实现连续控制....................................................25-125.2 使用SFB42/FB42“CONT_S”进行步控制........................................................25-825.3 使用SFB43/FB43“PULSEGEN”生成脉冲....................................................25-1425.4PULSEGEN块的实例....................................................................................25-2526 用于紧凑型CPU的SFB 26-126.1 通过SFB44“Analog”使用模拟量输出进行定位...............................................26-126.2 通过SFB46“DIGITAL”使用数字量输出进行定位.......................................... 26-1326.3 使用SFB47“COUNT”控制计数器.................................................................26-2326.4 使用SFB48“FREQUENC”控制频率测量......................................................26-2826.5 使用SFB49“PULSE”控制脉宽调制...............................................................26-3226.6 使用SFB60 “SEND_PTP”发送数据(ASCII，3964(R)) .................................. 26-3526.7 使用SFB61 “RCV_PTP”接收数据(ASCII，3964(R)) .................................... 26-3826.8 使用SFB62 “RES_RCVB”删除接收缓冲区(ASCII，3964(R))...................... 26-4126.9 使用SFB63 “SEND_RK”发送数据(512(R))................................................... 26-4326.10 使用SFB64 “FETCH RK”获取数据(RK 512) ................................................. 26-4726.11 使用SFB65 “SERVE_RK”接收和提供数据(RK 512) ..................................... 26-5226.12 SFB60至65的附加出错信息......................................................................... 26-5727 用于H CPU的SFC 27-127.1 在H系统中使用SFC90“H_CTRL”控制操作....................................................27-128 集成功能(对于带集成I/O的CPU) 28-128.1SFB29(HS_COUNT)................................................................................. ......28-128.2SFB30(FREQ_MES).................................................................................. .....28-328.3SFB38(HSC_A_B).................................................................................... ......28-428.4SFB39(POS)........................................................................................... ........28-529 Plastics Techology 29-129.1 SFC63 (AB_CALL) .........................................................................................29-130 诊断数据30-130.1诊断数据结构概述...........................................................................................30-130.2诊断数据......................................................................................................... 30-230.3通道专有诊断数据的结构................................................................................30-4目录用于S7-300/400系统和标准功能的系统软件A5E00446508-01 xv31 系统状态列表(SSL) 31-131.1系统状态列表(SSL)概述..................................................................................31-131.2部分SSL列表的结构........................................................................................31-331.3 SSL-ID ............................................................................................................ 31-431.4可能的部分系统状态列表................................................................................31-531.5 SSL-ID W#16#xy11 -模块标识......................................................................31-631.6 SSL-ID W#16#xy12 -CPU特征......................................................................31-731.7 SSL-ID W#16#xy13 -存储区域......................................................................31-931.8 SSL-ID W#16#xy14 -系统区........................................................................31-1031.9 SSL-ID W#16#xy15 -块类型........................................................................31-1231.10 SSL-ID W#16#xy19 -模块LED的状态..........................................................31-1331.11 SSL-ID W#16#xy1C -组件标识....................................................................31-1531.12 SSL ID W#16#xy25 -将过程映像分区分配到OB.......................................... 31-1831.13 SSL-ID W#16#xy32 -通讯状态数据.............................................................31-2131.14 SSL-ID W#16#0132，索引为W#16#0005的部分列表的数据记录摘录....... 31-2231.15 SSL-ID W#16#0132，索引为W#16#0008的部分列表的数据记录摘录....... 31-2331.16 SSL-ID为W#16#0132、索引为W#16#000B的部分列表摘录的数据记录.... 31-2531.17 SSL-ID为W#16#0132、索引为W#16#000C的部分列表摘录的数据记录.... 31-2631.18 SSL-ID W#16#0232，索引为W#16#0004的部分列表的数据记录摘录....... 31-2731.19 SSL-ID W#16#xy71 - HCPU的组信息.........................................................31-2831.20 SSL-ID W#16#xy74 -模块LED的状态..........................................................31-3131.21 SSL-ID W#16#xy75 -H系统中切换的DP从站.............................................. 31-3331.22 SSL-ID W#16#xy90 -DP主站系统信息........................................................31-3531.23 SSL-ID W#16#xy91 -模块的状态信息..........................................................31-3731.24 SSL-ID W#16#xy92 -机架/站的状态信息..................................................... 31-4131.25 SSL-ID W#16#xy95 -扩展DP主站系统信息................................................. 31-4431.26 SSL-ID W#16#xyA0 -诊断缓冲区................................................................31-4631.27 SSL-ID W#16#00B1 -模块的诊断信息.........................................................31-4731.28 SSL-ID W#16#00B2 -对应物理地址的诊断数据记录1................................. 31-4931.29 SSL-ID W#16#00B3 -带逻辑基址的模块诊断数据....................................... 31-5031.30 SSL-ID W#16#00B4 -DP从站的诊断数据.................................................... 31-5132 事件32-132.1事件和事件标识符...........................................................................................32-132.2 事件等级1 -标准OB事件.................................................................................32-332.3 事件等级2 -异步出错......................................................................................32-332.4 事件等级3 -异步出错......................................................................................32-432.5 事件等级4 -停止事件和其它模式改变............................................................32-732.6 事件等级5 -模式运行期事件.........................................................................32-1032.7 事件等级6 -通讯事件....................................................................................32-1132.8 事件等级7 -H/F事件.....................................................................................32-1232.9 事件等级8 -模块的诊断事件.........................................................................32-1432.10 事件等级9 -标准用户事件.............................................................................32-1632.11 事件等级A和B -自由用户事件......................................................................32-1732.12保留的事件等级.............................................................................................32-18目录用于S7-300/400系统和标准功能的系统软件xvi A5E00446508-0133 SFC和SFB列表33-133.1按编号排序的SFC列表....................................................................................33-133.2按字母排序的SFC列表....................................................................................33-433.3按编号排序的SFB列表....................................................................................33-733.4按字母排序的SFB列表....................................................................................33-9参考书目词汇表索引用于S7-300/400系统和标准功能的系统软件A5E00446508-01 1-11 组织块1.1 组织块(OB)概述何为组织块？组织块(OB)是指CPU的操作系统与用户程序之间的接口。

Philips BrillianceCurved UltraWide LCD Monitor with USB-CP Line34" (86.36 cm)3440 x 1440 (WQHD)346P1CRHMaster every task in a crisp panoramic viewThe Philips Brilliance curved WQHD display with DisplayHDR 400 gives crisp,outstanding visuals. USB-C and a secure pop-up webcam with Windows Hello increase your productivity.Brilliant performance•CrystalClear images with UltraWide QHD 3440 x 1440 pixels •MultiView enables simultaneous dual connect and view •Effortlessly smooth action with Adaptive-Sync technology Optimal Connectivity•Built in USB-C docking station•Built-in KVM switch to easily switch between sources Designed for the way you work•Securely sign in with pop-up webcam with Windows Hello™•DisplayHDR 400 for more lifelike colorful visuals •Less eye fatigue with Flicker-free technology •LowBlue Mode for easy on-the-eyes productivity Designed for sustainability•PowerSensor saves up to 70% energy costsHighlightsUltraWide CrystalClear imagesThese Philips screens deliver CrystalClear, UltraWide Quad HD 3440 x 1440 pixelimages. Utilizing high performance panels with high-density pixel count, 178/178 wide viewing angles, these new displays will make your images and graphics come alive. The UltraWide 21:9 format enables moreproductivity with more room for side-by-side comparisons and more viewable spreadsheet columns. Whether you are demanding professional requiring extremely detailed information for CAD-CAM solutions, or a financial wizard working on huge spreadsheets, Philips displays delivers CrystalClear images.MultiView technologyWith the ultra-high resolution PhilipsMultiView display you can now experience a world of connectivity. MultiView enables active dual connect and view so that you can work with multiple devices like a PC and notebook simultaneously, for complex multi-tasking.Adaptive-Sync technologyGaming shouldn't be a choice between choppy gameplay or broken frames. Get fluid, artifact-free performance at virtually any framerate with Adaptive-Sync technology, smooth quick refresh and ultra-fast response time.Built in USB-C docking stationThis Philips display features a built-in USB type-C docking station with power delivery. Its slim, reversible USB-C connector allows for easy, one-cable docking. Simplify by connecting all your peripherals like keyboard, mouse and your RJ-45 Ethernet cable to the monitor's docking station. Simply connect yournotebook and this monitor with a single USB-C cable to watch high-resolution video and transfer super-speed data, while powering up and re-charging your notebook at the same time.MultiClient Integrated KVMWith MultiClient Integrated KVM switch, you can control two separate PCs with onemonitor-keyboard-mouse set up. A convenient button allows you to quickly switch between sources. Handy with set-ups that require dual PC computing power or sharing one large monitor to show two different PCs.Windows Hello™ pop-up webcamPhilips' innovative and secure webcam pops up when you need it and securely tucks back into the monitor when you are not using it. The webcam is also equipped with advanced sensors for Windows Hello™ facialrecognition, which conveniently logs you into your Windows devices in less than 2 seconds, 3 times faster than a password.DisplayHDR 400VESA-certified DisplayHDR 400 delivers a significant step-up from normal SDR displays. Unlike, other 'HDR compatible' screens, true DisplayHDR 400 produces astonishingbrightness, contrast and colors. With global dimming and peak brightness up-to 400 nits, images come to life with notable highlights while featuring deeper, more nuanced blacks. It renders a fuller palette of rich new colors, delivering a visual experience that engagesyour senses.Issue date 2021-03-07 Version: 6.0.112 NC: 8670 001 62662 EAN: 87 12581 76219 3© 2021 Koninklijke Philips N.V.All Rights reserved.Specifications are subject to change without notice. Trademarks are the property of Koninklijke Philips N.V. or their respective owners.SpecificationsPicture/Display•LCD panel type: VA LCD•Adaptive sync•Backlight type: W-LED system•Panel Size: 34 inch / 86.36 cm•Display Screen Coating: Anti-Glare, 2H, Haze 25%•Effective viewing area: 797.2 (H) x 333.7 (V) - at a 1500 R curvature*•Aspect ratio: 21:9•Maximum resolution: 3440 x 1440 @ 100 Hz*•Pixel Density: 110 PPI•Response time (typical): 4 ms (Gray to Gray)*•Brightness: 500 cd/m²•Contrast ratio (typical): 3,000:1•SmartContrast: 80,000,000 :1•Pixel pitch: 0.23175 x 0.23175 mm•Viewing angle: 178º (H) / 178º (V), @ C/R > 10•Picture enhancement: SmartImage•Display colors: 16.7 M•Color gamut (min.): BT. 709 Coverage: 96%*; DCI-P3 Coverage: 90%*•Color gamut (typical): NTSC 98%*, sRGB 120%*, Adobe RGB 88%*•HDR: DisplayHDR 400 certified (DP / HDMI)•Scanning Frequency: 30 - 160 kHz (H) / 48 - 100 Hz (V)•SmartUniformity: 93 ~ 105%•Delta E: < 2 (sRGB)•sRGB•Flicker-free•LowBlue Mode•EasyRead•KVMConnectivity•Signal Input: DisplayPort 1.4 x 1, HDMI 2.0 x 1, USB-C 3.2 Gen 2 x 1 (upstream, power delivery up to 90 W)•Signal Output: DisplayPort out (DP, USB-C)*•HDCP: HDCP 2.2 (HDMI / DP)•USB:: USB-C x 1, USB-B x 1 (upstream), USB 3.2 x 4 (downstream with 1 fast charge B.C 1.2)•Audio (In/Out): Headphone out•RJ45: Ethernet LAN up to 1G*, Wake On Lan •Sync Input: Separate SyncUSB•USB-C: Reversible plug connector•Super speed: Data and Video transfer•DP: Built-in Display Port Alt mode•Power delivery: USB PD version 3.0•USB-C max. power delivery: Up to 90W* (5V/3A; 7V/3A; 9V/3A; 10V/3A;12V/3A; 15V/3A; 20V/4.5A) Convenience•Built-in Speakers: 5 W x 2•Built-in webcam: 2.0 megapixel FHD camera with microphone and LED indictor (for Windows 10 Hello)•MultiView: PIP/PBP mode*, 2x devices•User convenience: SmartImage, Input, User, Menu, Power On/Off•Control software: SmartControl •OSD Languages: Brazil Portuguese, Czech, Dutch,English, French, Finnish, German, Greek,Hungarian, Italian, Japanese, Korean, Portuguese,Polish, Russian, Simplified Chinese, Spanish,Swedish, Traditional Chinese, Turkish, Ukranian•Other convenience: Kensington lock, VESA mount(100x100mm)•Plug & Play Compatibility: DDC/CI, Mac OS X,sRGB, Windows 10 / 8.1 / 8 / 7Stand•Height adjustment: 180 mm•Swivel: -180/180 degree•Tilt: -5 ~ 25 degreePower•ECO mode: 33 W (typ.)•On mode: 34.1 W (typ.) (EnergyStar test method)•Standby mode: < 0.5 W (typ.)•Off mode: Zero watts with Zero switch•Energy Label Class: G•Power LED indicator: Operation - White, Standbymode- White (blinking)•Power supply: Built-in, 100-240VAC, 50-60HzDimensions•Product with stand(max height): 807 x 601 x250 mm•Product without stand (mm): 807 x 367 x 110 mm•Packaging in mm (WxHxD): 930 x 525 x 282 mmWeight•Product with stand (kg): 11.65 kg•Product without stand (kg): 7.95 kg•Product with packaging (kg): 15.86 kgOperating conditions•Temperature range (operation): 0°C to 40°C °C•Temperature range (storage): -20°C to 60°C °C•Relative humidity: 20%-80 %•Altitude: Operation: +12,000ft (3,658m), Non-operation: +40,000ft (12,192m)•MTBF (demonstrated): 70,000 hrs (excludedbacklight)Sustainability•Environmental and energy: PowerSensor,LightSensor, EnergyStar 8.0, EPEAT*, RoHS•Recyclable packaging material: 100 %•Post consumer recycled plastic: 35%•Specific Substances: Mercury free, PVC / BFR freehousingCompliance and standards•Regulatory Approvals: CB, EPA, cETLus, FCCClass B, CE Mark, TUV/GS, TUV Ergo, SEMKO,CU-EAC, UKRAINIAN, CCC, CEL, RCMCabinet•Foot:Black•Rear cover: Black•Front bezel: Black•Finish: TextureWhat's in the box?•Monitor with stand•Cables: HDMI cable, DP cable, USB-C/A Y cable,Power cable•User Documentation*Radius of the arc of the display curvature in mm*The maximum resolution works for either HDMI, DP or USB-Cinput.*When connecting to USB-C, if your PC doesn't support HBR3,please switch USB hub setting to USB 2.0 and the resolution willsupport to 3440 x 1440 @ 100 Hz.*Response time value equal to SmartResponse*BT. 709 / DCI-P3 Coverage based on CIE1976*NTSC Area based on CIE1976*sRGB Area based on CIE1931*Adobe RGB Coverage based on CIE1976*If your Ethernet connection seems slow, please enter OSD menuand select USB 3.0 or higher version which can support the LANspeed to 1G.*DisplayPort 1.4 version is for HDR*For Video transmission via USB-C, your Notebook/device mustsupport USB-C DP Alt mode*For USB-C power and charging function, your Notebook/devicemust support USB-C standard Power Delivery specifications. Pleasecheck with your Notebook user manual or manufacturer for moredetails.*Maximum number of external displays that can be supported: 1 byusing USB-C, 2 by using DP*The maximum external monitor resolution will depend onbandwidth limitation.*When your monitor connected with USB-C and the PC supportsHBR3, you can have MST function with the max resolution of3440x1440@60Hz in primary monitor and 1920x1080@60Hz insecondary monitor. If not, please change the USB setting of theprimary monitor to USB2.0 via OSD setting to have MST function*While MST over DP, both of the primary and secondary monitorsneed to be set to DP out extend mode via monitor's OSD settingand the maximum resolution of both the primary & the secondarymonitor only can be 3440x1440@60Hz.*EPEAT rating is valid only where Philips registers the product. Pleasevisit https:/// for registration status in your country.*The monitor may look different from feature images.。