private void Keyb_OutCnData(string cn) { if (ISHAVEDY) { if (!ISHAVEVOLATE) { string[] a = mv.ListboxItemsources.ToArray(); mv.ListboxItemsources.RemoveAt(mv.ListboxItemsources.Count - 1); PhysicalVariable need = NumericsConverter.Text2Value(cn); mv.ListboxItemsources.Add("待测电压 :" + need); mv.ListboxItemsources.Add(a[a.Length - 1]); } else { string[] a = mv.ListboxItemsources.ToArray(); mv.ListboxItemsources.RemoveAt(mv.ListboxItemsources.Count - 1); mv.ListboxItemsources.RemoveAt(mv.ListboxItemsources.Count - 1); PhysicalVariable need = NumericsConverter.Text2Value(cn); mv.ListboxItemsources.Add("待测电压 :" + need); mv.ListboxItemsources.Add(a[a.Length - 2]); mv.ListboxItemsources.Add(a[a.Length - 1]); } } else { PhysicalVariable need = NumericsConverter.Text2Value(cn); mv.ListboxItemsources.Add("待测电压 :" + need); } }
// private bool ISHAVEVOLATE = false; private void Keyb_OutDYData(string cn) { if (!ISHAVEDY) { PhysicalVariable need = NumericsConverter.Text2Value(cn); mv.ListboxItemsources.Add("待测电晕 :" + need); ISHAVEDY = true; } else { if (ISHAVEVOLATE) { string[] b = mv.ListboxItemsources.ToArray(); mv.ListboxItemsources.RemoveAt(mv.ListboxItemsources.Count - 1); mv.ListboxItemsources.RemoveAt(mv.ListboxItemsources.Count - 1); PhysicalVariable need = NumericsConverter.Text2Value(cn); mv.ListboxItemsources.Add("待测电晕 :" + need); mv.ListboxItemsources.Add(b[b.Length - 1]); } else { mv.ListboxItemsources.RemoveAt(mv.ListboxItemsources.Count - 1); PhysicalVariable need = NumericsConverter.Text2Value(cn); mv.ListboxItemsources.Add("待测电晕 :" + need); } } }
private void Keyb_OutVolateData(string cn) { if (ISHAVEDY) { if (!ISHAVEVOLATE) { if (time.Text == "") { time.Text = "60"; } PhysicalVariable need = NumericsConverter.Text2Value(cn); mv.ListboxItemsources.Add("持续时间 :" + time.Text + ":" + " 耐 压:" + need); ISHAVEVOLATE = true; } else { if (time.Text == "") { time.Text = "60"; } mv.ListboxItemsources.RemoveAt(mv.ListboxItemsources.Count - 1); PhysicalVariable need = NumericsConverter.Text2Value(cn); mv.ListboxItemsources.Add("持续时间 :" + time.Text + ":" + "耐 压 :" + need); } } }
private void Keyb_OutCnTanData(string cntan) { CnTanButton.Content = cntan; PhysicalVariable need = NumericsConverter.Text2Value(cntan); Models.AutoStateStatic.SState.AGn = need; }
private static Models.SysAutoTestResult GetSys(ObservableCollection <string> ListboxItemsources) { // Models.AutoStateStatic.SState.Clear(); Models.SysAutoTestResult sys = new Models.SysAutoTestResult(); var tpd = ListboxItemsources.ToArray(); for (int i = 0; i < tpd.Length - 2; i++) { string[] Usedata = tpd[i].Split(':'); if (Usedata.Length == 2) { // Usedata[i] = Usedata[i].Trim(); sys.NeedTestList.Add((float)NumericsConverter.Text2Value(StaticClass.DeleteSpace(Usedata[1])).value); } } string[] Usedata1 = tpd[tpd.Length - 2].Split(':'); sys.IsEleY = true; sys.IsVolate = true; sys.EleY = (float)NumericsConverter.Text2Value(StaticClass.DeleteSpace(Usedata1[1])).value; string[] p = tpd[tpd.Length - 1].Split(':'); sys.EleVolate = (float)NumericsConverter.Text2Value(StaticClass.DeleteSpace(p[3])).value; try { sys.HideTime = Convert.ToInt32(StaticClass.DeleteSpace(p[1])); } catch { sys.HideTime = 60; // ShowHide("键入的耐压保持时间格式错误" + "\t\n" + "以设置为默认60S"); } return(sys); }
private void Keyb_OutCnData(string cn) { if (ISHAVEDY) { if (!ISHAVEVOLATE) { string[] a = (this.DataContext as MainWindowModel).ProjectVolate.ToArray(); (this.DataContext as MainWindowModel).ProjectVolate.RemoveAt((this.DataContext as MainWindowModel).ProjectVolate.Count - 1); PhysicalVariable need = NumericsConverter.Text2Value(cn); (this.DataContext as MainWindowModel).ProjectVolate.Add("待测电压 :" + need); (this.DataContext as MainWindowModel).ProjectVolate.Add(a[a.Length - 1]); } else { string[] a = (this.DataContext as MainWindowModel).ProjectVolate.ToArray(); (this.DataContext as MainWindowModel).ProjectVolate.RemoveAt((this.DataContext as MainWindowModel).ProjectVolate.Count - 1); (this.DataContext as MainWindowModel).ProjectVolate.RemoveAt((this.DataContext as MainWindowModel).ProjectVolate.Count - 1); PhysicalVariable need = NumericsConverter.Text2Value(cn); (this.DataContext as MainWindowModel).ProjectVolate.Add("待测电压 :" + need); (this.DataContext as MainWindowModel).ProjectVolate.Add(a[a.Length - 2]); (this.DataContext as MainWindowModel).ProjectVolate.Add(a[a.Length - 1]); } } else { PhysicalVariable need = NumericsConverter.Text2Value(cn); (this.DataContext as MainWindowModel).ProjectVolate.Add("待测电压 :" + need); } }
private void pF_Click(object sender, RoutedEventArgs e) { try { int a = System.Text.RegularExpressions.Regex.Matches(ResultTextBox.Text, @"V").Count; if (a == 0) { ResultTextBox.Text += "V"; } PhysicalVariable tpd = NumericsConverter.Text2Value(ResultTextBox.Text); if (Flag == 1) { OutCnData(NumericsConverter.Value2Text((double)tpd.value, 4, -13, "", SCEEC.Numerics.Quantities.QuantityName.Voltage)); } if (Flag == 2) { OutVolateData(NumericsConverter.Value2Text((double)tpd.value, 4, -13, "", SCEEC.Numerics.Quantities.QuantityName.Voltage)); } if (Flag == 3) { OutDYData(NumericsConverter.Value2Text((double)tpd.value, 4, -13, "", SCEEC.Numerics.Quantities.QuantityName.Voltage)); } if (Flag == 4) { OutProjectVolate(NumericsConverter.Value2Text((double)tpd.value, 4, -13, "", SCEEC.Numerics.Quantities.QuantityName.Voltage)); } this.Close(); } catch { ShowHide("输出数据格式出错"); } }
private void Confire_click(object sender, RoutedEventArgs e) { PhysicalVariable tpd = NumericsConverter.Text2Value(ResultTextBox.Text); // NumericsConverter.Value2Text(tpd,4,percentage:true); OutCnTanData(NumericsConverter.Value2Text(tpd, percentage: true)); this.Close(); }
public static void BushingDCInsulation(ref MeasurementItemStruct mi, Transformer transformer, JobList Job) { Parameter.JYDZstation position; if (mi.Winding == WindingType.HV) { position = Parameter.JYDZstation.高压套管A + (((int)mi.Terimal[0] + 3) % 4); } else { position = Parameter.JYDZstation.中压套管A + (((int)mi.Terimal[0] + 3) % 4); } switch (mi.state) { case 0: byte[] TestKindData = TZ3310.SetPraJydz(position, GetParameter.GetPraBushingDCInsulationVoltage(Job), 50, GetParameter.GetPraDCInsulationResistance(Job), GetParameter.GetPraDCInsulationAbsorptionRatio(Job), 0); Thread.Sleep(100); TZ3310.StartTest(TestKindData); mi.stateText = "正在测试" + position.ToString() + "末屏中..."; mi.state++; Thread.Sleep(4000); break; case 1: string[] Recbuffer = TZ3310.ReadTestData(Parameter.TestKind.绝缘电阻); Thread.Sleep(150); if (Recbuffer != null) { PhysicalVariable[] Volate = new PhysicalVariable[1]; if (Recbuffer[Recbuffer.Length - 1] == "0") { mi.Result = MeasurementResult.NewBushingDCInsulationResult(mi, NumericsConverter.Text2Value(Recbuffer[0]), NumericsConverter.Text2Value(Recbuffer[1]), NumericsConverter.Text2Value(Recbuffer[2]), null, false); } else if (Recbuffer[Recbuffer.Length - 1] == "1") { mi.Result = MeasurementResult.NewBushingDCInsulationResult(mi, Volate[0], NumericsConverter.Text2Value(Recbuffer[0]), NumericsConverter.Text2Value(Recbuffer[1]), NumericsConverter.Text2Value(Recbuffer[2]), true); mi.state++; mi.completed = true; mi.stateText = position.ToString() + "末屏测试完成"; } else { mi.failed = true; mi.completed = true; mi.stateText = mi.Winding + "错误类型:" + Recbuffer[0]; } } break; } }
public static void Capacitance(ref MeasurementItemStruct mi, Transformer transformer, JobList Job) { switch (mi.state) { case 0: byte[] TestKindData; if (!transformer.Coupling || mi.Winding == WindingType.LV) { TestKindData = TZ3310.SetPraJs(mi.Winding.ToJSstation(), Parameter.JSstyle.内接反接, GetParameter.GetPraCapacitanceVoltage(Job), Parameter.JSFrequency._45To_55HZ, 0); } else { TestKindData = TZ3310.SetPraJs(Parameter.JSstation.高中绕组, Parameter.JSstyle.内接反接, GetParameter.GetPraCapacitanceVoltage(Job), Parameter.JSFrequency._45To_55HZ, 0); } Thread.Sleep(100); TZ3310.StartTest(TestKindData); mi.stateText = "正在测试" + mi.Winding + "介损绕组中..."; mi.state++; Thread.Sleep(4000); break; case 1: string[] Recbuffer = TZ3310.ReadTestData(Parameter.TestKind.介质损耗); Thread.Sleep(150); if (Recbuffer != null) { if (Recbuffer[Recbuffer.Length - 1] == "0") { mi.Result = MeasurementResult.NewCapacitanceResult(mi, NumericsConverter.Text2Value(Recbuffer[1]), null, null , NumericsConverter.Text2Value(Recbuffer[2]), NumericsConverter.Text2Value(Recbuffer[3]), false); } else if (Recbuffer[Recbuffer.Length - 1] == "1") { mi.Result = MeasurementResult.NewCapacitanceResult(mi, NumericsConverter.Text2Value(Recbuffer[0]), NumericsConverter.Text2Value(Recbuffer[1]), NumericsConverter.Text2Value(Recbuffer[2]) , NumericsConverter.Text2Value(GetParameter.GetFreQuency(Parameter.JSFrequency._45To_55HZ)), NumericsConverter.Text2Value(Recbuffer[3]), true); mi.completed = true; mi.stateText = "读取" + mi.Winding + "绕组介损测试成功"; } else { mi.failed = true; mi.completed = true; mi.stateText = mi.Winding + "错误类型为:" + Recbuffer[0].ToString(); } } break; } }
public static void DoDCInsulation(ref MeasurementItemStruct mi, Transformer transformer, JobList Job) { switch (mi.state) { case 0: byte[] TestKindData; if (!transformer.Coupling || mi.Winding == WindingType.LV) { TestKindData = TZ3310.SetPraJydz(mi.Winding.ToJYDZstation(), GetParameter.GetPraDCInsulationVoltage(Job), 50, GetParameter.GetPraDCInsulationResistance(Job), GetParameter.GetPraDCInsulationAbsorptionRatio(Job), 0); } else { TestKindData = TZ3310.SetPraJydz(Parameter.JYDZstation.高中绕组, GetParameter.GetPraDCInsulationVoltage(Job), 50, GetParameter.GetPraDCInsulationResistance(Job), GetParameter.GetPraDCInsulationAbsorptionRatio(Job), 0); } Thread.Sleep(100); TZ3310.StartTest(TestKindData); mi.stateText = "开始测量" + mi.Winding + "绝缘电阻中..."; mi.state++; Thread.Sleep(4000); break; case 1: string[] Recbuffer = TZ3310.ReadTestData(Parameter.TestKind.绝缘电阻); if (Recbuffer != null) { PhysicalVariable[] Volate = new PhysicalVariable[1]; if (Recbuffer[Recbuffer.Length - 1] == "0") { mi.Result = MeasurementResult.NewDCInsulationResult(mi, NumericsConverter.Text2Value(Recbuffer[0]), NumericsConverter.Text2Value(Recbuffer[1]), NumericsConverter.Text2Value(Recbuffer[2]), null, false); Volate[0] = NumericsConverter.Text2Value(Recbuffer[0]); } else if (Recbuffer[Recbuffer.Length - 1] == "1") { mi.Result = MeasurementResult.NewDCInsulationResult(mi, Volate[0], NumericsConverter.Text2Value(Recbuffer[0]), NumericsConverter.Text2Value(Recbuffer[1]), NumericsConverter.Text2Value(Recbuffer[2]), true); mi.completed = true; mi.stateText = "读取" + mi.Winding + "绝缘电阻结果成功"; } else { mi.failed = true; mi.completed = true; mi.stateText = mi.Winding + "错误类型:" + Recbuffer[0]; } } break; } }
public static void BushingCapacitance(ref MeasurementItemStruct mi, Transformer transformer, JobList Job) { Parameter.JSstation Jsposition; if (mi.Winding == WindingType.HV) { Jsposition = Parameter.JSstation.高压套管A + (((int)mi.Terimal[0] + 3) % 4); } else { Jsposition = Parameter.JSstation.中压套管A + (((int)mi.Terimal[0] + 3) % 4); } switch (mi.state) { case 0: byte[] TestKindData = TZ3310.SetPraJs(Jsposition, Parameter.JSstyle.内接正接, GetParameter.GetPraCapacitanceVoltage(Job), Parameter.JSFrequency._45To_55HZ, 0); Thread.Sleep(100); TZ3310.StartTest(TestKindData); mi.stateText = "正在测试" + mi.Winding + "末屏中..."; mi.state++; Thread.Sleep(4000); break; case 1: string[] Recbuffer = TZ3310.ReadTestData(Parameter.TestKind.介质损耗); if (Recbuffer != null) { if (Recbuffer[Recbuffer.Length - 1] == "0") { mi.Result = MeasurementResult.NewBushingCapacitanceResult(mi, NumericsConverter.Text2Value(Recbuffer[1]), null, null , NumericsConverter.Text2Value(Recbuffer[2]), NumericsConverter.Text2Value(Recbuffer[3]), false); } else if (Recbuffer[Recbuffer.Length - 1] == "1") { mi.Result = MeasurementResult.NewBushingCapacitanceResult(mi, NumericsConverter.Text2Value(Recbuffer[0]), NumericsConverter.Text2Value(Recbuffer[1]), NumericsConverter.Text2Value(Recbuffer[2]) , NumericsConverter.Text2Value(GetParameter.GetFreQuency(Parameter.JSFrequency._45To_55HZ)), NumericsConverter.Text2Value(Recbuffer[3]), true); mi.completed = true; mi.stateText = "读取" + mi.Winding + "末屏测试完成"; } else { // mi.failed = true; mi.completed = true; mi.stateText = mi.Winding + "错误类型:" + Recbuffer[0].ToString(); } } break; } }
private string calcDF(PhysicalVariable AGx) { double tan = Math.Tan(pnv(AGx.value) - pnv(AGn.value)); if (Math.Abs(tan) < 0.0000005) { return("0.000%"); } if ((tan < 1e24) && (tan > -1e24)) { return(NumericsConverter.Value2Text(tan, 4, -5, "", SCEEC.Numerics.Quantities.QuantityName.None, percentage: true).Trim()); } else { return("NaN"); } }
private void Keyb_OutVolateData(string cn) { if (ISHAVEDY) { if (!ISHAVEVOLATE) { PhysicalVariable need = NumericsConverter.Text2Value(cn); (this.DataContext as MainWindowModel).ProjectVolate.Add("持续时间:" + Timecombobox.SelectedIndex.ToString() + ":" + " 耐 压:" + need); ISHAVEVOLATE = true; } else { (this.DataContext as MainWindowModel).ProjectVolate.RemoveAt((this.DataContext as MainWindowModel).ProjectVolate.Count - 1); PhysicalVariable need = NumericsConverter.Text2Value(cn); (this.DataContext as MainWindowModel).ProjectVolate.Add("持续时间:" + Timecombobox.SelectedIndex.ToString() + ":" + "耐 压 :" + need); } } }
private void nF_Click(object sender, RoutedEventArgs e) { try { int a = System.Text.RegularExpressions.Regex.Matches(ResultTextBox.Text, @"F").Count; if (a == 0) { ResultTextBox.Text += "nF"; } PhysicalVariable tpd = NumericsConverter.Text2Value(ResultTextBox.Text); OutCnData(NumericsConverter.Value2Text((double)tpd.value, 4, -13, "", SCEEC.Numerics.Quantities.QuantityName.Capacitance)); this.Close(); } catch { throw new Exception("结果值出错"); } }
private PhysicalVariable calcCap(PhysicalVariable Ix, PhysicalVariable AGx) { double angle = pnv(AGx.value); double ratio = pnv(Ix.value) / pnv(In.value); double zn = pnv(Cn.value) / Math.Cos(pnv(AGn.value)); double z = zn * ratio; double cp = z * Math.Cos(angle); double rp = z * Math.Sin(angle); double tan = Math.Tan(pnv(AGx.value) - pnv(AGn.value)); double cs = cp * (1 + tan * tan); if ((cs < 1e24) && (cs > -1e24)) { return(NumericsConverter.Value2Text(cs, 4, -13, "", SCEEC.Numerics.Quantities.QuantityName.Capacitance)); } else { return("NaN"); } }
private string calcPower(PhysicalVariable Ix, PhysicalVariable AGx) { double angle = pnv(AGx.value); double ratio = pnv(Ix.value) / pnv(In.value); double zn = pnv(Cn.value) / Math.Cos(pnv(AGn.value)); double z = zn * ratio; double cp = z * Math.Cos(angle); double rp = z * Math.Sin(angle); double tan = Math.Tan(pnv(AGx.value) - pnv(AGn.value)); double rs = cp * (tan * tan) / (1 + tan * tan); double i = pnv(Ix.value); double p = i * i * rs; if ((p < 1e24) && (p > -1e24)) { return(NumericsConverter.Value2Text(p, 4, -3, "", SCEEC.Numerics.Quantities.QuantityName.Power)); } else { return("NaN"); } }
private string calcVolt(PhysicalVariable Freq, PhysicalVariable C, PhysicalVariable I) { double freq = pnv(Freq.value); double c = pnv(C.value); double i = pnv(I.value); if (freq < 1.0) { return("0 V"); } if (c < 1e-13) { return("NaN"); } if (i < 1e-9) { return("0 V"); } double v = i / (2 * Math.PI * freq * c); return(NumericsConverter.Value2Text(v, 4, -1, "", SCEEC.Numerics.Quantities.QuantityName.Voltage)); }
private void WorkTest_OutTestResult(byte[] result) { OutTestResult(result); ViewSources vs = new ViewSources(result); this.TestFre = vs.TestFre; this.In = NumericsConverter.Value2Text(vs.TestIn, 4, -13, "", SCEEC.Numerics.Quantities.QuantityName.Capacitance); this.Ix1 = NumericsConverter.Value2Text(vs.TestIx1, 4, -13, "", SCEEC.Numerics.Quantities.QuantityName.Current); this.AG1 = vs.TestPh1.ToString("F6"); //NumericsConverter.Value2Text(vs.TestPh1, 4, -6, "", SCEEC.Numerics.Quantities.QuantityName.None); this.Ix2 = NumericsConverter.Value2Text(vs.TestIx2, 4, -13, "", SCEEC.Numerics.Quantities.QuantityName.Current); this.AG2 = vs.TestPh2.ToString("F6"); //NumericsConverter.Value2Text(vs.TestPh2, 4, -6, "", SCEEC.Numerics.Quantities.QuantityName.None); this.Ix3 = NumericsConverter.Value2Text(vs.TestIx3, 4, -13, "", SCEEC.Numerics.Quantities.QuantityName.Current); this.AG3 = vs.TestPh3.ToString("F6"); //NumericsConverter.Value2Text(vs.TestPh3, 4, -6, "", SCEEC.Numerics.Quantities.QuantityName.None); this.Ix4 = NumericsConverter.Value2Text(vs.TestIx4, 4, -13, "", SCEEC.Numerics.Quantities.QuantityName.Current); this.AG4 = vs.TestPh4.ToString("F6"); //NumericsConverter.Value2Text(vs.TestPh4, 4, -6, "", SCEEC.Numerics.Quantities.QuantityName.None); this.OneStata = NumericsConverter.Value2Text(vs.OneVolate, 4, -13, "", SCEEC.Numerics.Quantities.QuantityName.Voltage); this.Alarm = vs.AlarmStata.ToString(); StandardCapacitance = Cn.ToString(); StandardCapacitanceDissipationFactor = NumericsConverter.Value2Text(Math.Tan(pnv(AGn.value)), 4, -5, "", SCEEC.Numerics.Quantities.QuantityName.None, percentage: true).Trim(); HVFrequency = NumericsConverter.Value2Text(vs.TestFre, 4, -3, "", SCEEC.Numerics.Quantities.QuantityName.Frequency); HVVoltage = calcVolt(HVFrequency, Cn, In); Capacitance1 = calcCap(Ix1, AG1).ToString(); Capacitance2 = calcCap(Ix2, AG2).ToString(); Capacitance3 = calcCap(Ix3, AG3).ToString(); Capacitance4 = calcCap(Ix4, AG4).ToString(); Current1 = Ix1.ToString(); Current2 = Ix2.ToString(); Current3 = Ix3.ToString(); Current4 = Ix4.ToString(); DissipationFactor1 = calcDF(AG1); DissipationFactor2 = calcDF(AG2); DissipationFactor3 = calcDF(AG3); DissipationFactor4 = calcDF(AG4); Power1 = calcPower(Ix1, AG1); Power2 = calcPower(Ix2, AG2); Power3 = calcPower(Ix3, AG3); Power4 = calcPower(Ix4, AG4); }
/// <summary> /// 填充TCP接受的数据信息到数据源 /// </summary> /// <param name="ListboxItemsources">数据源</param> /// <param name="SysData">TCP接受的数据</param> public static ObservableCollection <string> FillListBoxTip(ObservableCollection <string> ListboxItemsources, byte[] SysData) { ThreadPool.QueueUserWorkItem(delegate { SynchronizationContext.SetSynchronizationContext(new System.Windows.Threading.DispatcherSynchronizationContext(Application.Current.Dispatcher)); SynchronizationContext.Current.Post(async pl => { ListboxItemsources.Add("远程数据显示\t\n若需要手动测量\t\n请设置电晕和耐压"); var a = StaticClass.GetDataForTcpAutoTest(SysData); foreach (var b in a.NeedTestList) { PhysicalVariable tpd = NumericsConverter.Text2Value(b.ToString() + "V"); ListboxItemsources.Add("待测电压 :" + tpd); } PhysicalVariable eley = NumericsConverter.Text2Value(a.EleY.ToString() + "V"); PhysicalVariable elevolate = NumericsConverter.Text2Value(a.EleVolate.ToString() + "V"); ListboxItemsources.Add("待测电晕 :" + eley); ListboxItemsources.Add("持续时间 :" + a.HideTime.ToString() + ":" + " 耐 压:" + elevolate); }, null); }); return(ListboxItemsources); }
private void Button_Click(object sender, RoutedEventArgs e) { t1.Text = NumericsConverter.Value2Text(1e-10, 2, -23, " ", "V", false, false); }
public static FourTestResult ReturntestTestData(FourTestResult AllTestResult, string Cn1, string Cn2, string Cn3, string Cn4, string Ag1, string Ag2, string Ag3, string Ag4, bool ISVOLATEFALSE) { if (ISVOLATEFALSE) { if (AllTestResult.PanelEnable) { PanelResult p1 = new PanelResult { Cn = NumericsConverter.Text2Value(Cn1), CnTan = NumericsConverter.Text2Value(Ag1) }; AllTestResult.Panel1Result.Add(p1); } if (AllTestResult.Pane2Enable) { PanelResult p2 = new PanelResult { Cn = NumericsConverter.Text2Value(Cn2), CnTan = NumericsConverter.Text2Value(Ag2) }; AllTestResult.Panel2Result.Add(p2); } if (AllTestResult.Pane3Enable) { PanelResult p3 = new PanelResult { Cn = NumericsConverter.Text2Value(Cn3), CnTan = NumericsConverter.Text2Value(Ag3) }; AllTestResult.Panel3Result.Add(p3); } if (AllTestResult.Pane4Enable) { PanelResult p4 = new PanelResult { Cn = NumericsConverter.Text2Value(Cn4), CnTan = NumericsConverter.Text2Value(Ag4) }; AllTestResult.Panel4Result.Add(p4); } return(AllTestResult); } else { if (AllTestResult.PanelEnable) { PanelResult p1 = new PanelResult { Cn = NumericsConverter.Text2Value("0pF"), CnTan = NumericsConverter.Text2Value("0") }; AllTestResult.Panel1Result.Add(p1); } if (AllTestResult.Pane2Enable) { PanelResult p2 = new PanelResult { Cn = NumericsConverter.Text2Value("0pF"), CnTan = NumericsConverter.Text2Value("0") }; AllTestResult.Panel2Result.Add(p2); } if (AllTestResult.Pane3Enable) { PanelResult p3 = new PanelResult(); p3.Cn = NumericsConverter.Text2Value("0pF"); p3.CnTan = NumericsConverter.Text2Value("0"); AllTestResult.Panel3Result.Add(p3); } if (AllTestResult.Pane4Enable) { PanelResult p4 = new PanelResult(); p4.Cn = NumericsConverter.Text2Value("0pF"); p4.CnTan = NumericsConverter.Text2Value("0"); AllTestResult.Panel4Result.Add(p4); } return(AllTestResult); } }
public static void DCResistance(ref MeasurementItemStruct mi, Transformer transformer, JobList Job) { if (mi.Terimal != null) { Parameter.ZldzStation Dcposition; if (mi.Winding == WindingType.HV) { Dcposition = (Parameter.ZldzStation)(Parameter.ZldzStation.高压全部 + (((int)mi.Terimal[0]) % 4));//1 } else if (mi.Winding == WindingType.MV) { Dcposition = (Parameter.ZldzStation)(Parameter.ZldzStation.中压全部 + (((int)mi.Terimal[0]) % 4));//5 } else { Dcposition = (Parameter.ZldzStation)(Parameter.ZldzStation.低压全部 + (((int)mi.Terimal[0]) % 4));//9 } switch (mi.state) { case 0: byte[] TestKindData = TZ3310.SetPraZldz((Parameter.ZldzWindingKind)mi.WindingConfig, Dcposition, GetParameter.GetPraDCResistanceCurrent(Job), 0); Thread.Sleep(100); TZ3310.StartTest(TestKindData); WorkingSets.local.IsEnablestable = true; mi.stateText = "正在测试" + mi.Winding + "直流电阻中..."; mi.state++; Thread.Sleep(4000); break; case 1: string[] Recbuffer = TZ3310.ReadTestData(Parameter.TestKind.直流电阻); if (Recbuffer != null) { if (Recbuffer[Recbuffer.Length - 1] == "0") { PhysicalVariable[] Voltage = { NumericsConverter.Text2Value(Recbuffer[0]), NumericsConverter.Text2Value(Recbuffer[3]), NumericsConverter.Text2Value(Recbuffer[6]) }; PhysicalVariable[] Current = { NumericsConverter.Text2Value(Recbuffer[1]), NumericsConverter.Text2Value(Recbuffer[4]), NumericsConverter.Text2Value(Recbuffer[7]) }; PhysicalVariable[] Resistance = { NumericsConverter.Text2Value(Recbuffer[2]), NumericsConverter.Text2Value(Recbuffer[5]), NumericsConverter.Text2Value(Recbuffer[8]) }; mi.Result = MeasurementResult.NewDCResistanceResult(mi, Voltage, Current, Resistance, false); mi.state++; //测量结束数据需要确定 mi.stateText = "读取" + mi.Winding + "直流电阻数据中..."; //临时 Thread.Sleep(500); } else { // mi.failed = true; mi.completed = true; mi.stateText = mi.Winding + "错误类型:" + Recbuffer[0].ToString(); } } break; case 2: string[] Recbuffer1 = TZ3310.ReadTestData(Parameter.TestKind.直流电阻); if (Recbuffer1 != null) { if (Recbuffer1[Recbuffer1.Length - 1] == "0") { PhysicalVariable[] Voltage = { NumericsConverter.Text2Value(Recbuffer1[0]), NumericsConverter.Text2Value(Recbuffer1[3]), NumericsConverter.Text2Value(Recbuffer1[6]) }; PhysicalVariable[] Current = { NumericsConverter.Text2Value(Recbuffer1[1]), NumericsConverter.Text2Value(Recbuffer1[4]), NumericsConverter.Text2Value(Recbuffer1[7]) }; PhysicalVariable[] Resistance = { NumericsConverter.Text2Value(Recbuffer1[2]), NumericsConverter.Text2Value(Recbuffer1[5]), NumericsConverter.Text2Value(Recbuffer1[8]) }; mi.Result = MeasurementResult.NewDCResistanceResult(mi, Voltage, Current, Resistance, false); if (WorkingSets.local.IsStable == true) { mi.Result = MeasurementResult.NewDCResistanceResult(mi, Voltage, Current, Resistance, true); TZ3310.InterRuptMe(Parameter.CommanTest.判断直流电阻稳定状态); Thread.Sleep(500); WorkingSets.local.IsStable = false; mi.stateText = "确定" + mi.Winding + "直流电阻稳定成功"; //临时 Thread.Sleep(500); mi.stateText = "读取" + mi.Winding + "直流电阻数据成功"; //临时 mi.state++; } } else { // mi.failed = true; mi.completed = true; mi.stateText = mi.Winding + "错误类型:" + Recbuffer1[0].ToString(); //临时 } } break; case 3: string[] Recbuffer2 = TZ3310.ReadTestData(Parameter.TestKind.直流电阻); if (Recbuffer2 != null) { if (Recbuffer2[Recbuffer2.Length - 1] == "1") { mi.stateText = mi.Winding + "直流电阻测试完成:"; mi.completed = true; } else { // mi.failed = true; mi.completed = true; mi.stateText = mi.Winding + "错误类型:" + Recbuffer2[0].ToString(); //临时 } } break; } } else { switch (mi.state) { case 0: byte[] TestKindData = TZ3310.SetPraZldz((Parameter.ZldzWindingKind)mi.WindingConfig, mi.Winding.TozldzStation(), GetParameter.GetPraDCResistanceCurrent(Job), 0); Thread.Sleep(100); TZ3310.StartTest(TestKindData); WorkingSets.local.IsEnablestable = true; mi.stateText = "正在测试" + mi.Winding.TozldzStation() + "直流电阻中..."; mi.state++; Thread.Sleep(4000); break; case 1: string[] Recbuffer = TZ3310.ReadTestData(Parameter.TestKind.直流电阻); if (Recbuffer != null) { if (Recbuffer[Recbuffer.Length - 1] == "0") { PhysicalVariable[] Voltage = { NumericsConverter.Text2Value(Recbuffer[0]), NumericsConverter.Text2Value(Recbuffer[3]), NumericsConverter.Text2Value(Recbuffer[6]) }; PhysicalVariable[] Current = { NumericsConverter.Text2Value(Recbuffer[1]), NumericsConverter.Text2Value(Recbuffer[4]), NumericsConverter.Text2Value(Recbuffer[7]) }; PhysicalVariable[] Resistance = { NumericsConverter.Text2Value(Recbuffer[2]), NumericsConverter.Text2Value(Recbuffer[5]), NumericsConverter.Text2Value(Recbuffer[8]) }; mi.Result = MeasurementResult.NewDCResistanceResult(mi, Voltage, Current, Resistance, false); mi.state++; mi.stateText = "等待" + mi.Winding + "直流电阻稳定中..."; } else { // mi.failed = true; mi.completed = true; mi.stateText = mi.Winding + "错误类型" + Recbuffer[0].ToString(); } } break; case 2: string[] Recbuffer1 = TZ3310.ReadTestData(Parameter.TestKind.直流电阻); if (Recbuffer1 != null) { if (Recbuffer1[Recbuffer1.Length - 1] == "0") { PhysicalVariable[] Voltage = { NumericsConverter.Text2Value(Recbuffer1[0]), NumericsConverter.Text2Value(Recbuffer1[3]), NumericsConverter.Text2Value(Recbuffer1[6]) }; PhysicalVariable[] Current = { NumericsConverter.Text2Value(Recbuffer1[1]), NumericsConverter.Text2Value(Recbuffer1[4]), NumericsConverter.Text2Value(Recbuffer1[7]) }; PhysicalVariable[] Resistance = { NumericsConverter.Text2Value(Recbuffer1[2]), NumericsConverter.Text2Value(Recbuffer1[5]), NumericsConverter.Text2Value(Recbuffer1[8]) }; mi.Result = MeasurementResult.NewDCResistanceResult(mi, Voltage, Current, Resistance, false); if (WorkingSets.local.IsStable == true) { mi.Result = MeasurementResult.NewDCResistanceResult(mi, Voltage, Current, Resistance, true); TZ3310.InterRuptMe(Parameter.CommanTest.判断直流电阻稳定状态); WorkingSets.local.IsStable = false; mi.stateText = "确定" + mi.Winding + "直流电阻稳定成功"; Thread.Sleep(500); mi.stateText = "读取" + mi.Winding + "直流电阻数据成功"; mi.completed = true; } } } break; } } }
public static void OLTCSwitchingCharacter(ref MeasurementItemStruct mi, Transformer transformer, JobList Job) { Parameter.YzfjStation yzfjStation; if (mi.Winding == WindingType.HV) { yzfjStation = Parameter.YzfjStation.高压侧; } else { yzfjStation = Parameter.YzfjStation.中压侧; } switch (mi.state) { case 0: byte[] TestKindData = TZ3310.SetPraYzfj((Parameter.YzfjWindingKind)mi.WindingConfig, yzfjStation, Parameter.yzfjTap._1To_2, Parameter.YzfjCurrent._1_A, 5, 5, 0); Thread.Sleep(100); TZ3310.StartTest(TestKindData); mi.stateText = "正在测试" + mi.Winding + "有载分接中..."; mi.state++; Thread.Sleep(4000); break; case 1: string[] Recbuffer = TZ3310.ReadTestData(Parameter.TestKind.载分接); if (Recbuffer != null) { bool ReadforT; if (Recbuffer[0] == "1") { ReadforT = true; } else { ReadforT = false; } if (Recbuffer.Length == 7) { PhysicalVariable[] Voltage = { NumericsConverter.Text2Value(Recbuffer[1]), NumericsConverter.Text2Value(Recbuffer[3]), NumericsConverter.Text2Value(Recbuffer[5]) }; //135 PhysicalVariable[] current = { NumericsConverter.Text2Value(Recbuffer[2]), NumericsConverter.Text2Value(Recbuffer[4]), NumericsConverter.Text2Value(Recbuffer[6]) }; //246 PhysicalVariable[] Resistans = new PhysicalVariable[3]; Resistans[0] = NumericsConverter.Text2Value("0.005"); Resistans[1] = NumericsConverter.Text2Value("0.005"); Resistans[2] = NumericsConverter.Text2Value("0.005"); mi.Result = MeasurementResult.NewOLTCSwitchingCharacterResult(mi, Voltage, current, Resistans, null, ReadforT, false); mi.stateText = "读取" + mi.Winding + "有载分接充电中..."; if (ReadforT) //可以触发 { mi.stateText = mi.Winding + "有载分接等待触发。。。"; Thread.Sleep(500); mi.state++; } } else { // mi.failed = true; mi.completed = true; mi.stateText = "充电时错误:" + Recbuffer[0].ToString(); } } break; case 2: string[] Recbuffer1 = TZ3310.ReadTestData(Parameter.TestKind.载分接); if (Recbuffer1 != null) { bool ReadforR; if (Recbuffer1[0] == "2") { ReadforR = true; } else { ReadforR = false; } if (Recbuffer1.Length == 7) { PhysicalVariable[] Voltage = { NumericsConverter.Text2Value(Recbuffer1[1]), NumericsConverter.Text2Value(Recbuffer1[3]), NumericsConverter.Text2Value(Recbuffer1[5]) }; //135 PhysicalVariable[] current = { NumericsConverter.Text2Value(Recbuffer1[2]), NumericsConverter.Text2Value(Recbuffer1[4]), NumericsConverter.Text2Value(Recbuffer1[6]) }; //246 if (ReadforR) //触发成功 { mi.Result = MeasurementResult.NewOLTCSwitchingCharacterResult(mi, Voltage, current, new PhysicalVariable[3], null, ReadforR, true); mi.stateText = "读取" + mi.Winding + "触发成功"; mi.state++; } } else if (Recbuffer1.Length == 1) { // mi.failed = true; mi.completed = true; mi.stateText = mi.Winding + "错误类型:" + Recbuffer1[0].ToString(); } } break; case 3: mi.stateText = "正在读取波形中。。。"; Thread.Sleep(8000); mi.state++; break; case 4: var Waveform = TZ3310.GetWaveFormData; //5s if (Waveform != null) { mi.Result = MeasurementResult.NewOLTCSwitchingCharacterResult(mi, new PhysicalVariable[3], new PhysicalVariable[3], new PhysicalVariable[3], Waveform, false, true); mi.state++; WorkingSets.local.WaveFormSwicth = Waveform; Thread.Sleep(50); WorkingSets.local.ShowWaveForm = true; mi.stateText = mi.Winding + "波形读取完成"; } else { // mi.state++; // mi.failed = true; mi.completed = true; mi.stateText = mi.Winding + "未读取到波形"; } break; case 5: mi.completed = true; break; } }
public static void DCResistance(ref MeasurementItemStruct mi, Transformer transformer, JobList Job, TestingWorkerSender sender) { //string p = (1.1 + i / 10) + " kV"; //string q = tempp.ToString("f1") + " A"; //tempp += 0.1; //string w = (3.3 + i) + " Ω"; //var p1 = new PhysicalVariable[] { p, q, w }; //var p2 = new PhysicalVariable[] { p, q, w }; //var p3 = new PhysicalVariable[] { p, q, w }; //mi.Result = MeasurementResult.NewDCResistanceResult(mi, p1, p2, p3, false); //i++; //if (i > 100) //{ // mi.completed = true; // mi.failed = true; // mi.stateText = "测量人为中断"; // i = 0; //} //Thread.Sleep(200); if (mi.Terimal != null) { Parameter.ZldzStation Dcposition; if (mi.Winding == WindingType.HV) { Dcposition = Parameter.ZldzStation.高压全部 + (((int)mi.Terimal[0]) % 4);//1 // mi.WindingConfig = GetWindConfig(sender.MeasurementItems[sender.CurrentItemIndex + 1], transformer); } else if (mi.Winding == WindingType.MV) { Dcposition = Parameter.ZldzStation.中压全部 + (((int)mi.Terimal[0]) % 4);//5 } else { if (!Job.DCResistance.ZcEnable) { Dcposition = Parameter.ZldzStation.低压全部 + (((int)mi.Terimal[0]) % 4);//9 } else { Dcposition = Parameter.ZldzStation.注磁抵押 + (((int)mi.Terimal[0]) % 4);//9 } } switch (mi.state) { case 0: if (mi.Winding == WindingType.HV) { mi.WindingConfig = transformer.WindingConfig.HV; } else if (mi.Winding == WindingType.MV) { mi.WindingConfig = transformer.WindingConfig.MV; } else { if (transformer.WindingNum == 2) { mi.WindingConfig = transformer.WindingConfig.MV; } else { mi.WindingConfig = transformer.WindingConfig.LV; } } Thread.Sleep(2000); byte[] TestKindData = TZ3310.SetPraZldz((Parameter.ZldzWindingKind)mi.WindingConfig, Dcposition, GetParameter.GetPraDCResistanceCurrentSpa(mi, Job), 0); Thread.Sleep(100); TZ3310.StartTest(TestKindData); WorkingSets.local.TestDCI = false; WorkingSets.local.IsEnablestable = true; mi.stateText = "正在开始" + mi.Winding + "直流电阻中..."; Thread.Sleep(4000); mi.state++; break; case 1: string[] Recbuffer = TZ3310.ReadTestData(Parameter.TestKind.直流电阻); Thread.Sleep(150); if (Recbuffer != null) { if (Recbuffer[Recbuffer.Length - 1] == "0") { PhysicalVariable[] Voltage = { NumericsConverter.Text2Value(Recbuffer[0]), NumericsConverter.Text2Value(Recbuffer[3]), NumericsConverter.Text2Value(Recbuffer[6]) }; PhysicalVariable[] Current = { NumericsConverter.Text2Value(Recbuffer[1]), NumericsConverter.Text2Value(Recbuffer[4]), NumericsConverter.Text2Value(Recbuffer[7]) }; PhysicalVariable[] Resistance = { NumericsConverter.Text2Value(Recbuffer[2]), NumericsConverter.Text2Value(Recbuffer[5]), NumericsConverter.Text2Value(Recbuffer[8]) }; mi.Result = MeasurementResult.NewDCResistanceResult(mi, Voltage, Current, Resistance, false); mi.state++; //测量结束数据需要确定 mi.stateText = "等待确认" + mi.Winding + "直流电阻稳定中..."; //临时 WorkingSets.local.IsVisible = true; WorkingSets.local.IsVisible1 = true; } else if (Recbuffer[Recbuffer.Length - 1] == "1") { mi.state++; } else { mi.failed = true; mi.completed = true; mi.stateText = mi.Winding + "错误类型:" + Recbuffer[0].ToString(); } } break; case 2: string[] Recbuffer1 = TZ3310.ReadTestData(Parameter.TestKind.直流电阻); Thread.Sleep(150); if (Recbuffer1 != null) { if (Recbuffer1[Recbuffer1.Length - 1] == "0") { PhysicalVariable[] Voltage = { NumericsConverter.Text2Value(Recbuffer1[0]), NumericsConverter.Text2Value(Recbuffer1[3]), NumericsConverter.Text2Value(Recbuffer1[6]) }; PhysicalVariable[] Current = { NumericsConverter.Text2Value(Recbuffer1[1]), NumericsConverter.Text2Value(Recbuffer1[4]), NumericsConverter.Text2Value(Recbuffer1[7]) }; PhysicalVariable[] Resistance = { NumericsConverter.Text2Value(Recbuffer1[2]), NumericsConverter.Text2Value(Recbuffer1[5]), NumericsConverter.Text2Value(Recbuffer1[8]) }; mi.Result = MeasurementResult.NewDCResistanceResult(mi, Voltage, Current, Resistance, false); if (WorkingSets.local.IsStable == true) { WorkingSets.local.IsStable = false; mi.Result = MeasurementResult.NewDCResistanceResult(mi, Voltage, Current, Resistance, true); TZ3310.InterRuptMe(Parameter.CommanTest.判断直流电阻稳定状态); mi.stateText = "确定" + mi.Winding + "直流电阻稳定成功"; mi.state++; } } else if (Recbuffer1[Recbuffer1.Length - 1] == "1") { mi.state++; } else { mi.stateText = mi.Winding + "错误类型:" + Recbuffer1[0].ToString(); mi.failed = true; mi.completed = true; } } break; case 3: string[] Recbuffer2 = TZ3310.ReadTestData(Parameter.TestKind.直流电阻); if (Recbuffer2 != null) { if (Recbuffer2[Recbuffer2.Length - 1] == "1") { if (sender.MeasurementItems.Length != (sender.CurrentItemIndex + 1)) { var miNext = sender.MeasurementItems[sender.CurrentItemIndex + 1]; if (miNext.Terimal != null && mi.Function == miNext.Function && mi.Terimal[0] == miNext.Terimal[0] && mi.Terimal[1] == miNext.Terimal[1] && mi.Winding == miNext.Winding && mi.WindingConfig == GetWindConfig(miNext, transformer)) { //不需要放电 mi.stateText = "直流电阻" + mi.Winding + ":" + mi.Terimal[0] + "-" + mi.Terimal[1] + "测试完成"; mi.completed = true; } else { //需要放电的 TZ3310.ShutDownOutCurrent(0); mi.state++; } } else { //为最后一项 mi.stateText = mi.Winding + "直流电阻正在放电..."; TZ3310.ShutDownOutCurrent(0); mi.state++; } } else { mi.failed = true; mi.completed = true; mi.stateText = mi.Winding + "错误类型:" + Recbuffer2[0].ToString(); //临时 } } break; case 4: string[] readdata = TZ3310.ReadTestData(Parameter.TestKind.读取放电数据); if (readdata[0] == "2") { mi.stateText = mi.Winding + "直流电阻放电完成"; mi.completed = true; } break; } } else { switch (mi.state) { case 0: if (mi.Winding == WindingType.HV) { mi.WindingConfig = transformer.WindingConfig.HV; } else if (mi.Winding == WindingType.MV) { mi.WindingConfig = transformer.WindingConfig.MV; } else { if (transformer.PhaseNum == 2) { mi.WindingConfig = transformer.WindingConfig.MV; } else { mi.WindingConfig = transformer.WindingConfig.LV; } } WorkingSets.local.TestDCI = false; WorkingSets.local.IsEnablestable = true; byte[] TestKindData = TZ3310.SetPraZldz((Parameter.ZldzWindingKind)mi.WindingConfig, mi.Winding.TozldzStation(Job), GetParameter.GetPraDCResistanceCurrentSpa(mi, Job), 0); Thread.Sleep(100); if (TZ3310.StartTest(TestKindData)) { mi.stateText = "正在测试" + mi.Winding.TozldzStation(Job) + "直流电阻中..."; mi.state++; } Thread.Sleep(4000); break; case 1: string[] Recbuffer = TZ3310.ReadTestData(Parameter.TestKind.直流电阻); Thread.Sleep(150); if (Recbuffer != null) { if (Recbuffer[Recbuffer.Length - 1] == "0") { PhysicalVariable[] Voltage = { Recbuffer[0], Recbuffer[3], Recbuffer[6] }; PhysicalVariable[] Current = { Recbuffer[1], Recbuffer[4], Recbuffer[7] }; PhysicalVariable[] Resistance = { Recbuffer[2], Recbuffer[5], Recbuffer[8] }; mi.Result = MeasurementResult.NewDCResistanceResult(mi, Voltage, Current, Resistance, false); mi.state++; mi.stateText = "等待确定" + mi.Winding + "直流电阻稳定中..."; WorkingSets.local.IsVisible = true; WorkingSets.local.IsVisible1 = true; } else if (Recbuffer[Recbuffer.Length - 1] == "1") { mi.state++; } else { mi.failed = true; mi.completed = true; mi.stateText = mi.Winding + "错误类型:" + Recbuffer[0].ToString(); } } break; case 2: string[] Recbuffer1 = TZ3310.ReadTestData(Parameter.TestKind.直流电阻); if (Recbuffer1 != null) { if (Recbuffer1[Recbuffer1.Length - 1] == "0") { PhysicalVariable[] Voltage = { Recbuffer1[0], Recbuffer1[3], Recbuffer1[6] }; PhysicalVariable[] Current = { Recbuffer1[1], Recbuffer1[4], Recbuffer1[7] }; PhysicalVariable[] Resistance = { Recbuffer1[2], Recbuffer1[5], Recbuffer1[8] }; mi.Result = MeasurementResult.NewDCResistanceResult(mi, Voltage, Current, Resistance, false); if (WorkingSets.local.IsStable == true) { WorkingSets.local.IsStable = false; mi.Result = MeasurementResult.NewDCResistanceResult(mi, Voltage, Current, Resistance, true); TZ3310.InterRuptMe(Parameter.CommanTest.判断直流电阻稳定状态); mi.stateText = "确定" + mi.Winding + "直流电阻稳定成功"; mi.state++; } } else if (Recbuffer1[Recbuffer1.Length - 1] == "1") { mi.state++; } else { mi.failed = true; mi.completed = true; mi.stateText = mi.Winding + "错误类型:" + Recbuffer1[0].ToString(); } } break; case 3: string[] Recbuffer2 = TZ3310.ReadTestData(Parameter.TestKind.直流电阻); if (Recbuffer2 != null) { if (Recbuffer2[Recbuffer2.Length - 1] == "1") { if (sender.MeasurementItems.Length != (sender.CurrentItemIndex + 1)) { var miNext = sender.MeasurementItems[sender.CurrentItemIndex + 1]; if (mi.Function == miNext.Function && mi.Winding == miNext.Winding && mi.WindingConfig == GetWindConfig(miNext, transformer)) { //不需要放电 mi.stateText = "直流电阻" + mi.Winding + "测试完成"; mi.completed = true; } else { //需要放电的 TZ3310.ShutDownOutCurrent(0); mi.state++; } } else { //为最后一项 mi.stateText = mi.Winding + "直流电阻测试完成"; TZ3310.ShutDownOutCurrent(0); mi.state++; } } else { mi.failed = true; mi.completed = true; mi.stateText = mi.Winding + "错误类型:" + Recbuffer2[0].ToString(); //临时 } } Thread.Sleep(1000); break; case 4: string[] readdata = TZ3310.ReadTestData(Parameter.TestKind.读取放电数据); if (readdata[0] == "2") { mi.stateText = mi.Winding + "直流电阻放电完成"; mi.completed = true; } break; } } }
//读取测量数据 /// <summary> /// 读取测量数据和数据的处理 /// </summary> /// <param name="testkind">测试类型</param> /// <returns>回复解析完成的数据</returns> public string[] ReadTestData(Parameter.TestKind testkind) { if (testkind == Parameter.TestKind.介质损耗) { //string[] RetData = new string[5]; byte[] SendComman = { 0x12 }; byte[] RecBuffer = new byte[31]; sc.SendCommand(SendComman, ref RecBuffer, 50); if (RecBuffer[0] == 0xfa) { string[] RetData = new string[5]; RetData[0] = RecBuffer[1].ToString(); PhysicalVariable pv = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecBuffer.Skip(2).Take(7).ToArray())); RetData[1] = pv.ToString(); PhysicalVariable pv1 = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecBuffer.Skip(9).Take(7).ToArray())); RetData[2] = pv1.ToString(); PhysicalVariable pv2 = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecBuffer.Skip(16).Take(7).ToArray())); RetData[3] = pv2.ToString(); RetData[4] = "0"; return(RetData); } if (RecBuffer[0] == 0xff) { string[] RetData = new string[5]; PhysicalVariable pv = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecBuffer.Skip(2).Take(7).ToArray())); RetData[0] = pv.ToString(); PhysicalVariable pv1 = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecBuffer.Skip(9).Take(7).ToArray())); RetData[1] = pv1.ToString(); PhysicalVariable pv2 = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecBuffer.Skip(16).Take(7).ToArray()) + "%"); RetData[2] = pv2.ToString(percentage: true, positiveSign: true); PhysicalVariable pv3 = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecBuffer.Skip(23).Take(7).ToArray())); RetData[3] = pv3.ToString(); RetData[4] = "1"; return(RetData); } if (RecBuffer[0] == 0xee) { string[] Rd = new string[1]; Rd[0] = TestErrDC(RecBuffer[1].ToString()); return(Rd);//错误类型 } } if (testkind == Parameter.TestKind.直流电阻) { byte[] Sendbuffer = { 0x32 }; byte[] RecBuffer = new byte[75]; try { sc.SendCommand(Sendbuffer, ref RecBuffer, 10); //if (CheckData(RecData) == RecData[74]) //{ if (RecBuffer[0] == 0xfa) { string[] RetData = new string[10]; RetData[0] = Encoding.ASCII.GetString(RecBuffer.Skip(2).Take(8).ToArray()); PhysicalVariable pv = NumericsConverter.Text2Value(RetData[0]); RetData[0] = pv.ToString(); RetData[1] = Encoding.ASCII.GetString(RecBuffer.Skip(10).Take(8).ToArray()); PhysicalVariable pv1 = NumericsConverter.Text2Value(RetData[1]); RetData[1] = pv1.ToString(); RetData[2] = Encoding.ASCII.GetString(RecBuffer.Skip(18).Take(8).ToArray()).Replace("$", "Ω"); PhysicalVariable pv2 = NumericsConverter.Text2Value(RetData[2]); RetData[2] = pv2.ToString(); RetData[3] = Encoding.ASCII.GetString(RecBuffer.Skip(26).Take(8).ToArray()); PhysicalVariable pv3 = NumericsConverter.Text2Value(RetData[3]); RetData[3] = pv3.ToString(); RetData[4] = Encoding.ASCII.GetString(RecBuffer.Skip(34).Take(8).ToArray()); PhysicalVariable pv4 = NumericsConverter.Text2Value(RetData[4]); RetData[4] = pv4.ToString(); RetData[5] = Encoding.ASCII.GetString(RecBuffer.Skip(42).Take(8).ToArray()).Replace("$", "Ω"); PhysicalVariable pv5 = NumericsConverter.Text2Value(RetData[5]); RetData[5] = pv5.ToString(); RetData[6] = Encoding.ASCII.GetString(RecBuffer.Skip(50).Take(8).ToArray()); PhysicalVariable pv6 = NumericsConverter.Text2Value(RetData[6]); RetData[6] = pv6.ToString(); RetData[7] = Encoding.ASCII.GetString(RecBuffer.Skip(58).Take(8).ToArray()); PhysicalVariable pv7 = NumericsConverter.Text2Value(RetData[7]); RetData[7] = pv7.ToString(); RetData[8] = Encoding.ASCII.GetString(RecBuffer.Skip(66).Take(8).ToArray()).Replace("$", "Ω"); PhysicalVariable pv8 = NumericsConverter.Text2Value(RetData[8]); RetData[8] = pv8.ToString(); RetData[9] = "0"; return(RetData); } else if (RecBuffer[0] == 0xff) { string[] RetData = new string[10]; RetData[0] = Encoding.ASCII.GetString(RecBuffer.Skip(2).Take(8).ToArray()); PhysicalVariable pv = NumericsConverter.Text2Value(RetData[0]); RetData[0] = pv.ToString(); RetData[1] = Encoding.ASCII.GetString(RecBuffer.Skip(10).Take(8).ToArray()); PhysicalVariable pv1 = NumericsConverter.Text2Value(RetData[1]); RetData[1] = pv1.ToString(); RetData[2] = Encoding.ASCII.GetString(RecBuffer.Skip(18).Take(8).ToArray()).Replace("$", "Ω"); PhysicalVariable pv2 = NumericsConverter.Text2Value(RetData[2]); RetData[2] = pv2.ToString(); RetData[3] = Encoding.ASCII.GetString(RecBuffer.Skip(26).Take(8).ToArray()); PhysicalVariable pv3 = NumericsConverter.Text2Value(RetData[3]); RetData[3] = pv3.ToString(); RetData[4] = Encoding.ASCII.GetString(RecBuffer.Skip(34).Take(8).ToArray()); PhysicalVariable pv4 = NumericsConverter.Text2Value(RetData[4]); RetData[4] = pv4.ToString(); RetData[5] = Encoding.ASCII.GetString(RecBuffer.Skip(42).Take(8).ToArray()).Replace("$", "Ω"); PhysicalVariable pv5 = NumericsConverter.Text2Value(RetData[5]); RetData[5] = pv5.ToString(); RetData[6] = Encoding.ASCII.GetString(RecBuffer.Skip(50).Take(8).ToArray()); PhysicalVariable pv6 = NumericsConverter.Text2Value(RetData[6]); RetData[6] = pv6.ToString(); RetData[7] = Encoding.ASCII.GetString(RecBuffer.Skip(58).Take(8).ToArray()); PhysicalVariable pv7 = NumericsConverter.Text2Value(RetData[7]); RetData[7] = pv7.ToString(); RetData[8] = Encoding.ASCII.GetString(RecBuffer.Skip(66).Take(8).ToArray()).Replace("$", "Ω"); PhysicalVariable pv8 = NumericsConverter.Text2Value(RetData[8]); RetData[8] = pv8.ToString(); RetData[9] = "1"; return(RetData); } else if (RecBuffer[0] == 0xee) { string[] Rd = new string[1]; Rd[0] = TestErr(RecBuffer[1].ToString()); return(Rd);//错误类型 } //} } catch { } } if (testkind == Parameter.TestKind.绝缘电阻) { byte[] SendComman = { 0x22 }; byte[] RecData = new byte[18]; // float[] RetData = new float[4]; sc.SendCommand(SendComman, ref RecData, 50); if (CheckData(RecData) == RecData[17]) { if (RecData[0] == 0xfa) { string[] RetData = new string[4]; PhysicalVariable pv = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecData.Skip(1).Take(5).ToArray()) + "V"); RetData[0] = pv.ToString(); string TempData = Encoding.ASCII.GetString(RecData.Skip(6).Take(7).ToArray()).Replace("$", "Ω"); if (TempData.IndexOf('Ω') < 0) { TempData += "Ω"; } PhysicalVariable pv1 = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecData.Skip(6).Take(7).ToArray()).Replace("$", "Ω")); RetData[1] = pv1.ToString(); PhysicalVariable pv2 = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecData.Skip(13).Take(4).ToArray())); RetData[2] = pv2.ToString(); RetData[3] = "0"; return(RetData); } if (RecData[0] == 0xff) { string[] RetData = new string[4]; string TempData = Encoding.ASCII.GetString(RecData.Skip(1).Take(7).ToArray()).Replace("$", "Ω"); if (TempData.IndexOf('Ω') < 0) { TempData += "Ω"; } PhysicalVariable pv = NumericsConverter.Text2Value(TempData); RetData[0] = pv.ToString(); PhysicalVariable pv1 = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecData.Skip(8).Take(4).ToArray())); RetData[1] = pv1.ToString(); PhysicalVariable pv2 = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecData.Skip(12).Take(4).ToArray())); RetData[2] = pv2.ToString(); RetData[3] = "1"; return(RetData); } if (RecData[0] == 0xee) { string[] Rd = new string[1]; Rd[0] = TestErrDC(RecData[1].ToString()); return(Rd);//错误类型 } } else { } } if (testkind == Parameter.TestKind.载分接) { byte[] RecBuffer = new byte[51]; // float[] RetData = new float[7]; byte[] SendComman = { 0x42 }; sc.SendCommand(SendComman, ref RecBuffer, 50); if (RecBuffer[0] == 0xfa) { string[] RetData = new string[7]; RetData[0] = RecBuffer[1].ToString(); PhysicalVariable pv = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecBuffer.Skip(2).Take(8).ToArray())); RetData[1] = pv.ToString(); PhysicalVariable pv1 = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecBuffer.Skip(10).Take(8).ToArray())); RetData[2] = pv1.ToString(); PhysicalVariable pv2 = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecBuffer.Skip(18).Take(8).ToArray())); RetData[3] = pv2.ToString(); PhysicalVariable pv3 = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecBuffer.Skip(26).Take(8).ToArray())); RetData[4] = pv3.ToString(); PhysicalVariable pv4 = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecBuffer.Skip(34).Take(8).ToArray())); RetData[5] = pv4.ToString(); PhysicalVariable pv5 = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecBuffer.Skip(42).Take(8).ToArray())); RetData[6] = pv5.ToString(); return(RetData); } else if (RecBuffer[0] == 0xff && RecBuffer[1] == 0xff) { string[] RetData = new string[6]; PhysicalVariable pv = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecBuffer.Skip(2).Take(8).ToArray())); RetData[0] = pv.ToString(); PhysicalVariable pv1 = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecBuffer.Skip(10).Take(8).ToArray())); RetData[1] = pv1.ToString(); PhysicalVariable pv2 = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecBuffer.Skip(18).Take(8).ToArray())); RetData[2] = pv2.ToString(); PhysicalVariable pv3 = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecBuffer.Skip(26).Take(8).ToArray())); RetData[3] = pv3.ToString(); PhysicalVariable pv4 = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecBuffer.Skip(34).Take(8).ToArray())); RetData[4] = pv4.ToString(); PhysicalVariable pv5 = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecBuffer.Skip(42).Take(8).ToArray())); RetData[5] = pv5.ToString(); return(RetData); } else if (RecBuffer[0] == 0xee) { string[] Rd = new string[1]; Rd[0] = TestErr(RecBuffer[1].ToString()); return(Rd);//错误类型 } else { return(null); } } if (testkind == Parameter.TestKind.读取放电数据) { byte[] RecData = new byte[26]; // float[] RetData = new float[4]; byte[] SendComman = { 0x3e }; if (sc.SendCommand(SendComman, ref RecData, 50) >= 0) { string[] RetData = new string[4]; bool Success; RetData[0] = RecData[0].ToString(); PhysicalVariable pv = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecData.Skip(1).Take(8).ToArray()), out Success); if (Success) { RetData[1] = pv.ToString(); } else { RetData[1] = Encoding.ASCII.GetString(RecData.Skip(1).Take(8).ToArray()); } PhysicalVariable pv1 = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecData.Skip(9).Take(8).ToArray()), out Success); if (Success) { RetData[2] = pv1.ToString(); } else { RetData[2] = Encoding.ASCII.GetString(RecData.Skip(9).Take(8).ToArray()); } PhysicalVariable pv2 = NumericsConverter.Text2Value(Encoding.ASCII.GetString(RecData.Skip(17).Take(8).ToArray()), out Success); if (Success) { RetData[3] = pv2.ToString(); } else { RetData[3] = Encoding.ASCII.GetString(RecData.Skip(17).Take(8).ToArray()); } return(RetData); } } return(null); }
private void TextBox1_TextChanged(object sender, EventArgs e) { label1.Text = NumericsConverter.Text2Value(textBox1.Text.ToString()).ToString(); }
private void Recor_Click(object sender, RoutedEventArgs e) { #region 设置基础值 double VolateD = 0; string Volate = "0V"; try { if (AutoStateStatic.SState.mv.HVVoltage.ToString() != "NaN") { Volate = mv.HVVoltage.ToString(); PhysicalVariable a = NumericsConverter.Text2Value(Volate); VolateD = (double)a.value; } } catch { } var Fre = mv.HVFrequency.ToString(); var Time = DateTime.Now.ToString(); float Cn = (float)NumericsConverter.Text2Value(AutoStateStatic.SState.mv.Capacitance1).value; var Current = (float)NumericsConverter.Text2Value(AutoStateStatic.SState.mv.Current1).value; var Tan = (float)NumericsConverter.Text2Value(AutoStateStatic.SState.mv.DissipationFactor1).value; var Cn2 = (float)NumericsConverter.Text2Value(AutoStateStatic.SState.mv.Capacitance2).value; var Current2 = (float)NumericsConverter.Text2Value(AutoStateStatic.SState.mv.Current2).value; var Tan2 = (float)NumericsConverter.Text2Value(AutoStateStatic.SState.mv.DissipationFactor2).value; var Cn3 = (float)NumericsConverter.Text2Value(AutoStateStatic.SState.mv.Capacitance3).value; var Current3 = (float)NumericsConverter.Text2Value(AutoStateStatic.SState.mv.Current3).value; var Tan3 = (float)NumericsConverter.Text2Value(AutoStateStatic.SState.mv.DissipationFactor3).value; var Cn4 = (float)NumericsConverter.Text2Value(AutoStateStatic.SState.mv.Capacitance4).value; var Current4 = (float)NumericsConverter.Text2Value(AutoStateStatic.SState.mv.Current4).value; var Tan4 = (float)NumericsConverter.Text2Value(AutoStateStatic.SState.mv.DissipationFactor4).value; if (Com1.SelectedIndex == 0) { XVolate.Add(Volate); if (Com2.SelectedIndex == 0) { YVolateAndCn.Add(Cn); YVolateAndCn2.Add(Cn2); YVolateAndCn3.Add(Cn3); YVolateAndCn4.Add(Cn4); mv.SetChartObserver(YVolateAndCn.ToArray(), XVolate, ChartPannel.Channel1); mv.SetChartObserver(YVolateAndCn2.ToArray(), XVolate, ChartPannel.Channel2); mv.SetChartObserver(YVolateAndCn3.ToArray(), XVolate, ChartPannel.Channel3); mv.SetChartObserver(YVolateAndCn4.ToArray(), XVolate, ChartPannel.Channel4); } else if (Com2.SelectedIndex == 1) { YVolateAndCurrent.Add((double)Current); YVolateAndCurrent2.Add((double)Current2); YVolateAndCurrent3.Add((double)Current3); YVolateAndCurrent4.Add((double)Current4); mv.SetChartObserver(YVolateAndCurrent.ToArray(), XVolate, ChartPannel.Channel1); mv.SetChartObserver(YVolateAndCurrent2.ToArray(), XVolate, ChartPannel.Channel2); mv.SetChartObserver(YVolateAndCurrent3.ToArray(), XVolate, ChartPannel.Channel3); mv.SetChartObserver(YVolateAndCurrent4.ToArray(), XVolate, ChartPannel.Channel4); } else if (Com2.SelectedIndex == 2) { YVolateAndTan.Add((double)Tan); YVolateAndTan2.Add((double)Tan2); YVolateAndTan3.Add((double)Tan3); YVolateAndTan4.Add((double)Tan4); mv.SetChartObserver(YVolateAndTan.ToArray(), XVolate, ChartPannel.Channel1); mv.SetChartObserver(YVolateAndTan2.ToArray(), XVolate, ChartPannel.Channel2); mv.SetChartObserver(YVolateAndTan3.ToArray(), XVolate, ChartPannel.Channel3); mv.SetChartObserver(YVolateAndTan4.ToArray(), XVolate, ChartPannel.Channel4); } } if (Com1.SelectedIndex == 1) { XFre.Add(Fre); if (Com2.SelectedIndex == 0) { YVolateAndCn.Add((double)Cn); YVolateAndCn2.Add((double)Cn2); YVolateAndCn3.Add((double)Cn3); YVolateAndCn4.Add((double)Cn4); mv.SetChartObserver(YVolateAndCn.ToArray(), XFre, ChartPannel.Channel1); mv.SetChartObserver(YVolateAndCn2.ToArray(), XFre, ChartPannel.Channel2); mv.SetChartObserver(YVolateAndCn3.ToArray(), XFre, ChartPannel.Channel3); mv.SetChartObserver(YVolateAndCn4.ToArray(), XFre, ChartPannel.Channel4); } else if (Com2.SelectedIndex == 1) { YVolateAndCurrent.Add((double)Current); YVolateAndCurrent2.Add((double)Current2); YVolateAndCurrent3.Add((double)Current3); YVolateAndCurrent4.Add((double)Current4); mv.SetChartObserver(YVolateAndCurrent.ToArray(), XFre, ChartPannel.Channel1); mv.SetChartObserver(YVolateAndCurrent2.ToArray(), XFre, ChartPannel.Channel2); mv.SetChartObserver(YVolateAndCurrent3.ToArray(), XFre, ChartPannel.Channel3); mv.SetChartObserver(YVolateAndCurrent4.ToArray(), XFre, ChartPannel.Channel4); } else { YVolateAndTan.Add((double)Tan); YVolateAndTan2.Add((double)Tan2); YVolateAndTan3.Add((double)Tan3); YVolateAndTan4.Add((double)Tan4); mv.SetChartObserver(YVolateAndTan.ToArray(), XFre, ChartPannel.Channel1); mv.SetChartObserver(YVolateAndTan2.ToArray(), XFre, ChartPannel.Channel2); mv.SetChartObserver(YVolateAndTan3.ToArray(), XFre, ChartPannel.Channel3); mv.SetChartObserver(YVolateAndTan4.ToArray(), XFre, ChartPannel.Channel4); } } if (Com1.SelectedIndex == 2) { XFre.Add(Time); if (Com2.SelectedIndex == 0) { YVolateAndCn.Add((double)VolateD); YVolateAndCn2.Add((double)VolateD); YVolateAndCn3.Add((double)VolateD); YVolateAndCn4.Add((double)VolateD); mv.SetChartObserver(YVolateAndCn.ToArray(), XTime, ChartPannel.Channel1); mv.SetChartObserver(YVolateAndCn2.ToArray(), XTime, ChartPannel.Channel2); mv.SetChartObserver(YVolateAndCn3.ToArray(), XTime, ChartPannel.Channel3); mv.SetChartObserver(YVolateAndCn4.ToArray(), XTime, ChartPannel.Channel4); } else if (Com2.SelectedIndex == 1) { YVolateAndCurrent.Add((double)Current); YVolateAndCurrent2.Add((double)Current2); YVolateAndCurrent3.Add((double)Current3); YVolateAndCurrent4.Add((double)Current4); mv.SetChartObserver(YVolateAndCurrent.ToArray(), XTime, ChartPannel.Channel1); mv.SetChartObserver(YVolateAndCurrent2.ToArray(), XTime, ChartPannel.Channel2); mv.SetChartObserver(YVolateAndCurrent3.ToArray(), XTime, ChartPannel.Channel3); mv.SetChartObserver(YVolateAndCurrent4.ToArray(), XTime, ChartPannel.Channel4); } else { YVolateAndTan.Add((double)Tan); YVolateAndTan2.Add((double)Tan2); YVolateAndTan3.Add((double)Tan3); YVolateAndTan4.Add((double)Tan4); mv.SetChartObserver(YVolateAndTan.ToArray(), XTime, ChartPannel.Channel1); mv.SetChartObserver(YVolateAndTan2.ToArray(), XTime, ChartPannel.Channel2); mv.SetChartObserver(YVolateAndTan3.ToArray(), XTime, ChartPannel.Channel3); mv.SetChartObserver(YVolateAndTan4.ToArray(), XTime, ChartPannel.Channel4); } } #endregion }
private void MainWindow_OutTestResult(byte[] data) { ViewSources vs = new ViewSources(data); this.Dispatcher.BeginInvoke((Action) delegate() { if (Com1.SelectedIndex == 0) { DL.Text = NumericsConverter.Value2Text(vs.TestIn, 6, -13, "", SCEEC.Numerics.Quantities.QuantityName.Current); XW.Text = vs.TestPh1.ToString("F6"); float[] tpd = GetTwoNum(Com1.SelectedIndex, Com2.SelectedIndex, (int)vs.TestRn); if (tpd != null) { if ((((int)vs.TestRn).ToString() != LC.Text) && CurrentTextBox.Text.Length < 1) { CurrentTextBox.Text = tpd[0].ToString(); Tant.Text = tpd[1].ToString(); } } LC.Text = vs.TestRn.ToString(); } if (Com1.SelectedIndex == 3) { DL.Text = NumericsConverter.Value2Text(vs.TestIx1, 6, -13, "", SCEEC.Numerics.Quantities.QuantityName.Current); XW.Text = vs.TestPh2.ToString("F6"); float[] tpd = GetTwoNum(Com1.SelectedIndex, Com2.SelectedIndex, (int)vs.TestRx1); if (tpd != null) { if ((((int)vs.TestRx1).ToString() != LC.Text) && CurrentTextBox.Text.Length < 1) { CurrentTextBox.Text = tpd[0].ToString(); Tant.Text = tpd[1].ToString(); } } LC.Text = vs.TestRx1.ToString(); } if (Com1.SelectedIndex == 4) { DL.Text = NumericsConverter.Value2Text(vs.TestIx2, 6, -13, "", SCEEC.Numerics.Quantities.QuantityName.Current); XW.Text = vs.TestPh3.ToString("F6"); float[] tpd = GetTwoNum(Com1.SelectedIndex, Com2.SelectedIndex, (int)vs.TestRx2); if (tpd != null) { if ((((int)vs.TestRx2).ToString() != LC.Text) && CurrentTextBox.Text.Length < 1) { CurrentTextBox.Text = tpd[0].ToString(); Tant.Text = tpd[1].ToString(); } } LC.Text = vs.TestRx2.ToString(); } if (Com1.SelectedIndex == 5) { DL.Text = NumericsConverter.Value2Text(vs.TestIx3, 6, -13, "", SCEEC.Numerics.Quantities.QuantityName.Current); XW.Text = vs.TestPh4.ToString("F6"); float[] tpd = GetTwoNum(Com1.SelectedIndex, Com2.SelectedIndex, (int)vs.TestRx3); if (tpd != null) { if ((((int)vs.TestRx3).ToString() != LC.Text) && CurrentTextBox.Text.Length < 1) { CurrentTextBox.Text = tpd[0].ToString(); Tant.Text = tpd[1].ToString(); } } LC.Text = vs.TestRx3.ToString(); } if (Com1.SelectedIndex == 6) { DL.Text = NumericsConverter.Value2Text(vs.TestIx4, 6, -13, "", SCEEC.Numerics.Quantities.QuantityName.Current); XW.Text = vs.TestPh4.ToString("F6"); float[] tpd = GetTwoNum(Com1.SelectedIndex, Com2.SelectedIndex, (int)vs.TestRx4); if (tpd != null) { if ((((int)vs.TestRx4).ToString() != LC.Text) && CurrentTextBox.Text.Length < 1) { CurrentTextBox.Text = tpd[0].ToString(); Tant.Text = tpd[1].ToString(); } } LC.Text = vs.TestRx4.ToString(); } if (Com1.SelectedIndex == 1 || Com1.SelectedIndex == 2 || Com1.SelectedIndex == 7) { LC.Text = ""; DL.Text = ""; XW.Text = ""; CurrentTextBox.Text = ""; Tant.Text = ""; } }); }