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I'm not into online adventures 'cause my web-line well, not. Survive freezing cold temperatures, explore loot-filled dungeons, develop your character from a lowly peasant to a mighty barbarian, and fight to dominate your enemies in epic siege wars.

Conan Exiles can be played in full single-player, co-op, or persistent online multiplayer. After Conan himself saves your life by cutting you down from the corpse tree, you must quickly learn to survive.

The Admin Panel is a technical game mechanic in Conan Exiles. It provides access to many of the game's items, creatures, thralls and enemies.

It is also possible to alter character stats. The Admin Panel as seen on PS4. You may use this section to report any bugs or technical issues you're experiencing with the game or to report connectivity problems and unexpect 2: August 28, PS4 Patch Archive. In this thread you can find all the updates, patches and hotfixes that. Conan Exiles; About This File. Then enable it in the game. Instructions Press the vocalize key at anytime and your character will cat-call.

Use this when you want to let someone know you're checking them out, or you want to have sex, or you're just. Conan Exiles is an online multiplayer survival game, now with mounts and mounted combat, set in the lands of Conan the Barbarian.

Enter a vast, open-world sandbox and play together with friends and strangers as you build your own home or even a shared city. Survive freezing cold temperatures, explore loot-filled dungeons, develop your character from a lowly peasant to a mighty barbarian, and. Bis jetzt. Wie kann ich mehrere Tiere auf ein Mal mitnehmen? Ich habe. Weather scouring sandstorms, shield yourself from intense temperatures and hunt animals for food and resources.

Explore a vast and seamless world, from the burning desert in the south to the. Cheats pour Conan Exiles. So after i played conan exiles on pc for a bit i now moved onto ps4 cause of some friends and yeah even there the game is Press J to jump to the feed. Press question mark to learn the rest of the keyboard shortcuts. Log In Sign Up. User account menu. Chat on Ps4. Posted by 2 years ago.

So after i played conan exiles on pc for a bit i now. Exile Architect makes it onto the Best Conan Exiles Building Mods list for it's ability to really add that extra attention to detail with your bases.

It features a stunning set of fences, gates and bridges which can really help make some cool looking bases, personally I've used the bridges as an entrance to my island base, pretty awesome. Pour localiser un serveur disponible : Cliquez sur l'option « Montrer les serveurs invalides » dans la liste des serveurs, puis cliquez sur l'un des serveurs disponibles.

Sur BattlEye, allez dans Affichage - Serveurs. Exiles de Conan : L'ex. Server Status. Max Distance. We are now able to query server names and player counts. We have removed all filters, ability to view server rules, and other information.

These features could be available again, but we are prohibited from providing them by the Funcom. Join us for a new pvp experience with RP raiding, events, admin shops, a 10x drop rate, KoD, and active and helpful admins! Come check us out today. The more detail you provide for your issue and question, the easier it will be for other MSI Windbox DE owners to properly answer your question. This manual comes under the category Desktops and has been rated by 3 people with an average of a 7.

This manual is available in the following languages: English. Is your question not listed? Index Copyright Notice Trademarks U. Ask a question. Related product manuals. Because the transmitter being used for this test was not the one actually being used on the field test and because the calibration is a costly and time consuming task, the results of these tests were used to indicate only that such calibration should be performed on the actual transmitters prior to their installation at the Collins plant.

Calibration data was not prepared for the heater box test. During the heater box test an Acurex transmitter was mounted in the rotor coupling bolt hole and six of the thermocouples from the bore system were connected to it.

Telemetry Antenna Mounted to Rotor in Heater Box Test Facility output from the telemetry systems demultiplexer was fed to a volt meter and scanner system that in turn outputs the data to a teleprinter, The printed record consisted of six thermocouple readings, the capsule temperature, the two capsule calibration voltages, and the time when the data was sampled.

The comparison between measured and calculated results are illustrated in Figure A-I1. The location of the thermocouples measured during the heater box test is shown in Figure A Only data for five of the six channels of the transmitter was available because of a connection failure.

Comparison Between Measured Temperatures from Heater Box Test and Calculations During Shutdown axisymmetric heat conduction computer programs that were used to analyze the field test results. The system operated successfully and the only failure was a thermocouple connection. Calibration of Transmitters The three telemetry transmitters for measuring the rotor bore temperatures were received from Acurex Corporation after approximately 12 months delay because of a redesign problem the manufacturer encountered.

The calibration technique used for a single transmitter for the heater box test is illustrated in Figure A The three transmitters were set up in much the same fashion; the one difference was that an oi! The calibration was proceeding satisfactorily when several inputs of the telemetry capsule multiplexer failed.

The capsules were returned to the supplier for examination and repair which took approximately a month.

When the capsules were returned a factory representative examined the test set up to see if he could determine the cause of the failures. His examination revealed a rather complex failure mode and he concluded that there was a rather high common mode voltage existing between our salt bath and the secondary coil of the inductive power supply.

Also, the way the thermocouples were being soldered to the transmitters allowed a conducting salt path from the acid flux to form to the transmitters case. After this repair, calibrations were run on the transmitters.

Telemetry Transmitter Calibration Test Block Diagram These two positions were shorted at the capsule with thermocouple wires to avoid any additional problems. Since there are two thermocouples at each bore location, we were still able to obtain data from these locations. The rotor bore temperature telemetry systen initially gave reasonable data on all of the active channels but as the test progressed over the first few months it had two problems: The first was that the signals were responding to exciter voltages and appeared to be a function of turbine speed, The other was the demodulating card in the telemetry receiver for one of the transmitters required a field repair by the ge problem.

When the unit was shut down for strainer removal, frayed wires in the transmitters and associated wiring were supplier to correct a high calibration vol: repaired where possible, but since the wire paths into the rotor bore down the coupling face were not accessible, repair and inspection was limited, Table A-l lists the status of the telemetry systen after the July inspection and repair.

Thermocouple Now n 12 1B u 15 16 uv 18 Transmitter No. P, Dummy 1. Thermocouple TR15 is functioning properly while TRI6 drops sharply with increasing speed, a condition probably due to centrifugal force causing frayed wires in the rotor bore to have another contact point. The calibration constant of the transmitter Number 3 was corrected based on the assumption that the faulty transmitter should read the average value of the other two transmitters. This transmitter is the one that had its demodulating card repaired in July of , Even when data isn't available at load, the values of the majority of the remaining thermcouples cone into general agreement on turning gear.

Therefore, rotor cool-down data is still available. In November of the end of the project turbine bearing Number 3 was opened to install lift pumps which exposed the turbire coupling that contained the telemetry transmitter.

It was decided to check the calibrations of the three transmitters and hopefully resolve the discrepancies in the calibration, especially the one transmitter that had continuously given higher readings. The calibration check consisted of injecting a known millivolt signal into one or more input channels on each of two of the three transmitters.

The input channels chosen were ones which were known to have shorted or open thermocouples. The analysis of the calibration test confirms that transmitter nunber 2 gave results that agree with the original calibration. Transmitter nunber 1, which could not be calibrated while we were at the site because work was being done on the turbine bearings, and the rotor could not be rotated, gives data that agrees with transmitter number 2, Because of this agreement we concluded that the original calibration for transmitter number 1 is still valid.

Inspection of the thermocouple wire during the above calibration showed additional fraying of the insulation since the last inspection. Also, the transmitter and the Micarta sleeve did not slide in and out very easily in the bolt holes. This is probably due to sone deformation in the Micarta sleeve insulator. If this test is ever repeated additional design consideration should be given to removing the capsule with a jacking screw or puller assenbly.

The cover plates over the trans- mitters successfully prevented any appreciasle amount of oi] from the bearing housing getting into the capsule area. The general conclusion that can be made about the temperature telemetry test is that even with the problem that occurred the trarsmitters were still all functioning after almost two years of operation. It is highly recommended that if this test is repeated that a better thermocouple insulation material be used, A sheathed thermocouple should be used but this will require sone sort of transition to a flexible thermocouple extension wire before aeW?

Turbine and cycle data used to estinate turbine stresses and obtain heat transfer correlations. Boiler metal temperatures to estimate boiler stresses. Cycle conditions and control parameters for model validation. Some data points serve more than one purpose. Compromises were made on the amount.

For example, no redundancy exists for cycle steam conditions, since most of these sensors could be replaced. In addition, the power plant was designed with a limited number of sensor locations available. Diagram for Collins Test A simplified block diagram, Figure A, of the instrumentation for the test at the Collins Plant shows the transducers and thermocouples added to the turbine and boiler and the interconnection for the data acquisition systen.

The primary purpose of this diagram was to provide the interface information by which Sargent and Lundy prepared the cable routing drawings for the test. Das Svs. This list groups data points according to the type of measurement. In addition, the tabulation indicates the origin of the signal. Error No Exist. Temp, Error No Exist. TGA-1 Gas Temp.

Probe North Yes Exist. TGA-1a Gas Temp. Probe South Yes Exist. Yes Exist. TGA-6 Sec. Air Temp. TGA-7 Sec. TGA Gas Temp. Plenum N. Plenum S. Tsh-3 Cold Reheat Steam Temp. Steam Temp. Stage 2 Temp. Inlet Temp. Yes x Tse? Ext Stm, Temp, to 54 Her. Yes Exist, Sig. Spray Attenp. Ne Yes Exist. Pot S. Wer, Spray Attemp. Wer, Spray Attenp. Sig, F6 S. Fer Rul Water Spray Attenp. Bypass tm, Flow Yes Exist. F9 Ss. Stm, Attenp. Fo10 RAH, Sat. F 51 GR Fan Mtr. Anps Yes Exist. F Main O11 Flow to Exist. F Cond.

Flow to Deaerator Wo Exist. Poa Turbine Throttle Press, ves Exist. No Ww P Extr. No w Paz Cond. Narrow Range Yes Exist. P Sec, S. H, Outlet Yes Exist. P-l7 Furnace Press. No Exist. P18 Turb, First Stg. Med Additive Viv. Position Yes Exist. MT Ist Stg. M8 Ist Stg. Meg 2nd Stg. Viv, M10 and Stg. Attemp, Viv. Nel Rell. Spray Viv. Me13 Turb, Diff. Pickup 2A No Exist. No14 Tur. Casing Expansion No Exist.

Nels: Brg. Hdr, Btm. Bottom Bir. Top Bir. Outlet Hdr. Top Near S. Inner Cyl. Base Gen. Cover Gov. Base Extr. Base Bir. Continuous sheath thermocouples are being used for the low pressure extractions since the piping and thermal wells for these therno- couples are in the neck of the condenser, Therefore, sheath thermocouples provide protection against damage by high velocity wet steam.

The low pressure inlet thermocouple was included in the group since it could provide a backup during installation and could be installed at a later date if needed. These thermocouples were ordered in advance of the other cycle steam thermocouples to ensure that they would be available before work in the condenser was finished. The thermocouples are Chromel-Alumel for the same reasons that the stationary metal thermocouples are this type. Most of the thermocouples were calibrated by themselves without extension wires, except the throttle, hot reheat, and cold reheat thermocouples which were calibrated with their respective connection wires to maximize the accuracy of these readings.

For the most part the thermocouples are sheath thermocouples with a bullet head brazed to the tip. The turbine metal thermocouples are all chromel-alumel, type K.

This choice was made for two reasons, For the quantity ordered, the material was more readily available than the type E thermocouples, and for installation reasons. Since the sheath were routed through the turbine after installing the junction, the sheath cannot be cut to the proper length and transitions made to standard wire until the routing is complete. Since alumel is slightly magnetic the use of the K thermocouple allows for simple identification of the wires after cutting the sheath to its proper length.

The specific nunber identifying the thermocouple and its Tocation in the turbine is stenciled on the thermocouples bullet head and on the sheath at the cold junction to aid in identification during assenbly.

The thermocouples were checked with x-ray and electrically at volts to ensure that the junctions were ungrounded. The thermocouples were also cycled thermally to check integrity.

Premium grade wire was chosen and the thernocouples were calibrated at seven temperatures above the ice point, These calibrations were used in the Westinghouse data reduction program. New thermocouple locations were added to provide information that was being obtained from standard turbine metal thermocouples at Eddystone.

This was required since all the spare Junctions supplied were being used at Collins Unit 5. The thermocouple installation techniques were previously used on another unit. The low pressure turbine installation was completely new since this particular Tow pressure turbine is a different design than the one that was previously instrumented. The view shows thermocouple HP leaving the inner cylinder through a fitting and joining another group of thermocouples crossing over to the outer cylinder and suoported along the entire length.

Figure A shows a closer view of this grouping and the supporting of the thermo- couples. Note how the wires are supported along the support lug of the inner cylinder onto the outer cylinder, The wires are then fed into the holes in the outer cylinders to exit the turbine. Thermocouples are not routed straight across to the next wall but are supported with clips around the inside fo the flange. Figure A shows the same area fron anotter angle. The supporting of thermocouples is important in the extraction zones to ensure thermocouple reliability.

Figure A shows the region where the low pressure thermocouples cross over from the inner cylinder to the outer cylinder before exiting from the turbine. A second supplier's transmitters were chosen for the remaining locations where Westinghouse installed transmitters for the program. Tris selection was made to reduce cost.

The transmitters pressure ranges were selected to cover the range of operation expected during testing. Special consideration was given to the first stage and cold reheat pressure transmitters. The extraction flow was established using a differential pressure transmitter and cold reheat pressure transmitter.

The differential pressure transmitters reading, however, could not be correlated with flow satisfactorily. Therefore, IP flows were obtained by alternate methods. The transducers are all 4 to 20 ma output type transducers and each was calibrated with the series resistance across which the data system measured voltage in the installation at Collins, 11 transducers calibrated well within the plus or minus.

The transducers were calibrated against the Westinghouse Steam Turbine Division Gilmore pressure calibration standard. The pressure transducers were then shipped to Collins for installation. The delay was caused by the fact that the string of high pressure feedwater heaters and the gas recircu- lation fans were not brought into service until August.

The station then started conducting heat rate tests. The boiler steam path thermocouple measurenents were delayed because the thermocouples for this project were mistakenly installed for the routine plant service thermocouples.

Once this error was uncovered by Babcock and Wilcox, some delay was incurred before replacement thermocouples could be obtained. The plant heat rate tests started in August. Because the cold reference junction wasn't functioning properly, Conmonwealth Edison personnel disconnected the thermocouples needed to conduct their tests and inserted their own thermo- couples.

The most important of these thermocouples were main steam and hot reheat steam. The first stage pressure transmitter failed in December, and was replaced with a transmitter borrowed from Westinghouse in January, The failed transmitter was repaired and recalibrated.

Rather than replace the repaired transmitter a swap was made with Westinghosue for the installed transmitter. Considerable calibration changes were required for the LP pressure transmitters because of zero drift and slope changes. These transmitters were supplied as a cost saving item for the low pressure turbine. Other calibration changes were required since a few of the Bailey Meter transmitters had different calibrations than were was specified for the job.

Installation THE 9-H inner cylinder bolt. The main problem encountered with the tengerature instrumentation was with the thermocouple reference junction. However, when it was operating correctly, it gave excellent results and it was convenient te connect and use.

The Power supply failure was an inconvenience but repairable. After the units were replaced, the operation was satisfactory even though the refrigeration cycle time was excessive.

In addition to the operating software supplied by Hewlett Packard, a relay driver was also incorporated into the system to interface with the relay interrupt circuit from the generator breaker contacts.

A general description of each of the six programs will follow. This program also indirectly scheduled the logging program through the use of a program called DAYFL. DAYFL determined that all equipment was on and functioning before it scheduled the logging program.

Failure of any DAS equipment to operate stopped the operation of the program and caused error messages to be written on the computer display console. Each time this program was scheduled it took one sample of every point of data and recorded the raw data on the magnetic tape.

This program was the means to detect the state of the display switches on the computer and run various options of this program depending upon the state of the switches. INTRP was scheduled to operate each time the computer sensed that the generator circuit breaker relay had changed state, which occurs when the generator was synchronized or tripped off line. This program ran continuously once it was turned on, Its function was to sample selected variables and determine if they have varied by a predetermined ancunt.

This program examined the variation of the variables and selected a time interval, which it then used to schedule the logging program. The selected time intervals were 3, 6 or 12 minutes. The time intervals and variation limits could be changed from the console.

This program also had the option of selecting various modes of operation depending upon which display switches on the computer were selected. Data could be outputted as raw data or, in engineering units, on either the display console or the printer. This program provided for on-line plotting of the 10 variables in engineering units on the printer, The plotting mode automatically disabled the printer from printing data. The display unit could still output data in this mode of operation. This technique made it possible to use only two scanners and signal conditioners at the remote portion of the data system.

The major components of the system located in the electrical equipment room were the computer, display console, tape recorder, digital voltmeter, printer, clock, and the other two scanners.

The use of scanners at the remote location reduced the amount of cabling between the turbine and the electrical equipment room. A block diagram of the data acquisition system is shown in Figure B AI] equipment was mounted in standard 19 inch racks.

The equipment racks supplied with the system had lockable doors, front and rear. The remote cabinet, located on the turbine floor, was the cabinet in which the data system was origi. This cabinet was modified somewhat for the test.

The modifications consisted of cutting an access hole in the base of the cabinet to route in the turbine metal thermocouples and moving the cooling fan and power access panel to the top rear of the rack fram the bottom rear, The rear door was also lowered 8 inches to accommodate the cooling fan. The local cabinet, in the electrical equipment room, was a double width unit with double doors front and rear. This cabinet was identical to the type of cabinet which Westinghouse uses for the Digital Electric Hydraulic Control System.

The remote cabinet contained four half-shells and the local cabinet eight half-shells. These half-shells permitted the cable connections to be made to standard industrial type terminations instead of the electronic type termination that the data system used. The complete data system and cable termination half-shells were premounted in their racks to ensure that all pieces would fit properly with ample room for working.

The data system was then removed and the cabinets shipped to the site. The listings of the programs used to control the data acquisition system are listed on the following pages. FE 2,1. DeLay co To 31 4 wrrTect. This program applied the appropriate sensor calibrations, A set of new variables calculated from input data was a'so calculated in COLLI. High pressure extraction heater drain flow calculated from pressure drop and valve position Wi57D.

In addition, the program provides for printing and plotting of the data for any group of variables over any desired period of time. Lo soz soz foe ene tne oye. Love sore wove. Loe one. He eve 2ue we one. ASCL is a simulation language. Pages D-7 through include the user input sheets for the various modules. The schematic of the plant model is shown as Figures and D-7, These figures show the interconnection of the model and provide the "ID" for use with the module input sheets.

The model parameters were calculated for MW and are listed in table D The KAD signifies that the number represents the cross sectional area of the steam drum in square feet. The DF is the module identifier in the boiler interconnection schematic. Pages D through contain the program listing, The use of this program requires a working knowledge of the ASCL simulation language. Volume of Saturated Region ft? Figures through show the individual components used to assemble the model.

FALSEs ,. These summaries include two basic sets of information. The first identifies the conditions prior to starting on each day that the unit was started and the load fron which the unit was tripped. The second set of data includes information during the operation of the unit. This valve is intended to highlight significant changes in operational efficiency for future evaluations, A final project summary is included which provides the basis for the operational summary data presented in Section 4.

The models used to simulate the open loop tests and modifications for the startup and shutdown runs are described in Section 5.

Macros are written for the components and then invoked in the ACSL model. One requirement of this structure is that each identifier exists once and only once on the left side of an assignnent statement, unless it is generated in a procedural.

The macros in the Modular Modeling System make use of the ACSL concatenation operator to automatically generate names for the variables in the program.

Exceotions to this rule occur at the model boundaries and in the simplified models wrich were not generated by macros. Examples of several identifiers are: GPL Enthalpy of the stream GPL in this case enthalpy of of flue gas leaving the platen superheater. In this case, tube metal temperature in the platen superheater. Each module is described in the following pages. The user worksheets which show information flow for the module, interface variables and other information are shown in Appendix D.

Steam Properties All of the steam properties are generated from curve fits. Some are from a single function and some are over regiows and matched at the boundaries. Any discontinuities, particularly in pressure, will result in drastic increases in computation cost.

In the turbine calculations, isentropic enthalpy change across a blade group wes calculated by calculating S P , H and then H Pp, S. This turned out to be poor choice because it places high accuracy requirements on the steam properties involved. This accuracy was not achieved and as a result, turbine power calcu- ations were less accurate then desired. A better approach would have been to generate a curve fit for isentropic enthalpy change directly.

Examination of P, H diagram having lines of constant entropy indicates that such a function would fit fairly easily as a function of pressure ratio, inlet enthalpy, and inlet pressure, It would be mich easier to achieve acceptable accuracy in this way than in the method used in the model. The attemperator sprays water into a steam flow path to reduce steam superheat and provide steam tenperature control.

The module accounts for pressure loss through the steam path and pressure loss through the spray control valve and spray nozzle. The spray path line friction, expansion, and mixing losses are assumed secondary to the control valve losses.

This module models the pressure losses in the two flow streams and the enthalpy drop through the attemperator. The pressure losses are derived from the modified Bernoulli relation and assume that both flow streams may be regarded as incompressible. F-2 The spray valve flow coefficient, Z, is a function of the valve position, spray pipe resistance, and valve flow characteristic.

The valve position, Y, may be set manually by the user, calculated by the actuator model ACT, or, where the user wishes to neglect actuator response, calculated directly by the user defined control system.

This module performs a strict mathematical function within the Modular Model ing System, serving to allow resistive type midules to be interconnected. Resistive modules require upstream and downstream pressure as inputs in order to define the flowrate through the component, A typical combination of two resistive type modules, a valve followed by a turbine, is sketched in Figure F Except for the simplest configuration for incompressible flow, this problem must be solved by a trial and error or iterative numerical technique.

The objective of this technique is to determine the unique value of the intermediate pressure Po , which provides the same flow rate through both components. The problem, basically a fluid mechanics problem, may be thought of as a controls problem. In this control problem a process variable, the intermediate pressure is to be controlled to minimize a control error, the flow rate mismatch.

The particular gain which best represents the function differs for compressible and incompressible flow. For incompressible flow a G of 1. The leaving enthalpy equals the entering enthalpy, and the other required outlet properties are determined as a function of the known pressure and enthalpy.

Divider Module The divider module DIV allows the user to branch from a single flow path to as many as nine separate flow paths, They are used to represent one or more tees, manifolds, or multiple inlets to a single component. The DIV modules have no physical parameters.