/// <summary>
        /// Monitors the flow rate and adjustes voltage to pump as necessary in
        /// order to maintain desired flowrate.
        /// </summary>
        protected override void Run()
        {
            try
            {
                if (!Pump.IsRunning())
                {
                    return;
                }

                ConsoleState state = Master.ConsoleService.CurrentState;
                if (state == ConsoleState.Diagnosing || state == ConsoleState.InteractiveDiagnostics)
                {
                    return;
                }

                int openedPosition = Pump.GetOpenValvePosition();

                if (openedPosition > 0)
                {
                    DateTime openTime = Pump.GetTimePumpStarted();
                    DateTime now      = DateTime.UtcNow;

                    Log.Debug(string.Format("Opened solenoid {0} at {1}", Pump.GetOpenValvePosition(), Log.DateTimeToString(openTime)));

                    Pump.FlowStatus flowStatus = Pump.CheckFlow();

                    if (flowStatus != Pump.FlowStatus.TooLow)
                    {
                        _flowFailures = 0;
                        if ((openTime != DateTime.MinValue) && ((now - openTime) > _periodAllowedOpen))
                        {
                            Pump.CloseValve(openedPosition);   // Close the valve.
                        }
                    }
                    // Else, assumption is that FlowStatus is TooLow. (empty cylinder?)
                    else if (((now - openTime) > _minOpenPeriod) &&
                             Pump.IsRunning())
                    {
                        _flowFailures++;
                        Log.Debug("Flow failed " + _flowFailures + " times.");

                        if (_flowFailures >= _MIN_FLOW_FAILURES)
                        {
                            _flowFailures = 0;
                            Pump.CloseValve(openedPosition);
                        }
                        else
                        {
                            Pump.OpenValve(Pump.GetOpenValvePosition(), false);
                        }
                    }
                }
            }
            catch (Exception e)
            {
                Log.Error(Name, e);
            }
        }
示例#2
0
        private void PrepValve(int valveId)
        {
            if ( valveId < 1 || valveId > Configuration.DockingStation.NumGasPorts )
            {
                Log.Debug("PrepValve given invalid valve value = " + valveId.ToString());
                return;
            }

            Pump.OpenValve(valveId, false);
            Thread.Sleep(500);
            Pump.CloseValve(valveId, false);
        }
示例#3
0
		/// <summary>
		/// Check if gas port solenoids work properly.
		/// </summary>
		/// <param name="details">The string to hold details.</param>
		private void TestSolenoids( DetailsBuilder details )
		{
			// close all valves and stop pump
			Pump.CloseAllValves( true );

			for ( int portNum = 1; portNum <= Configuration.DockingStation.NumGasPorts; portNum++ )
			{
				/* DIAGNOSTIC_SOLENOID_CURRENT */

				// give the valves a chance to finish closing
				Thread.Sleep( 500 );

				// get the closed current counts (c1)
				int countsClosed = Controller.Get12VCurrent();

				// open valve
				Pump.OpenValve( portNum, false );

				// wait at least 500 ms
				Thread.Sleep( 500 );

				// get the open current counts (c2)
				int countsOpen = Controller.Get12VCurrent();

				// close the valve that was opened
				Pump.CloseValve( portNum );

				// convert current counts to milliamps (mA)
				int currentClosed = CountToCurrent( countsClosed );
				int currentOpen = CountToCurrent( countsOpen );

				// DSX solenoids are designed to use 180 mA to remain open 
				int currentSolenoid = currentOpen - currentClosed;
				
				// counts for min limit provided by Engineering (Bryan Pavlisko); 
				// 20 counts is 160 mA which is approximately 10% below 180 mA
				int COUNTS_MIN_LIMIT = 20;
				bool solenoidCheckFailed = false;

				// fail if c2 - c1 < 20
				solenoidCheckFailed = ( countsOpen - countsClosed ) < COUNTS_MIN_LIMIT;

				// report the results
				_gdpList.Add( new GeneralDiagnosticProperty( "DIAGNOSTIC_SOLENOID_" + portNum + "_CURRENT_CLOSED", countsClosed.ToString() ) );
				_gdpList.Add( new GeneralDiagnosticProperty( "DIAGNOSTIC_SOLENOID_" + portNum + "_CURRENT_OPEN", countsOpen.ToString() ) );
				_gdpList.Add( new GeneralDiagnosticProperty( "DIAGNOSTIC_SOLENOID_" + portNum + "_CURRENT_MILLIAMPS", currentSolenoid.ToString() ) );
				_gdpList.Add( new GeneralDiagnosticProperty( "DIAGNOSTIC_SOLENOID_" + portNum + "_CURRENT_PASSED", ( !solenoidCheckFailed ).ToString() ) );

				// log the results
				ReportDiagnostic( details, details.GetText( "SOLENOID_CURRENT_" + portNum ), countsClosed, countsOpen, solenoidCheckFailed );
			}
		}
示例#4
0
 public virtual void CloseValve(int id, bool stopPump)
 {
     Pump.CloseValve(id, stopPump);
 }
示例#5
0
 public virtual void CloseValve(int id)
 {
     Pump.CloseValve(id);
 }
示例#6
0
		/// <summary>
		/// Test the specified solenoid
		/// </summary>
		/// <param name="details">The string to hold details.</param>
		private void TestFlow( DetailsBuilder details, int solenoid )
        {
            // Validate the solenoid number
            if ( solenoid < 1 || solenoid > Configuration.DockingStation.NumGasPorts )
            {
                Log.Debug( "TestFlow:  Invalid solenoid value = " + solenoid.ToString() );
                return;
            }

            Log.Debug( "TestFlow: port=" + solenoid.ToString() );

            // Determine whether a cylinder is attached to this port.  
            // If there is one attached, skip this test.
            DockingStation ds = Controller.GetDockingStation();
            GasEndPoint gasEndPoint = ds.GasEndPoints.Find(m => m.Position == solenoid);
            if (gasEndPoint != null && gasEndPoint.Cylinder.IsFreshAir == false)
            {
                Log.Debug( "TestFlow: Cylinder attached to port " + solenoid.ToString() + "; SKIPPING THIS TEST." );
                return;
            }

            Pump.DoCheckFlow = true;

            // Ensure that only the specified solenoid is open.
            Pump.CloseAllValves( true );
            Thread.Sleep(500); // Give the valves a chance to finish closing
            Pump.OpenValve(solenoid, false); // Open the specified solenoid
            Thread.Sleep(500); // Pause at least 500ms.

            Pump.SetDesiredFlow( Pump.StandardFlowRate);
            Pump.Start( Pump.StandardStartVoltage );  // Turn on the pump.

            Thread.Sleep( 3000 ); // Wait for it to stabilize the flow before letting CheckFlow take its first reading.

            // CheckFlow could enter an infinite loop if it's unable to 
            // establish the desired flow rate and we don't tell it to time out.
            // We therefore give it a time out of a minute which should be more than sufficient.


            ushort rawFlowCounts;
            ushort rawVacuumCounts;
            Pump.FlowStatus flowStatus = Pump.CheckFlow( new TimeSpan( 0, 1, 0 ), out rawFlowCounts, out rawVacuumCounts );

            byte pumpVoltage = Pump.GetPumpVoltage(); // obtain and hold onto final voltage of the pump, to report it to inet.

            // Get the flow rate.
            ushort flowVolts = Pump.ConvertRawFlowToVolts( rawFlowCounts );

            int flowRate = Pump.CalculateFlowRate( flowVolts, rawVacuumCounts );  // Convert that value to mL/min

            // Report the results.
            string flowString = BuildFlowString(flowRate, flowVolts);
            // We create a property for every value used to compute the flow rate, and also the flow rate itself.
            _gdpList.Add( new GeneralDiagnosticProperty( "DIAGNOSTIC_CHECK_FLOW_" + solenoid + "_VACUUM", rawVacuumCounts.ToString() ) );
            _gdpList.Add( new GeneralDiagnosticProperty( "DIAGNOSTIC_CHECK_FLOW_" + solenoid + "_VACUUM_INCHES", Pump.ConvertRawVacuumToInches( rawVacuumCounts ).ToString() ) );
            _gdpList.Add( new GeneralDiagnosticProperty( "DIAGNOSTIC_CHECK_FLOW_" + solenoid, rawFlowCounts.ToString() ) );
            _gdpList.Add( new GeneralDiagnosticProperty( "DIAGNOSTIC_CHECK_FLOW_" + solenoid + "_VOLTS", flowVolts.ToString() ) );
            _gdpList.Add( new GeneralDiagnosticProperty( "DIAGNOSTIC_CHECK_FLOW_" + solenoid + "_RATE", flowRate.ToString() ) );
            _gdpList.Add( new GeneralDiagnosticProperty( "DIAGNOSTIC_CHECK_FLOW_" + solenoid + "_PUMP_VOLTS", pumpVoltage.ToString() ) );
            // The flow is considered a failure if it's not equal to the StandardFlowRate plus/minus the standardtolerance
            bool flowFailed = flowRate < ( Pump.StandardFlowRate - Pump.FLOWRATE_TOLERANCE ) || flowRate > ( Pump.StandardFlowRate + Pump.FLOWRATE_TOLERANCE );
            // TODO - we should rename the translation string so that it's prefixed with "CHECK_FLOW" instead of "SOLENOID_FLOW"
            ReportDiagnostic( details, details.GetText( "SOLENOID_FLOW_" + solenoid ), flowString, flowFailed );

            // Check Pump Error Status -- FAIL IF STATE IS 1
            int pumpErrorState = Pump.GetPumpErrorState();

            // Report the results.
            _gdpList.Add( new GeneralDiagnosticProperty( "DIAGNOSTIC_CHECK_FLOW_" + solenoid + "_PUMP_ERROR", pumpErrorState.ToString() ) );
            // TODO - we should rename the translation string so that it's prefixed with "CHECK_FLOW" instead of "SOLENOID_FLOW"
            ReportDiagnostic(details, details.GetText("SOLENOID_PUMP_ERROR_" + solenoid), pumpErrorState.ToString(), (pumpErrorState == 1));

            // Stop the pump and close the solenoid
            Pump.CloseValve(solenoid);

            Pump.DoCheckFlow = false;
        }
示例#7
0
        /// <summary>
        /// Check if pump works properly.
        /// </summary>
        /// <remarks>
        /// Engineering Notes: This step is to check if pump works properly.
        /// Run pump at two different control voltages, check the flow rate difference between these two cases.
        /// </remarks>
        /// <param name="details">The string to hold details.</param>
        private void TestPump(DetailsBuilder details)
        {
            // Find a port without a gas cylinder connected. 
            // If all ports are connected, skip this test.
            DockingStation ds = Controller.GetDockingStation();

            // First, see if port one is unconnected or is providing FRESH AIR
            // Note: we are trying ports in the order of 3-2-1 so as to avoid pulling air through the filter, if possible.
            int testPort = -1;
            GasEndPoint gasEndPoint = null;
            for ( int solenoid = Configuration.DockingStation.NumGasPorts; solenoid >= 1 && testPort <= 0; solenoid-- )
            {
                gasEndPoint = ds.GasEndPoints.Find(m => m.Position == solenoid);
                if (gasEndPoint == null || gasEndPoint.Cylinder.IsFreshAir)
                    testPort = solenoid;
            }

            if (testPort <= 0)
            {
                Log.Debug("TestPump:  could not find open solenoid; this test will be skipped.");
                return;
            }

            // Open solenoid valve determined to be unconnected
            Pump.CloseAllValves( true );
            Thread.Sleep(500); // Give the valves a chance to finish closing
            Pump.OpenValve(testPort, false);

            // Start pump with pump voltage of 80
            Pump.Start(80);

            // Wait 3 seconds
            Thread.Sleep(3000);

            // Read flow 1
            ushort flowCount1 = Pump.GetRawFlow();
            ushort flowVolts1 = Pump.ConvertRawFlowToVolts( flowCount1 );
            ushort vacuumCounts1 = Pump.GetRawVacuum();

            int flowRate1 = Pump.CalculateFlowRate( flowVolts1, vacuumCounts1 );
            string flowString1 = BuildFlowString(flowCount1, flowRate1, flowVolts1);

            // Increase pump voltage to 240
            Pump.SetNewPumpVoltage(240);

            // Wait 3 seconds
            Thread.Sleep(3000);

            // Check Pump Error status
            int pumpErrorState = Pump.GetPumpErrorState();

            // Fail if state is 1
            _gdpList.Add(new GeneralDiagnosticProperty("DIAGNOSTIC_PUMP_ERROR_STATUS", pumpErrorState.ToString()));
            ReportDiagnostic(details, DiagnosticResources.PUMP_ERROR_STATUS, pumpErrorState.ToString(), (pumpErrorState == 1));

            // Read flow 2
            ushort flowCount2 = Pump.GetRawFlow();
            ushort flowVolts2 = Pump.ConvertRawFlowToVolts( flowCount2 );
            ushort vacuumCounts2 = Pump.GetRawVacuum();
            int flowRate2 = Pump.CalculateFlowRate( flowVolts2, vacuumCounts2 );
            string flowString2 = BuildFlowString(flowCount2, flowRate2, flowVolts2);

            // Fail if f2 - f1 < 100 OR f2 - f1 > 450
            _gdpList.Add(new GeneralDiagnosticProperty("DIAGNOSTIC_PUMP_F1", flowCount1.ToString()));
            _gdpList.Add(new GeneralDiagnosticProperty("DIAGNOSTIC_PUMP_F2", flowCount2.ToString()));
            ReportDiagnostic(details, DiagnosticResources.PUMP, flowString1, flowString2, ( flowCount2 - flowCount1 < 100 ) || ( flowCount2 - flowCount1 > 450 ) );

            // Stop the pump and close the port used for this test
            Pump.CloseValve(testPort);
            Thread.Sleep(500);
        }
示例#8
0
        /// <summary>
        /// Check for leaks.
        /// </summary>
        /// <remarks>
        /// This is to check if the components in the closed gas delivery system work properly including
        /// tubing, 3 solenoid valves, manifolds, check valves, vacuum sensor, flow sensor and pump.
        /// The pump failure to operate could also cause this test to fail.
        /// If a leakage is found, flow check will be meaningless.
        /// </remarks>
        /// <param name="details">The details to fill in.</param>
        private void TestForLeak(DetailsBuilder details)
        {
            Pump.CloseAllValves( true );

            Thread.Sleep( 500 ); // Give the valves a chance to finish closing

            int pumpVoltage = 80; // initial voltage for leak test
            bool leakCheck1Failed = true;
            ushort vac1Raw;
            double vac1Inches;
            string vac1String;
            const int maxPumpVoltage = 120;
            const ushort rawInches40 = 360;
            const int inches40 = 40;
            const int pumpVoltageIncrement = 10;
            //const ushort rawInches55 = 466;
            //const int inches55 = 55;

            Pump.Start( pumpVoltage ); // start pump with initial voltage

            //Suresh 19-JUNE-2012 INS-3067
            do
            {
                // After changing pump voltage, always wait 1 second before reading  
                // vacuum sensor to give the sensor time to adjust to the change.
                Thread.Sleep( 1000 );

                // Take vacuum reading (vac1)
                vac1Raw = Pump.GetRawVacuum();
                vac1Inches = Pump.ConvertRawVacuumToInches( vac1Raw );
                vac1String = BuildCountAndUnitString( vac1Raw, vac1Inches, 1, "\"" );

                Log.Debug( string.Format( "Vacuum: {0}, Pump voltage: {1}", vac1String, pumpVoltage ) );

                // Check vacuum reading against target pressure.  Pass after we reach or exceed target.
                if ( vac1Raw >= rawInches40 )
                {
                    // Pass if vac1 >= 40 inches of water
                    leakCheck1Failed = false;
                    Log.Debug( string.Format( "Leak Check 1 PASSED. (vacuum exeeds {0}\")", inches40 ) );
                    break;
                }

                if ( pumpVoltage + pumpVoltageIncrement >= maxPumpVoltage )// if the pump voltage crests above 120 
                {
                    Log.Debug( string.Format( "Leak Check 1 FAILED (pump voltage exeeds {0} but vacuum under {1}\")", maxPumpVoltage, inches40 ) );
                    break;
                }

                pumpVoltage += pumpVoltageIncrement;

                Pump.SetNewPumpVoltage( (byte)pumpVoltage ); // set the new voltage to pump

            } while ( true );

            _gdpList.Add( new GeneralDiagnosticProperty( "DIAGNOSTIC_LEAK_CHECK_VAC1", vac1Raw.ToString() ) );
            _gdpList.Add( new GeneralDiagnosticProperty( "DIAGNOSTIC_LEAK_CHECK_VAC1_INCHES", vac1Inches.ToString() ) );
            _gdpList.Add( new GeneralDiagnosticProperty( "DIAGNOSTIC_LEAK_CHECK_VAC1_PASSED", (!leakCheck1Failed).ToString() ) );
            _gdpList.Add( new GeneralDiagnosticProperty( "DIAGNOSTIC_LEAK_CHECK_VAC1_PUMP_VOLTAGE", pumpVoltage.ToString() ) );
            ReportDiagnostic( details, DiagnosticResources.LEAK_CHECK_1, vac1String, leakCheck1Failed );

            int vacuumError = Pump.GetVacuumErrorState(); // Check status of Vacuum Error by calling GetVacuumErrState()

            _gdpList.Add( new GeneralDiagnosticProperty( "DIAGNOSTIC_LEAK_CHECK_VAC_ERROR", vacuumError.ToString() ) );
            //Pass no matter what the state is [Vacuum Error Status]. The purpose is to keep the data structure of the report same as previous version. 
            ReportDiagnostic( details, DiagnosticResources.VACUUM_ERROR_STATUS, vacuumError.ToString(), false );

            // Stop pump
            Pump.Stop();

            //Open Solenoid #1 for 1 second to relieve the pressure
            Pump.OpenValve( 1, false );
            Thread.Sleep( 1000 ); // 1 sec
            Pump.CloseValve( 1 ); 
        }