Terminals FC 规格书

Home / Products / Copper tube terminal / RCCN Terminals HUPDRCCN Terminals HUPDCable Lugs, CopperMaterial:Japanese HUP brass terminal made of high-quality copper,good electrical conductivity, durability is not easy aging.Features: high-quality matte plating, anti-rust greatly extended time, no sharp parts;supporting the day into the terminal clamp to clamp the wire, wiring beautiful,Product color: see the physical pictureInternational Certification: EU RoHS environmental certification, the European CE certification.Features: high quality, not broken after the release loose, -40 degrees to 150 degrees heat-resistant normal use.Use way: the wire stripped of the skin, into the terminal after the brass, use the terminal clampcan be pressed.Features:tube size is for small wire,HUP standardVDE60228(such as VDE0295 bno.5、6）.HUP inside hole enlarged, easy to insert cables.Without inspection hole terminal,part no.:HUP35-8/N,Advantage:keep perfect stability when it wasstrong mechanical strain or shake,less amending,used more widelyCable Lugs Copper HUPDSpecificationDIMENSIONItem No.E DΦdΦW B L1HUPD10-5 5.38.0 5.5121433HUPD10-6 6.58.0 5.5121433HUPD10-88.58.0 5.5161437HUPD10-1010.58.0 5.5161841HUPD10-1213.08.0 5.5191441HUPD16-5 5.39.5 6.6131536HUPD16-6 6.59.5 6.6131536HUPD16-88.59.5 6.6161542HUPD16-1010.59.5 6.6171542 HUPD16-1213.09.5 6.6191546 HUPD25-5 5.3117.9151739.5 HUPD25-6 6.5117.9151739.5 HUPD25-88.5117.9171744 HUPD25-1010.5117.9171744 HUPD25-1213.0117.9191749 HUPD35-6 6.512.59.2171942.5 HUPD35-88.512.59.2181947 HUPD35-1010.512.59.2181952 HUPD35-1213.012.59.2191952 HUPD35-1415.012.59.2211952 HUPD50-6 6.51511212151 HUPD50-88.51511212151 HUPD50-1010.51511212155 HUPD50-1213.01511212159 HUPD50-1415.01511232159 HUPD50-1617.01511282159 HUPD70-88.51713252556 HUPD70-1010.51713252560 HUPD70-1213.01713252563 HUPD70-1415.01713252563 HUPD70-1617.01713252563 HUPD95-88.51914.5282664 HUPD95-1010.51914.5282664 HUPD95-1213.01914.5282666 HUPD95-1415.01914.5282666 HUPD95-1617.01914.5282666 HUPD120-88.52116.2303071 HUPD120-1010.52116.2303071 HUPD120-1213.02116.2303073 HUPD120-1415.02116.2303073 HUPD120-1617.02116.2303073 HUPD120-2021.02116.2303073 HUPD150-88.52318343279 HUPD150-1010.52318343279 HUPD150-1213.023******** HUPD150-1415.023******** HUPD150-1617.023******** HUPD150-2021.023******** HUPD185-1010.52620.6393593.5 HUPD185-1213.02620.6393593.5 HUPD185-1415.02620.6393593.5 HUPD185-1617.02620.6393593.5 HUPD185-2021.02620.6393593.5 HUPD240-1010.52823.1414496 HUPD240-1213.02823.1414496 HUPD240-1415.02823.14144102 HUPD240-1617.02823.14144102 HUPD240-2021.02823.14144102MoreHUPD300-1213.03226.14744115HUPD300-1415.03226.14744115HUPD300-1617.03226.14744115HUPD300-2021.03226.14744115zProduct Copper tube terminal >Product Show Dow nloadRCCN Copper tube terminal …Catalogue-PDFRelated ProudctRCCN Terminals HUPD45Cable LugsRCCN Terminals HUPD90Cable LugsRCCN Terminals HUPDCable Lugs, CopperRCCN Terminals OTCable Lugs High VoltageRCCN Terminals B LCable Lugs High VoltageRCCN Cable Lugs HUPDNew Product:Cable Lugs, Co…RCCN Cable Lugs HUPD…New Product:Cable LugsPDF。

Simple Methods for Calculating Short Circuit CurrentWithout a ComputerBy Dennis McKeown, PEGE Senior System Application EngineerA Short Circuit analysis is used to determine the magnitude of short circuit current the system is capable of producing and compares that magnitude with the interrupting rating of the overcurrent protective devices (OCPD). Since the interrupting ratings are based by the standards, the methods used in conducting a short circuit analysis must conform to the procedures which the standard making organizations specify for this purpose. In the United States, the America National Standards Institute (ANSI) publishes both the standards for equipment and the application guides, which describes the calculation methods.Short circuit currents impose the most serious general hazard to power distribution system components and are the prime concerns in developing and applying protection systems. Fortunately, short circuit currents are relatively easy to calculate. The application of three or four fundamental concepts of circuit analysis will derive the basic nature of short circuit currents. These concepts will be stated and utilized in a step-by-step development.The three phase bolted short circuit currents are the basic reference quantities in a system study. In all cases, knowledge of the three phase bolted fault value is wanted and needs to be singled out for independent treatment. This will set the pattern to be used in other cases.A device that interrupts short circuit current, is a device connected into an electric circuit to provide protection against excessive damage when a short circuit occurs. It provides this protection by automatically interrupting the large value of current flow, so the device should be rated to interrupt and stop the flow of fault current without damage to the overcurrent protection device. The OCPD will also provide automatic interruption of overload currents.Listed here are reference values that will be needed in the calculation of fault current. Impedance Values for Three phase transformersHV Rating 2.4KV – 13.8KV 300 – 500KVA Not less than 4.5%HV Rating 2.4KV – 13.8KV 750 – 2500KVA 5.75%General Purpose less then 600V 15 – 1000KVA 3% to 5.75%Reactance Values for Induction and Synchronous MachineX” SubtransientSalient pole Gen 12 pole 0.1614 pole 0.21Synchronous motor 6 pole 0.158-14 pole 0.20Induction motor above 600V 0.17Induction motor below 600V 0.25TRANSFORMER FAULT CURRENTCalculating the Short Circuit Current when there is a Transformer in the circuit. Every transformer has “ %” impedance value stamped on the nameplate. Why is it stamped? It is stamped because it is a tested value after the transformer has been manufactured. The test is as follows: A voltmeter is connected to the primary of the transformer and the secondary 3-Phase windings are bolted together with an ampere meter to read the value of current flowing in the 3-Phase bolted fault on the secondary. The voltage is brought up in steps until the secondary full load current is reached on the ampere meter connected on the transformer secondary.So what does this mean for a 1000KVA 13.8KV – 480Y/277V.First you will need to know the transformer Full Load AmpsFull Load Ampere = KVA / 1.73 x L-L KVFLA = 1000 / 1.732 x 0.48FLA = 1,202.85The 1000KVA 480V secondary full load ampere is 1,202A.When the secondary ampere meter reads 1,202A and the primary Voltage Meter reads 793.5V. The percent of impedance value is 793.5 / 13800 = 0.0575. Therefore;% Z = 0.0575 x 100 = 5.75%This shows that if there was a 3-Phase Bolted fault on the secondary of the transformer then the maximum fault current that could flow through the transformer would be the ratio of 100 / 5.75 times the FLA of the transformer, or 17.39 x the FLA = 20,903ABased on the infinite source method at the primary of the transformer. A quick calculation for the Maximum Fault Current at the transformer secondary terminals is FC = FLA / %PU Z FC = 1202 / 0.0575 = 20,904AThis quick calculation can help you determine the fault current on the secondary of a transformer for the purpose of selecting the correct overcurrent protective devices that can interrupt the available fault current. The main breaker that is to be installed in the circuit on the secondary of the transformer has to have a KA Interrupting Rating greater then 21,000A. Be aware that feeder breakers should include the estimated motor contribution too. If the actual connected motors are not known, then assume the contribution to be 4 x FLA of the transformer. Therefore, in this case the feeders would be sized at 20.904 + (4 x 1202 = 25,712 AmpsGENERATOR FAULT CURRENTGenerator fault current differs from a Transformer. Below, we will walk through a 1000KVA example.800KW 0.8% PF 1000KVA 480V 1,202FLAKVA = KW / PFKVA = 800 / .8KVA = 1000FLA = KVA / 1.732 x L-L VoltsFLA = 1000 / 1.732 x 0.48FLA = 1,202(As listed in the table for generator subtransient X” values is 0.16)FC = FLA / X”FC = 1202 / 0.16FC = 7,513ASo, the fault current of a 1000KVA Generator is a lot less then a 1000KVA transformer. The reason is the impedance value at the transformer and Generator reactance values are very different. Transformer 5.75% vs. a Generator 16%SYSTEM FAULT CURRENTBelow is a quick way to get a MVA calculated value. The MVA method is fast and simple as compared to the per unit or ohmic methods. There is no need to convert to an MVA base or worry about voltage levels. This is a useful method to obtain an estimated value of fault current. The elements have to be converted to an MVA value and then the circuit is converted to admittance values.Utility MVA at the Primary of the TransformerMVAsc = 500MVATransformer Data13.8KV - 480Y/277V1000KVA Transformer Z = 5.75%MVA Value1000KVA / 1000 = 1 MVAMVA Value = 1MVA / Z pu = 1MVA / .0575 = 17.39 MVAUse the admittance method to calculate Fault Current1 / Utility MVA + 1 / Trans MVA = 1 / MVAsc1 / 500 + 1 / 17.39 = 1 / MVAsc0.002 + 0.06 = 1/ MVAscMVAsc = 1 / (0.002 + 0.06)MVAsc = 16.129FC at 480V = MVAsc / (1.73 x 0.48)FC = 16.129 / 0.8304FC = 19.423KAFC = 19, 423 AThe 480V Fault Current Value at the secondary of the 1000KVA transformer based on an Infinite Utility Source at the Primary of the transformer as calculated in the Transformer Fault Current section in this article is 20,904AThe 480V Fault Current Value at the secondary of the 1000KVA transformer based on a 500MVA Utility Source at the Primary of the transformer as calculated in the System Fault Current section in this article is 19,432AThe 480V Fault Current Value at the secondary of the 1000KVA transformer based on a 250MVA Utility Source at the Primary of the transformer the calculated value is 18,790AWhen the cable and its length is added to the circuit the fault current in a 480V system will decrease to a smaller value. To add cable into your calculation use the formula. Cable MVA Value MVAsc = KV2 / Z cable. Use the cable X & R values to calculate the Z value then add to the Admittance calculation as shown in this article.The conclusion is that you need to know the fault current value in a system to select and install the correct Overcurrent Protective Devices (OCPD). The available FC will be reduced as shown in the calculations when the fault current value at the primary of the transformer is reduced. If the infinite method is applied when calculating fault current and 4 x FLA is added for motor contributions, then the fault current value that is obtained will be very conservative. This means the calculated value in reality will never be reached, so you reduce any potential overcurrent protection device failures due to fault current.。

Pure competence in air.927665-0FREQUENCY CONVERTERS DANFOSS FC 101 AND FC 102NOVENCO CONTROL USER GUIDE927665-0GBFrequency converters Danfoss FC 101 and FC 102Novenco control user guideContents1.General2.Wire configuration3.First time run after installation4.Configuration of FC101 converter5.Configuration of FC102 converter6.Modbus configuration7.Reference documentation8.Patents and trademarks9.Declaration of conformity1.GeneralThe procedures in this guide serve as examples of how to control the Danfoss FC 101 and FC 102 frequency con-verters in combination with Novenco fans.Please read all relevant parts of this complete guide.Procedures and methods in this guide should be fol-lowed for the warranty to remain valid.2.Wire configurationCheck wires are correctly connected•Check that a wire connects the terminals no. 12 and 27 in the frequency converter.•Connect a control wire to terminal no. 18 in the fre-quency converter. The terminal must pull high (24V) to activate the converter.•Check the signal wire is connected to terminal no. 53. For voltage control the signal levels are 0 - 10V and for current control the levels are 4 - 20mA.•Check that ground is connected to terminals no. 20 and 55.Table 1.Icons in guideFigure 2Terminal block set up for current control3.First time run after installationHow to check the installation is correct1.Check the installation is powered off on the mainswitch.2.Check the fan and frequency converter are in-stalled correctly. Refer to the installation and maintenance guides for the fan and frequency converter.3.Power on the installation at the main switch. Thefrequency converter starts in idle mode.4.Push Hand On on the local control panel (LCP)on the frequency converter. This activates the fan rotor.5.Check the direction of rotation is consistent withthe arrows on the fan casing.6.Turn off the installation at the main switch.7.Connect the start signal wire to terminal no. 18.8.Voltage or current mode:Connect the reference wire to terminal no. 53.Modbus mode:Connect the reference wires to terminals no. 68 and 69.4.Configuration of FC101 converterThe converter is set up for voltage mode as standard. The minimum speed is indicated with 0V and the max-imum speed with 10V.Figure 3Wire diagram for the FC101+10 V DC4.1Change from voltage to current con-trolHow to change the FC101 to current control1.Push the Menu button on the LCP on the fre-quency converter.2.Push the ↓ and ↑ buttons to navigate to the Wiz-ard. Push OK to select.3.Push ↓ to navigate to the following menu item.6-19 Terminal 53 mode[1] Voltage mode4.Push OK to access and use the ↓ and ↑ to selectcurrent mode.5.Push OK to accept.The frequency converter now operates in current mode for control signals. The minimum speed is indicated with 4mA and the maximum speed with 20mA.5.Configuration of FC102 converter The converter is set up for voltage mode as standard.The minimum speed is indicated with 0V and the max-imum speed with 10V.Figure 4Wire diagram for the FC1025.1Change from voltage to current con-trolHow to change the FC102 to current control1.Remove the screw that holds the lid on the fre-quency converter.2.Pull out the LCP with a straight pull.3.Locate the text A53 U - I.4.Push the button from position U to I with ascrewdriver.5.Put the LCP back.6.Attach the lid and insert the screw.The frequency converter now operates in current mode for control signals. The minimum speed is indicated with 4mA and the maximum speed with 20mA. 6.Modbus configurationAll parameters are accessible through Modbus RTU (Re-mote Terminal Unit) either directly or via PCD (Process Data).To setup the Modbus RTU1.Push the Menu button two times.2.Push ↓ to navigate to8-** Comm. and Options.3.Push OK.4.Push ↓ to navigate to 8-3 FC port settings.5.Push OK.6.Push OK again.7.Push ↓ to navigate to [2] Modbus RTU.8.Push OK to confirm.9.Push ↓ to navigate down and check the followingsettings.•Address•Baud Rate•Parity / Stop bit•Minimum Response Delay•Maximum Inter-char..10.Push OK to select, the ↓ and ↑ buttons to changeand push OK to confirm settings.Write and start-stop notes•PCD: It is possible to configure up to 64 parame-ters in PCDs.Write PCDs in par. 8-42.xx, and read PCDs in par.8-43.xx. These PCDs are accessible via holdingregisters 28xx and 29xx.•Write control word: Par. 8-42.0 and par. 8-42.1 areset to the control word and as reference, respec-tively. Set par. 8-42[2-63] to the par. no. to write to.•Start-stop: Write the control word to register 2810to start or stop the converter.Read notes•The reference register is 2811 with 0 - 4000hex(0-100%).•Read status word: Par. 8-43.0 and par. 8-43.1 areset to status word and main actual value, respec-tively. Set par. 8-43[2-63] to the par. no. to readfrom.Figure 5Location of terminal 53Bit Bit value = 0Bit value = 100Reference value External selection LSB01Reference value External selection MSB02DC brake Ramp03Coasting No coasting04Quick stop Ramp05Hold output frequency Use ramp06Ramp stop Start07No function Rest08No function Jog09Ramp 1Ramp 210Data invalid Data valid11Relay 01 open Relay 01 active12Relay 02 open Relay 02 active13Parameter set-up Selection LSB14< Not used >< Not used >15No function ReverseTable 2.Control word bit positions•Read status word: Read the status word from reg-ister 2910.Other notes•Set the speed, i.e. the main actual value, with reg-ister 2911.•Read the configuration of par. 8-43.3.. with regis-ter 2912.•To configure a PCD to read a 32bit parameter re-quires configuration of two consecutive PCDs to the same parameter. For example, the parameter 16-10 Power [kW] is a 32bit integer, which may be configured in par. 8-43.2 and 8-43-3, or par. 8-43.4 and 8-43.5 and so on.The sizes of the different parameters are available in the programming guide.•To address parameters directly use the register no. = parameter no. x 10. For example, the par. 16-90 is accessible via register no 16900.•Some PLCs have 0 offsets, which means the value 1 must be subtracted from the register no. For ex-ample, reg. 2810 is 2809 etc.00Control not ready Control ready 01Drive not ready Drive ready 02Coasting Enable 03No error Trip04No error Error (no trip)05Reserved -06No error Triplock 07No warningWarning08Speed reference Speed = reference 09Local operationBus control10Out of frequency limit Frequency limit ok 11No operation On operation12Drive ok Stopped, auto start 13Voltage ok Voltage exceeded 14Torque ok Torque exceeded 15Timer okTimer exceededTable 3.Status word bit positionsNovenco Building & Industry A/S Industrivej 22Tel. +45 70 77 88 994700 Naestved Denmark7.Reference documentation•Danfoss Operating guideVLT ® HVAC basic drive FC 101Publication no. MG18AA02, 04/2018•Danfoss Programming guide VLT ® HVAC basic drive FC 101Publication no. MG18B502, 04/2018•Danfoss Design guideVLT ® HVAC basic drive FC 101Publication no. MG18C802, 04/2018•Danfoss Operating guide VLT ® HVAC drive FC 102Publication no. MG16O202, 04/2018•Danfoss Programming guide VLT ® HVAC drive FC 102Publication no. MG11CE02, 03/2015•Danfoss Design guide VLT ® HVAC drive FC 102Publication no. MG11BC02, 06/20148.Patents and trademarksNovenco ®ZerAx ® is a registered trademark of Novenco Building & Industry A/S.AirBox™ and NovAx™ are trademarks of Novenco Building & Industry A/S.VLT ® is a registered trademark of Danfoss A/S.The ZerAx ® processes of manufacture, technologies and designs are patented by Novenco A/S or Novenco Building & Industry A/S.Pending patents include Brazil no. BR-11-2012-008607-3, BR-11-2012-008543-3, BR-11-2012-008545-0, BR-11-2014-002282-8 and BR-11-2014-002426-0; India no. 4140/CHENP/2012, 4077/CHENP/2012, 821/CHENP/2014 and 825/CHENP/2014; PCT no. EP2012/064908 and EP2012/064928; South Korea no. 10-2012-7012154.Granted patents include Canada no. 2.777.140,2.777.141, 2.777.144, 2.832.131 and 2.843.132; China no. ZL2010800458842, ZL2010800460965, ZL2010800464275 and ZL2012800387210; EU no. 2488759, 2488760,2488761, 2739860 and 2739861; India no. 312464; South Korea no. 10-1907239, 10-1933724, 10-1980600 and 10-2011515; US no. 8.967.983, 9.200.641, 9.273.696 B2,9.683.577 and 9.926.943 B2. Granted designs include Bra-zil no. BR-30-2012-003932-0; Canada no. 146333; China no. 1514732, 1517779, 1515003, 1555664 and 2312963; EU no. 001622945-0001 to 001622945-0009 and 001985391 - 0001; India no. 246293; South Korea no. 30-0735804; US no. D665895S, D683840S, D692119S, D704323S,D712023S, D743018S, D755363S, D756500S, D821560S and D823452S.The NovAx Basic jet fans manufacturing processes, technologies and designs are patented by Novenco A/S or Novenco Building & Industry A/S.Granted patents include EU no. 2387670 and United Arab Emirates no. 1372. Granted designs include EU no. 001069884-0003, 001069884-0008, 001069884-0010, 001069884-0013, 001069884-0017, 001069884-0019, 001069884-0022, 001069884-0026 and 001069884-0028; United Arab Emirates no. D223/2009.The CGF jet fans designs are patented by Novenco A/S or Novenco Building & Industry A/S.Granted designs include EU no. 001610643-0001 to 001610643-0005.Copyright © 2016 - 2020,Novenco Building & Industry A/S.All rights are reserved.9.Declaration of conformityRefer to the declaration information in the documenta-tion for the fans and frequency converters.Figure 6QR code to this guide onPure competence in air. ttt͘EKs E Kͳ h/> /E'͘ KD。

FC Series 120 Watt Regulated High Voltage DC Power Supplies1 to 60kV, 1.75” PanelCE CompliantThe FC Series are sophisticated,120 Watt, high voltage power supplies in a small and lightweight package. They are air insulated, fast response units with tight regulation.Fully compliant with the European harmonized EMI directive, EN50082-2, and with the low voltage (safety) directive, 73/23/EEC.Line harmonics are within the European harmonized standard,EN61000-3-2 specifications.FeaturesL ow Stored Energy.Most modelsexhibit less than 1 joule ofstored energy.Pulse-Width Modulation.Off-the-line-pulse-width modulation provides highefficiency and a reduced parts countfor improved reliability.Air Insulated.The FC Series features“air” as the primary dielectricmedium. No oil or encapsulationis used to impede serviceabilityor increase weight.Constant Voltage/Constant CurrentOperation.Automatic crossover fromconstant-voltage to constant-currentregulation provides protection againstoverloads, arcs, and short circuits.Low Ripple.Ripple is less than 0.02%of rated voltage at full load.Tight Regulation.Voltage regulationis better than 0.005% for allowableline and load variations. Currentregulation is better than 0.05%from short circuit to rated voltage.Front Panel Controls.Separate10-turn controls with locking vernierdials are used to set voltage andcurrent levels. A high voltage enable(on) switch and an AC power on/offswitch complete the panel controls.L.E.D.’s indicate when high voltage ison, the output polarity, and whetherthe supply is operating in a voltage orcurrent regulating mode. For the blankpanel version, only a power on/offswitch is provided on the panel.Remote Control Facilities. Asstandard, all FC Series suppliesprovide output voltage and currentprogram/monitor signals, highvoltage enable, safety interlockterminals, and a +10 voltreference source.Small Size and Weight.FC Seriespower supplies occupy only 1.75inches of panel height. Net weightis less than 12 pounds.Warranty. Standard power suppliesare warranted for three years; OEMand modified power supplies arewarranted for one year. A formalwarranty statement is available.Models from 0 to 1kV through 0 to 60kV, 1.75” H x 19” W x 20.25” D, 12 lbs.C he ckt hes pe cs…a ndc omp ar eDesigning Solutions for High Voltage Power Supply ApplicationsGLASSMAN HIGH VOLTAGE INC.124 West Main Street,PO Box 317,High Bridge,NJ 08829-0317(908) 638-3800 • Fax (908) 638-3700 • GLASSMAN EUROPE Limited (UK)GLASSMAN JAPAN High Voltage Limited +44 1256 883007 FAX +44 1256 883017 +81 45 902 9988 FAX+81 45 902 2268 E-mail:******************************E-mail:*****************************©Glassman High Voltage, Inc.Printed in the U.S.A. B 12/18/2003program/monitor, HV enable, ground,and local control. A rear panel toggle switch selects either local or remote operation.External Interlock: Open off, closed on. Normally latching except for blank panel version where it is non-latching.Specifications(Specifications apply from 5 to 100%rated voltage. Operation is guaranteed down to 0% of rated voltage with aslight degradation of ripple, regulation, and stability.)Input: 102-132V RMS, single-phase, 48-420 Hz, <2.5A. Connectorper IEC 320 with mating line cord terminated with NEMA 5-15 plug.Efficiency:Typically 80% at full load.Output:Continuous, stable adjust-ment,from 0 to rated voltage or current by panel mounted 10-turn potentiometers with 0.05% resolution, or by external 0to 10V signals is provided. Voltage accuracy is 0.5% of setting +0.2% of rated. Repeatability is <0.1% of rated.Stored Energy:See Models chart.Static Voltage Regulation:Better than 0.005% for specified line variations and 0.005% + 0.5 mV/mA for load variations.Dynamic Voltage Regulation:For load transients from 10% to 100% and 100%to 10%, typical deviation is 2% of output voltage with recovery to within 1% in 500 µs and to 0.1% in 1 ms.Ripple:<0.02% of rated voltage plus 300mV RMS at full load.Current Regulation: Better than 0.1%from short circuit to rated voltage at any load condition.Voltage Monitor:0 to +10 V equivalent to 0 to rated voltage. Accuracy, 0.5% of reading +0.2% rated.Current Monitor:0 to +10 V equivalent to 0 to rated current. Accuracy, 1% of reading +0.05% rated. Reversible polar-ity models: 1% of reading + 0.1% of rated.Stability: 0.01% per hour after 1/2 hour warmup, 0.05% per 8 hours.Voltage Rise/Decay Time Constant:400 ms typical with a 10% resistive load using either HV on/off or remote programming control.Temperature Coefficient:0.01% per degree C.Ambient Temperature:-20 to +50 degrees C, operating; -40 to +85 degrees C, storage.Polarity:Available with either positive, negative, or reversible polarity with respect to chassis ground.Protection:Automatic current regulation protects against all overloads, including arcs and shorts. Fuses, surge-limiting resistors, and low energy components provide ultimate protection.Remote Controls: A five position terminal block and a 15 Pin “D”connector are provided for all remote functions, including common, +10 V reference, interlock, voltage and currentDesigning Solutions for High Voltage Power Supply ApplicationsGLASSMAN HIGH VOLTAGE INC .124 West Main Street,PO Box 317,High Bridge,NJ 08829-0317(908) 638-3800 • Fax (908) 638-3700 • OptionsSymbol Description10090 to 110VRMS input, 48-420Hz. NEMA 5-15 Plug. 220198 to 250VRMS input, 48-420Hz. NEMA 6-15 Plug. NC Blank front panel, power switch only.CTCurrent trip. Power supply trips off when the load current reaches the programmed level. This option has a rear panel switch that selects either “trip” operation or current limiting.ZR Zero start interlock. Voltage control, local or remote, must be atzero before HV will enable.SS Slow start ramp. Specify standard times of 1, 2, 3, 5, 10, 15, 20,or 30 s +/- 20%.X130-5 V voltage and current program/monitor.HVS High voltage status indicator. Normally open relay contactsthat close when HV is enabled. Contacts are rated for 24VDC at 1A maximum.Please consult factory for special requirements.Remote HV Enable:0-1.5 V off, 2.5-15 V on.Accessories:Detachable 8 foot shielded high voltage coaxial cable (see Models chart for cable type), 6 foot detachable line cord, and mating 15 Pin “D” connec-tor and shell are provided.ModelsPositive Negative Reversible Output Output Stored Output PolarityPolarityPolarityVoltageCurrentEnergyCableFC1P120FC1N120FC1R1200 - 1kV 0 - 120mA 0.2 J RG - 58FC1.5P80FC1.5N80FC1.5R800 - 1.5kV 0 - 80mA 0.45 J RG - 58FC2P60FC2N60FC2R600 - 2kV 0 - 60mA 0.1 J RG - 58FC3P40FC3N40FC3R400 - 3kV 0 - 40mA 0.2 J RG - 58FC5P24FC5N24FC5R240 - 5kV 0 - 24mA 0.3 J RG - 58FC6P20FC6N20FC6R200 - 6kV 0 - 20mA 0.25 J RG - 8U FC8P15FC8N15FC8R150 - 8kV 0 - 15mA 0.3 J RG - 8U FC10P12FC10N12FC10R120 - 10kV 0 - 12mA 0.4 J RG - 8U FC12P10FC12N10FC12R100 - 12kV 0 - 10mA 0.7 J RG - 8U FC15P8FC15N8FC15R80 - 15kV 0 - 8mA 1.1 J RG - 8U FC20P6FC20N6FC20R60 - 20kV 0 - 6mA 0.85 J RG - 8U FC25P4.8FC25N4.8FC25R4.80 - 25kV 0 - 4.8mA 1 J RG - 8U FC30P4FC30N4FC30R40 - 30kV 0 - 4mA 1 J RG - 8U FC40P3FC40N3FC40R30 - 40kV 0 - 3mA 1.5 J RG - 8U FC50P2.4FC50N2.4FC50R2.40 - 50kV 0 - 2.4mA 2 J RG - 8U FC60P2FC60N2FC60R20 - 60kV0 - 2mA2.4 JRG - 8U。