简陋检验，几种充电状态的切换

2024-08-23 16:50:34 +08:00 · 2024-08-23 16:50:34 +08:00 · de2f325604
parent b7e1572375
commit de2f325604
26 changed files with 12497 additions and 8790 deletions
--- a/App/inc/mppt_control.h
+++ b/App/inc/mppt_control.h
@ -19,8 +19,7 @@ typedef struct _SL_Mppt_para{
  uint16_t Battery_Voltage;             /* µç³ØµçÑ¹  */
  uint16_t Battery_temperature;         /* µç³ØÎÂ¶È  */
  uint16_t Remaining_Battery_Bower;     /* µç³ØÊ£ÓàµçÁ¿  */
-  uint16_t Solar_Open_Circuit_Voltage1; /* 太阳能开路电压1  */
+  uint16_t Solar_Open_Circuit_Voltage;  /* 太阳能开路电压  */
  uint16_t Solar_Open_Circuit_Voltage2; /* 太阳能开路电压2  */
 }SL_Mppt_para;
 extern SL_Mppt_para g_Mppt_Para;
 #pragma pack(pop)
@ -48,5 +47,6 @@ void mppt_readJust(void);
 void MpptMode(void);
 void mppt_constantVoltage(float InVoltage);
 void test(void);
 void printf_data(void);
 #endif /* APP_INC_MPPT_CONTROL_H_ */
--- a/App/inc/task.h
+++ b/App/inc/task.h
@ -17,7 +17,7 @@
 extern STR_TimeSliceOffset m_runled;
 void Task_RunLED(void);
-#define mpptControl_reloadVal 2000        /* 任务执行间隔  */
+#define mpptControl_reloadVal 10        /* 任务执行间隔  */
 #define mpptControl_offset 0            /* 任务执行偏移量  */
 extern STR_TimeSliceOffset m_mpptControl;
 void Task_mpptControl(void);
@ -47,7 +47,7 @@ extern uint8_t  g_recvBroadcastRegisterNumber;  /*
 extern STR_TimeSliceOffset m_recvbroadcast;
 void Task_recvbroadcast(void);
-#define EnPowerSupply_reloadVal 100           /* 任务执行间隔  */
+#define EnPowerSupply_reloadVal 1000           /* 任务执行间隔  */
 #define EnPowerSupply_offset 0               /* 任务执行偏移量  */
 extern STR_TimeSliceOffset m_EnPowerSupply;
 extern void Task_EnPowerSupply(void);
--- a/App/src/collect_Conversion.c
+++ b/App/src/collect_Conversion.c
@ -21,7 +21,7 @@
 #define MOSFET_Temper   ADC_Channel_6
 #define PV2_VOLT_IN     ADC_Channel_7
-#define enable_Printf_VI
+//#define enable_Printf_VI
 /* 光伏充电输出电流比例，放大倍数*电阻 */
 const float P_CHG_CURR = (1.0 / (50 * 0.005));
@ -30,9 +30,9 @@ const float P_PV_VOLT_OUT = (47.0 + 10.0) / 10.0;
 /* 放电电流采集电流倍数 */
 const float P_DSG_CURR = (1.0 / (50 * 0.005));
 ///* 光伏1开路输出电压比例 */
-//const float P_PV1_VOLT_IN = (100 + 4.7) / 4.7;
+const float P_PV1_VOLT_IN = (100 + 4.7) / 4.7;
 /* 光伏1开路输出电压比例 */
-const float P_PV1_VOLT_IN = (47 + 4.7) / 4.7;
+//const float P_PV1_VOLT_IN = (47 + 4.7) / 4.7;
 /* 系统电源电压比例 */
 const float P_PV_VOLT_IN1 = (47 + 4.7) / 4.7;
 /* 温度采集比例 */
@ -166,7 +166,7 @@ float get_DSG_CURR(void)
    I_ADC = Get_ConversionVal(get_adc(DSG_CURR));
 //    I_ADC = get_adc(DSG_CURR);
-    I = (float)(I_ADC) / 4095 * 3.3 * P_DSG_CURR;
+    I = (float)(I_ADC) / 4095 * 3.3 * P_DSG_CURR * 2;
 #ifdef enable_Printf_VI
    printf("\n DSG_CURR ADC : %d \n", I_ADC);
--- a/App/src/inflash.c
+++ b/App/src/inflash.c
@ -16,10 +16,10 @@ config_info g_slConfigInfo = {
    .Communication_Methods = RS485,
    .bat485_Baud = 9600,
    .gw485_Baud = 9600,
-    .ConstantCurrentV = 1030,
+    .ConstantCurrentV = 1100,
-    .ConstantCurrentV = 1300,
+    .ConstantVoltageV = 1400,
-    .FloatI = 10,
+    .FloatI = 50,
-    .startSolarOpenCircuitV = 1800,
+    .startSolarOpenCircuitV = 1600,
 };
--- a/App/src/mppt_control.c
+++ b/App/src/mppt_control.c
@ -24,7 +24,7 @@ static void FloatingCharge(void);
 /* 占空比 */
 float g_duty_ratio = 0.7;
 /* 用于确定工作模式 */
-static uint8_t modeFlag = 0;
+static uint8_t modeFlag = 2;
 /**
  * @brief  得到输出的功率
@ -137,13 +137,16 @@ void mppt_readJust(void)
 void printf_data(void)
 {
    printf("\n");
-    get_CHG_CURR();
+//    get_CHG_CURR();
-    get_PV_VOLT_OUT();
+//    get_PV_VOLT_OUT();
-    get_DSG_CURR();
+//    get_DSG_CURR();
 //    get_PV1_VOLT_IN();
-    get_PV_VOLT_IN1();
+//    get_PV_VOLT_IN1();
-    get_MOSFET_Temper();
+//    get_MOSFET_Temper();
-    get_PV2_VOLT_IN();
+//    get_PV2_VOLT_IN();
    printf("1. 涓流模式; 2.    恒流模式; 3,  恒压模式; 4,   浮充模式modeFlag : %d \n", modeFlag);
    printf("\n");
 }
@ -184,22 +187,23 @@ void mppt_constantVoltage(float InVoltage)
 //        }
 //    }
-    static float_t kp = 0.05;
+    static float_t kp = 0.005;
-    static float_t ki = 0.0001;
+    static float_t ki = 0.00001;
 //    static float_t allError = 0;
 //    float_t error = (get_PV1_VOLT_IN()) - InVoltage;
 //    float_t error = InVoltage - (get_PV2_VOLT_IN());
 //    allError += error;
-    float_t pv1Volt = get_PV2_VOLT_IN();
+    float_t pv1Volt = get_PV1_VOLT_IN();
    float_t error = pv1Volt - InVoltage;
 //    float_t error = InVoltage - pv1Volt;
    float_t stepPwm = kp * error + ki * pv1Volt;
    g_duty_ratio += stepPwm;
 //    printf("setPwm : %d/10000 \n", (int)(stepPwm * 10000));
-
+//    printf("setPwm : %d/10000 \n", (int)(stepPwm * 10000));
 //    printf("g_duty_ratio : %d/10000 \n", (int)(g_duty_ratio * 10000));
    Set_duty_ratio(&g_duty_ratio);
 }
@ -243,6 +247,8 @@ void mppt_constantVoltageO(float OutVoltage)
    static float_t kp = 0.02;
    static float_t ki = 0.00001;
 //    static float_t kp = 0.1;
 //    static float_t ki = 0.001;
    float_t outVolt = get_PV_VOLT_OUT();
 //    float_t error = outVolt - OutVoltage;
@ -250,8 +256,7 @@ void mppt_constantVoltageO(float OutVoltage)
    float_t stepPwm = kp * error + ki * outVolt;
    g_duty_ratio += stepPwm;
-    printf("setPwm : %d/10000 \n", (int)(stepPwm * 10000));
+//    printf("setPwm : %d/10000 \n", (int)(stepPwm * 10000));
    Set_duty_ratio(&g_duty_ratio);
@ -296,24 +301,43 @@ void mppt_constantCurrentO(float outCurrent)
 //        }
 //    }
-    static float_t kp = 0.01;
+    static float_t kp = 0.005;
-    static float_t ki = 0.0001;
+    static float_t ki = 0.00005;
 //    static float_t last_CHG_CURR = 0;
-//    static float_t flag = 0;
+//    static float_t flag = 1;
 //    static float_t last_OutputPower = 0;
    float_t outCurr = get_CHG_CURR();
 //    float_t OutputPower = outCurr * get_PV_VOLT_OUT();
    float_t error = outCurrent - outCurr;
 //    float_t error = outCurr - outCurrent;
    float_t stepPwm = kp * error + ki * outCurr;
-//    if ((last_CHG_CURR > outCurr) && flag) {
+//    if (flag) {
-//        g_duty_ratio -= stepPwm;
+//        if (OutputPower > last_OutputPower) {
 //            g_duty_ratio += stepPwm;
 //            flag = 1;
 //        } else {
-        g_duty_ratio += stepPwm;
+//            g_duty_ratio -= stepPwm;
 //            flag = 0;
 //        }
 //    } else {
 //        if (OutputPower > last_OutputPower) {
 //            g_duty_ratio -= stepPwm;
 //            flag = 0;
 //        } else {
 //            g_duty_ratio += stepPwm;
 //            flag = 1;
 //        }
 //    }
 //
 //    last_OutputPower = OutputPower;
-    printf("setPwm : %d/10000 \n", (int)(stepPwm * 10000));
+    g_duty_ratio += stepPwm;
 //    printf("setPwm : %d/10000 \n", (int)(stepPwm * 10000));
 //    printf("g_duty_ratio : %d/10000 \n", (int)(g_duty_ratio * 10000));
    Set_duty_ratio(&g_duty_ratio);
@ -333,7 +357,7 @@ void mppt_constantCurrentO(float outCurrent)
  */
 void TrickleCharge(void)
 {
-    mppt_constantCurrentO(0.7);
+    mppt_constantCurrentO(1);
 }
 /**
@ -344,7 +368,9 @@ void TrickleCharge(void)
  */
 void ConstantCurrentCharge(void)
 {
-    mppt_readJust();
+//    mppt_readJust();
    mppt_constantVoltage(18);
 }
 /**
@ -355,7 +381,12 @@ void ConstantCurrentCharge(void)
  */
 void ConstantVoltageCharge(void)
 {
-    mppt_constantVoltage(17.5);
+//    mppt_constantVoltage(17.5);
 //    mppt_constantVoltageO((float_t)g_Mppt_Para.Battery_Voltage);
    mppt_constantVoltageO(14.5);
 //    g_duty_ratio = 0.9;
 //    Set_duty_ratio(&g_duty_ratio);
 }
 /**
@ -366,39 +397,57 @@ void ConstantVoltageCharge(void)
  */
 void FloatingCharge(void)
 {
-    static uint8_t run_num;
+//    static uint32_t run_num;
-    if (get_CHG_CURR() > 0.1) {
+//    if (get_CHG_CURR() > 0.01) {
-        mppt_constantVoltageO(12);
+//        mppt_constantVoltageO(12);
-        if (run_num++ > 100) {
+//        if (run_num++ > 100) {
-            if ((get_PV_VOLT_OUT()) < 14) {
+//            if ((get_PV_VOLT_OUT()) < 14) {
-                run_num = 0;
+//                run_num = 0;
-                modeFlag = CONSTANTVOLTAGE;
+//                modeFlag = CONSTANTVOLTAGE;
-                return;
+//                return;
-            }
+//            }
-        }
+//        }
-    }
+//    }
 //
 //    else {
 //        TIM_SetCompare4(TIM4, 0);
 //        if (run_num++) {
 //            if ((get_PV_VOLT_OUT()) < 14) {
 //                run_num = 0;
 //                modeFlag = CONSTANTVOLTAGE;
 //                return;
 //            }
 //        }
 //
 //        if (run_num > 100) {
 //            run_num = 0;
 //            modeFlag = CONSTANTVOLTAGE;
 //            return;
 //        }
 //    }
 //
 //    if (run_num > 200) {
 //        run_num = 100;
 //    }
-    else {
+    static uint32_t num = 0;
    TIM_SetCompare4(TIM4, 0);
-        if (run_num++) {
+//    mppt_constantVoltageO(12);
-            if ((get_PV_VOLT_OUT()) < 14) {
+
-                run_num = 0;
+    if (500 == num++) {
 //        if ((get_PV_VOLT_OUT()) > 13.5) {
        num = 0;
        modeFlag = CONSTANTVOLTAGE;
-                return;
+//            return;
-            }
+//        }
    }
-        if (run_num > 100) {
+//    if ((get_PV_VOLT_OUT()) > 13.5) {
-            run_num = 0;
+//        modeFlag = CONSTANTVOLTAGE;
-            modeFlag = CONSTANTVOLTAGE;
+//        return;
-            return;
+//    }
        }
    }
    if (run_num > 200) {
        run_num = 100;
    }
 }
@ -428,40 +477,70 @@ void MpptContorl(void)
 void MpptMode(void)
 {
-    static uint8_t temp_flag = 1;
+//    static uint8_t temp_flag = 1;
-    static float ConstantCurrentV;
+//    static float ConstantCurrentV;
-    static float ConstantVoltageV;
+//    static float ConstantVoltageV;
-    static float FloatI;
+//    static float FloatI;
-    /* ¸³Öµ½öÖ´ÐÐÒ»´Î */
+//    /* 赋值仅执行一次 */
-    if (temp_flag) {
+//    if (temp_flag) {
-        ConstantCurrentV = (float)g_slConfigInfo.ConstantCurrentV / 100;
+//        ConstantCurrentV = (float)g_slConfigInfo.ConstantCurrentV / 100;
-        ConstantVoltageV = (float)g_slConfigInfo.ConstantVoltageV / 100;
+//        ConstantVoltageV = (float)g_slConfigInfo.ConstantVoltageV / 100;
-        FloatI = (float)g_slConfigInfo.FloatI / 100;
+//        FloatI = (float)g_slConfigInfo.FloatI / 100;
-        temp_flag = 0;
+//        temp_flag = 0;
-    }
+////        printf("g_slConfigInfo.ConstantCurrentV : %d   g_slConfigInfo.ConstantVoltageV : %d /100 \n", g_slConfigInfo.ConstantCurrentV, g_slConfigInfo.ConstantVoltageV);
 ////        printf("ConstantCurrentV : %d /100   ConstantVoltageV : %d /100 \n", (int)ConstantCurrentV, (int)ConstantVoltageV);
 //    }
-    if ((ConstantCurrentV < g_Mppt_Para.Battery_Voltage) &&
+    printf("vout : %d /100 \n", g_Mppt_Para.Battery_Voltage);
-            (ConstantVoltageV > g_Mppt_Para.Battery_Voltage)) {
+    printf("iout : %d /1000 \n", (int)(get_CHG_CURR() * 1000));
-        modeFlag = CONSTANTCURRENT;
+    printf("in checkSolarOpenCircuitVoltage v: %d/100 \n", g_Mppt_Para.Solar_Open_Circuit_Voltage);
-        return;
+//    printf("ConstantCurrentV : %d   ConstantVoltageV : %d \n", (int)ConstantCurrentV, (int)ConstantVoltageV);
    }
-    if (!(ConstantVoltageV > g_Mppt_Para.Battery_Voltage) &&
+//    if (((ConstantVoltageV < (float)g_Mppt_Para.Battery_Voltage / 100) &&
-            (FloatI < get_CHG_CURR())) {
+//            (FloatI > get_CHG_CURR())) || modeFlag == FLOAT) {
-        modeFlag = CONSTANTVOLTAGE;
+//        modeFlag = FLOAT;
-        return;
+//        return;
-    }
+//    }
 //
 //    if ((ConstantCurrentV < (float)g_Mppt_Para.Battery_Voltage / 100) &&
 //            (ConstantVoltageV >= (float)g_Mppt_Para.Battery_Voltage / 100)) {
 //        modeFlag = CONSTANTCURRENT;
 //        return;
 //    }
 //
 //    if ((ConstantVoltageV < (float)g_Mppt_Para.Battery_Voltage / 100) &&
 //            (FloatI <= get_CHG_CURR())) {
 //        modeFlag = CONSTANTVOLTAGE;
 //        return;
 //    }
-    if ((!(ConstantVoltageV > g_Mppt_Para.Battery_Voltage) &&
+    if (((14.3 < (float)g_Mppt_Para.Battery_Voltage / 100) &&
-            (FloatI > get_CHG_CURR())) || modeFlag == FLOAT) {
+            (0.08 > get_CHG_CURR())) || modeFlag == FLOAT) {
        modeFlag = FLOAT;
        return;
    }
    if ((13 < (float)g_Mppt_Para.Battery_Voltage / 100) &&
            (13.8 >= (float)g_Mppt_Para.Battery_Voltage / 100)) {
        modeFlag = CONSTANTCURRENT;
        return;
    }
    if ((14.3 < (float)g_Mppt_Para.Battery_Voltage / 100) &&
            (0.2 <= get_CHG_CURR())) {
        modeFlag = CONSTANTVOLTAGE;
        return;
    }
    if (12.5 > (float)g_Mppt_Para.Battery_Voltage / 100) {
        modeFlag = TRICKLE;
        return;
    }
 //    modeFlag = CONSTANTCURRENT;
 //    return;
 }
 void findMiNDutyRatio(void)
 {
    static uint8_t num = 100;
@ -488,11 +567,13 @@ void test(void)
 //    printf_data();
 //    void MpptContorl();
-//    mppt_constantVoltageO(13);
+//    mppt_constantVoltageO(12);
 //    FloatingCharge();
 //    mppt_readJust();
-//    mppt_constantCurrentO(1.0);
+//    mppt_constantCurrentO(1);
    MpptContorl();
 //    static uint32_t run_num = 0;
 //    if (1000 < run_num++) {
--- a/App/src/sl_protocol.c
+++ b/App/src/sl_protocol.c
@ -30,8 +30,8 @@ static uint16_t SL_ReadRegisterCommunicationMethods(void *pMsg);
 static uint16_t SL_ReadRegisterBatteryVoltage(void *pMsg);
 static uint16_t SL_ReadRegisterBatterytemperature(void *pMsg);
 static uint16_t SL_ReadRegisterRemainingBatteryBower(void *pMsg);
-static uint16_t SL_ReadRegisterSolarOpenCircuitVoltage1(void *pMsg);
+static uint16_t SL_ReadRegisterSolarOpenCircuitVoltage(void *pMsg);
-static uint16_t SL_ReadRegisterSolarOpenCircuitVoltage2(void *pMsg);
+//static uint16_t SL_ReadRegisterSolarOpenCircuitVoltage2(void *pMsg);
 //static uint16_t SL_WriteRegisterRegistrationStatus(void *pMsg);
 //static uint16_t SL_WriteRegisteraddress(void *pMsg);
@ -82,8 +82,8 @@ SL_RegProcTable g_RegTblR[] =
    {SL_Register_Battery_Voltage,               SL_ReadRegisterBatteryVoltage},
    {SL_Register_Battery_temperature,           SL_ReadRegisterBatterytemperature},
    {SL_Register_Remaining_Battery_Bower,       SL_ReadRegisterRemainingBatteryBower},
-    {SL_Register_Solar_Open_Circuit_Voltage1,   SL_ReadRegisterSolarOpenCircuitVoltage1},
+    {SL_Register_Solar_Open_Circuit_Voltage1,   SL_ReadRegisterSolarOpenCircuitVoltage},
-    {SL_Register_Solar_Open_Circuit_Voltage2,   SL_ReadRegisterSolarOpenCircuitVoltage2},
+//    {SL_Register_Solar_Open_Circuit_Voltage2,   SL_ReadRegisterSolarOpenCircuitVoltage2},
 };
 /* 寄存器处理表 */
@ -508,24 +508,24 @@ uint16_t SL_ReadRegisterRemainingBatteryBower(void *pMsg)
  * @param
  * @retval
  */
-uint16_t SL_ReadRegisterSolarOpenCircuitVoltage1(void *pMsg)
+uint16_t SL_ReadRegisterSolarOpenCircuitVoltage(void *pMsg)
 {
    log_info(" SL_ReadRegisterSolarOpenCircuitVoltage1 ");
-    uint16_t value = (uint16_t)g_Mppt_Para.Solar_Open_Circuit_Voltage1 * 10;
+    uint16_t value = (uint16_t)g_Mppt_Para.Solar_Open_Circuit_Voltage * 10;
    return value;
 }
 /**
  * @brief  读取太阳能开路电压2寄存器
  * @param
  * @retval
  */
 uint16_t SL_ReadRegisterSolarOpenCircuitVoltage2(void *pMsg)
 {
    log_info(" SL_ReadRegisterSolarOpenCircuitVoltage2 ");
    uint16_t value = (uint16_t)g_Mppt_Para.Solar_Open_Circuit_Voltage2 * 10;
    return value;
 }
 //
 ///**
 //  * @brief  读取太阳能开路电压2寄存器
 //  * @param
 //  * @retval
 //  */
 //uint16_t SL_ReadRegisterSolarOpenCircuitVoltage2(void *pMsg)
 //{
 //    log_info(" SL_ReadRegisterSolarOpenCircuitVoltage2 ");
 //    uint16_t value = (uint16_t)g_Mppt_Para.Solar_Open_Circuit_Voltage2 * 10;
 //    return value;
 //}
 ///**
 //  * @brief  写入注册状态寄存器
@ -770,7 +770,7 @@ static int uart_read_climate_pack(device_handle uart_handle,uint8_t *buff, uint3
        }
-        if ((offset == 14) && (pack->function_Code == SL_Function_Code_Write_Register)) {
+        if ((pack->function_Code == SL_Function_Code_Write_Register) && (offset >= 14)) {
            SL_Mppt_Worecv_pack *wpack = (SL_Mppt_Worecv_pack *)buff;
            uint8_t Register_Number = (wpack->write_Register_Number_H << 8) | wpack->write_Register_Number_L;
            len = Register_Number * 2 + SL_MPPT_WORECV_PACK_SIZE - 4;
--- a/App/src/task.c
+++ b/App/src/task.c
@ -33,7 +33,10 @@ void Task_RunLED(void)
 //    uart_sendstr(g_gw485_uart4_handle, "\n\n\n\n\n");
 //    uart_sendstr(g_gw485_uart4_handle, "is gw485\n");
 //    uart_sendstr(g_bat485_uart3_handle, "is bat485\n");
-//    printf("duty_ratio : %d/1000 \n", (int)(g_duty_ratio * 1000));
+    printf("duty_ratio : %d/1000 \n", (int)(g_duty_ratio * 1000));
    printf_data();
 //    get_CHG_CURR();
    static uint8_t flag = RESET;
    flag = !flag;
@ -50,7 +53,7 @@ void Task_RunLED(void)
 STR_TimeSliceOffset m_mpptControl;
 void Task_mpptControl(void)
 {
-//    test();
+    test();
 //    static uint8_t test_flag = 0;
 //    if (5 == ++test_flag) {
@ -102,8 +105,9 @@ void Task_wdi(void)
  * @retval
  */
 #define checkRemainingBatteryBower 30       //电池剩余电量30s刷新一次
-#define checkSolarOpenCircuitVoltage 1800   //太阳能板开路电压30min刷新一次
+//#define checkSolarOpenCircuitVoltage 1800   //太阳能板开路电压30min刷新一次
-#define mpptmodedelay 60                    //mppt工作模式60s刷新一次（小于1000S）
+#define checkSolarOpenCircuitVoltage 100   //太阳能板开路电压刷新一次
 #define mpptmodedelay 1                    //mppt工作模式60s刷新一次（小于1000S）
 //#define checkSolarOpenCircuitDelay 500    //检测太阳能板开路电压时，关闭太阳能板的延时时间
 STR_TimeSliceOffset m_refreshRegister;
 void Task_refreshRegister(void)
@ -114,9 +118,9 @@ void Task_refreshRegister(void)
    static uint32_t opencheckFlag = 0;
    static uint32_t mpptModeFlag = mpptmodedelay -1;
-    /* 后续可以添加考虑减少放电电流的影响 */
+//    g_Mppt_Para.Battery_Voltage = 0;
    g_Mppt_Para.Battery_Voltage = 0;
    g_Mppt_Para.Battery_temperature = 0;
    g_Mppt_Para.Battery_Voltage = (uint16_t)(get_PV_VOLT_OUT() * 100);
    if (checkRemainingBatteryBower == ++checkFlagTemp1) {
        g_Mppt_Para.Remaining_Battery_Bower = 0;
@ -124,43 +128,72 @@ void Task_refreshRegister(void)
    }
    if (checkSolarOpenCircuitVoltage == ++checkFlagTemp2 || (opencheckFlag && ++checkFlagTemp2)) {
        if (!opencheckFlag) {
            Set_duty_ratio(0);
 //        printf("in checkSolarOpenCircuitVoltage \n");
        if (!opencheckFlag) {
            TIM_SetCompare4(TIM4, 0);
            opencheckFlag = 1;
            checkFlagTemp2 = 0;
        }
        else {
-            GPIO_WriteBit(G_FFMOS_CON1_GPIO, G_FFMOS_CON1_PIN, SET);
+//            GPIO_WriteBit(G_FFMOS_CON1_GPIO, G_FFMOS_CON1_PIN, SET);
-            GPIO_WriteBit(G_FFMOS_CON2_GPIO, G_FFMOS_CON2_PIN, SET);
+//            GPIO_WriteBit(G_FFMOS_CON2_GPIO, G_FFMOS_CON2_PIN, SET);
-            g_Mppt_Para.Solar_Open_Circuit_Voltage1 = get_PV1_VOLT_IN();
+//            g_Mppt_Para.Solar_Open_Circuit_Voltage1 = get_PV1_VOLT_IN();
-            g_Mppt_Para.Solar_Open_Circuit_Voltage2 = get_PV2_VOLT_IN();
+//            g_Mppt_Para.Solar_Open_Circuit_Voltage2 = get_PV2_VOLT_IN();
-            GPIO_WriteBit(G_FFMOS_CON1_GPIO, G_FFMOS_CON1_PIN, RESET);
+//            GPIO_WriteBit(G_FFMOS_CON1_GPIO, G_FFMOS_CON1_PIN, RESET);
-            GPIO_WriteBit(G_FFMOS_CON2_GPIO, G_FFMOS_CON2_PIN, RESET);
+//            GPIO_WriteBit(G_FFMOS_CON2_GPIO, G_FFMOS_CON2_PIN, RESET);
 //            opencheckFlag = 0;
 //
 //            if ((g_Mppt_Para.Solar_Open_Circuit_Voltage1
 //                 > g_slConfigInfo.startSolarOpenCircuitV)
 //                    || (g_Mppt_Para.Solar_Open_Circuit_Voltage2
 //                    > g_slConfigInfo.startSolarOpenCircuitV)) {
 //                TimeSliceOffset_Register(&m_mpptControl, Task_mpptControl
 //                        , mpptControl_reloadVal, mpptControl_offset);
 //                mpptModeFlag = 0;
 //                Set_duty_ratio(&g_duty_ratio);
 //            } else {
 //                TimeSliceOffset_Unregister(&m_mpptControl);
 //                mpptModeFlag = 100;
 //            }
            g_Mppt_Para.Solar_Open_Circuit_Voltage = (uint16_t)(get_PV1_VOLT_IN() * 100);
            opencheckFlag = 0;
-            if ((g_Mppt_Para.Solar_Open_Circuit_Voltage1
+//            printf("in checkSolarOpenCircuitVoltage v: %d/100 \n", g_Mppt_Para.Solar_Open_Circuit_Voltage1);
-                 > g_slConfigInfo.startSolarOpenCircuitV)
+
-                    || (g_Mppt_Para.Solar_Open_Circuit_Voltage2
+            if (g_Mppt_Para.Solar_Open_Circuit_Voltage
-                    > g_slConfigInfo.startSolarOpenCircuitV)) {
+                 > g_slConfigInfo.startSolarOpenCircuitV) {
-                TimeSliceOffset_Register(&m_mpptControl, Task_mpptControl
+//                TimeSliceOffset_Register(&m_mpptControl, Task_mpptControl
-                        , mpptControl_reloadVal, mpptControl_offset);
+//                        , mpptControl_reloadVal, mpptControl_offset);
                mpptModeFlag = 0;
                TIM_Cmd(TIM3, ENABLE);
                Set_duty_ratio(&g_duty_ratio);
            } else {
-                TimeSliceOffset_Unregister(&m_mpptControl);
+//                TimeSliceOffset_Unregister(&m_mpptControl);
                TIM_Cmd(TIM3, DISABLE);
                TIM_SetCompare4(TIM4, 0);
                mpptModeFlag = 100;
            }
        }
    }
 //    if (mpptModeFlag != 100) {
 //        if (mpptmodedelay == ++mpptModeFlag) {
 ////            printf("vout : %d /100", g_Mppt_Para.Battery_Voltage);
 //            MpptMode();
 //            mpptModeFlag = 0;
 //        }
 //    }
    if (mpptModeFlag != 100) {
-        if (mpptmodedelay == ++mpptModeFlag) {
+//            printf("vout : %d /100", g_Mppt_Para.Battery_Voltage);
            MpptMode();
-            mpptModeFlag = 0;
+
        }
    }
 //    MpptMode();
    return;
 }
@ -264,12 +297,12 @@ void Task_recvbroadcast(void)
 STR_TimeSliceOffset m_EnPowerSupply;
 void Task_EnPowerSupply(void)
 {
-    if (get_PV_VOLT_IN1() > 17 - 0.4) {
+    if (get_PV_VOLT_IN1() > 16.0) {
        GPIO_WriteBit(EnPowerSupply_GPIO, EnPowerSupply_PIN, SET);
        return;
    } else if (get_PV_VOLT_IN1() < 14 - 0.4) {
        GPIO_WriteBit(EnPowerSupply_GPIO, EnPowerSupply_PIN, RESET);
        return;
    } else if (get_PV_VOLT_IN1() < 14.5) {
        GPIO_WriteBit(EnPowerSupply_GPIO, EnPowerSupply_PIN, SET);
        return;
    }
    return;
 }
@ -294,8 +327,8 @@ void g_Mppt_Para_Init(void)
    g_Mppt_Para.Battery_Voltage = 0;
    g_Mppt_Para.Battery_temperature = 0;
    g_Mppt_Para.Remaining_Battery_Bower = 0;
-    g_Mppt_Para.Solar_Open_Circuit_Voltage1 = 0;
+    g_Mppt_Para.Solar_Open_Circuit_Voltage = 0;
-    g_Mppt_Para.Solar_Open_Circuit_Voltage2 = 0;
+//    g_Mppt_Para.Solar_Open_Circuit_Voltage2 = 0;
 }
 /**
@ -305,25 +338,26 @@ void g_Mppt_Para_Init(void)
  */
 void task_Init(void)
 {
-    read_config_info();
+//    read_config_info();
    g_Mppt_Para_Init();
    TimeSliceOffset_Register(&m_runled, Task_RunLED, runled_reloadVal, runled_offset);
 //    m_refreshRegister.runFlag = 1;  /* 该启动后立即执行一次 */
-//    TimeSliceOffset_Register(&m_refreshRegister, Task_refreshRegister
+    TimeSliceOffset_Register(&m_refreshRegister, Task_refreshRegister
-//            , refreshRegister_reloadVal, refreshRegister_offset);
+            , refreshRegister_reloadVal, refreshRegister_offset);
 //    TimeSliceOffset_Register(&m_mpptControl, Task_mpptControl
 //            , mpptControl_reloadVal, mpptControl_offset);
    TimeSliceOffset_Register(&m_usart, Task_usart, usart_reloadVal, usart_offset);
 //
-//    TimeSliceOffset_Register(&m_wdi, Task_wdi, wdi_reloadVal, wdi_offset);
+    TimeSliceOffset_Register(&m_wdi, Task_wdi, wdi_reloadVal, wdi_offset);
    TimeSliceOffset_Register(&m_EnPowerSupply, Task_EnPowerSupply
            , EnPowerSupply_reloadVal, EnPowerSupply_offset);
 //    TimeSliceOffset_Register(&m_EnPowerSupply, Task_EnPowerSupply
 //            , EnPowerSupply_reloadVal, EnPowerSupply_offset);
    TimeSliceOffset_Start();    /* 启动时间片轮询 */
 }
@ -336,7 +370,7 @@ void task_Init(void)
  */
 void hardware_Init(void)
 {
-    TIM3_Init();
+    Systick_Init();
    TIM2_Init();
    uart_dev_init();
    PWM_TIM_Configuration();
@ -353,10 +387,13 @@ void hardware_Init(void)
 //    GPIO_WriteBit(POW_OUT_CON_GPIO, POW_OUT_CON_PIN, SET);
 //    TIM_SetCompare4(TIM4, 5000);
    GPIO_WriteBit(EnPowerSupply_GPIO, EnPowerSupply_PIN, RESET);
    Set_duty_ratio(&g_duty_ratio);
 //    Set_duty_ratio(0);
 //    Delay_Ms(100);
 //    TIM_SetCompare2(TIM4, 50);
 //    TIM1_Init(20);
    TIM3_Init(5);
 }
--- a/Hardware/inc/gpio.h
+++ b/Hardware/inc/gpio.h
@ -63,7 +63,7 @@ void DSG_PROT_Init(void);
 /* ¸ø±ÃµçÂ·µçÈÝ³äµç */
 /* EnPowerSupply  -->  PB7 */
 #define EnPowerSupply_GPIO GPIOB
-#define EnPowerSupply_PIN GPIO_Pin_7
+#define EnPowerSupply_PIN GPIO_Pin_3
 void EnPowerSupply_Init(void);
 #endif /* HARDWARE_INC_GPIO_H_ */
--- a/Hardware/inc/tim.h
+++ b/Hardware/inc/tim.h
@ -14,11 +14,16 @@
 extern uint8_t run_Broadcast;
-void TIM3_Init(void);
+void TIM3_Init(uint16_t delay_ms);
 void TIM3_Int_Init(uint16_t arr,uint16_t psc);
 void TIM2_Init(void);
 void TIM2_Int_Init(uint16_t arr,uint16_t psc);
 void Systick_Init(void);
 void TIM1_Init(uint16_t delay_ms);
 void TIM1_Int_Init(uint16_t arr,uint16_t psc);
 #endif /* HARDWARE_INC_TIM_H_ */
--- a/Hardware/src/gpio.c
+++ b/Hardware/src/gpio.c
@ -63,6 +63,8 @@ void POW_OUT_CON_Init(void)
    GPIO_InitStructure.GPIO_Mode = GPIO_Mode_Out_PP;      //ÍÆÍìÊä³ö
    GPIO_InitStructure.GPIO_Speed = GPIO_Speed_50MHz;
    GPIO_Init(POW_OUT_CON_GPIO, &GPIO_InitStructure);
    GPIO_WriteBit(POW_OUT_CON_GPIO, POW_OUT_CON_PIN, SET);
 }
 void EXTI2_IRQHandler(void) __attribute__((interrupt("WCH-Interrupt-fast")));
@ -110,7 +112,7 @@ void EnPowerSupply_Init(void)
    GPIO_InitStructure.GPIO_Speed = GPIO_Speed_50MHz;
    GPIO_Init(EnPowerSupply_GPIO, &GPIO_InitStructure);
-    GPIO_WriteBit(EnPowerSupply_GPIO, EnPowerSupply_PIN, RESET);
+    GPIO_WriteBit(EnPowerSupply_GPIO, EnPowerSupply_PIN, SET);
 }
--- a/Hardware/src/pwm.c
+++ b/Hardware/src/pwm.c
@ -57,12 +57,12 @@ void PWM_TIM_Configuration(void)
 void Set_duty_ratio(float *duty_ratio)
 {
-    if (*duty_ratio < 0.4) {
+    if (*duty_ratio < 0.5) {
-        *duty_ratio = 0.4;
+        *duty_ratio = 0.5;
-        return;
+//        return;
    } else if (*duty_ratio > 0.9) {
        *duty_ratio = 0.9;
-        return;
+//        return;
    }
    uint16_t pulse = *duty_ratio * (Period + 1);
--- a/Hardware/src/tim.c
+++ b/Hardware/src/tim.c
@ -8,9 +8,7 @@
 #include "tim.h"
 #include "timeSliceOffset.h"
 #include "pwm.h"
-
+#include "mppt_control.h"
 /* 时间基准为1ms，1ms切换一次任务 */
 #define delayms 1
 /* 延时时间 */
 #define delays 20
@ -20,13 +18,18 @@ uint8_t run_Broadcast = 1;
 void TIM3_IRQHandler(void) __attribute__((interrupt("WCH-Interrupt-fast")));
 void TIM2_IRQHandler(void) __attribute__((interrupt("WCH-Interrupt-fast")));
 void SysTick_Handler(void) __attribute__((interrupt("WCH-Interrupt-fast")));
-void TIM3_Init(void)
+void TIM1_UP_IRQHandler(void) __attribute__((interrupt("WCH-Interrupt-fast")));
 void TIM3_Init(uint16_t delay_ms)
 {
    /* 分频系数 */
    uint16_t psc = (SystemCoreClock / 10000) - 1;
    /* 分频系数 */
-    uint16_t arr = delayms * 10 - 1;
+    uint16_t arr = delay_ms * 10 - 1;
    TIM3_Int_Init(arr, psc);
 }
@ -49,11 +52,11 @@ void TIM3_Int_Init(uint16_t arr, uint16_t psc)
    //初始化TIM NVIC，设置中断优先级分组
    NVIC_InitStructure.NVIC_IRQChannel = TIM3_IRQn;           //TIM3中断
    NVIC_InitStructure.NVIC_IRQChannelPreemptionPriority = 0; //设置抢占优先级0
-    NVIC_InitStructure.NVIC_IRQChannelSubPriority = 3;        //设置响应优先级3
+    NVIC_InitStructure.NVIC_IRQChannelSubPriority = 1;        //设置响应优先级3
    NVIC_InitStructure.NVIC_IRQChannelCmd = ENABLE;           //使能通道1中断
    NVIC_Init(&NVIC_InitStructure); //初始化NVIC
-    TIM_Cmd(TIM3, ENABLE); //TIM3使能
+//    TIM_Cmd(TIM3, ENABLE); //TIM3使能
 }
 void TIM3_IRQHandler(void)
@ -63,7 +66,7 @@ void TIM3_IRQHandler(void)
 //    static int flag1 = 0;
    if (TIM_GetITStatus(TIM3, TIM_IT_Update) != RESET) { //检查TIM3中断是否发生。
        TIM_ClearITPendingBit(TIM3, TIM_IT_Update);    //清除TIM3的中断挂起位。
-        TimeSliceOffset_Produce();
+        test();
 //        flag1++;
 //        if (flag1 == 20) {
 //            if (flag) {
@ -129,3 +132,70 @@ void TIM2_IRQHandler(void)
        run_Broadcast = 1;
    }
 }
 //SysTick初始化配置          1MS进入一次中断
 static void SysTick_Config(uint32_t ticks)
 {
    SysTick->SR = 0;
    SysTick->CNT = 0;
    SysTick->CMP = ticks;
    SysTick->CTLR =0xF;
    NVIC_SetPriority(SysTicK_IRQn, 15);
    NVIC_EnableIRQ(SysTicK_IRQn);
 }
 void Systick_Init(void)
 {
    SysTick_Config((SystemCoreClock / 1000) - 1);
 }
 void SysTick_Handler(void)
 {
    SysTick->SR = 0;
    TimeSliceOffset_Produce();
 }
 void TIM1_Init(uint16_t delay_ms)
 {
    /* 分频系数 */
    uint16_t psc = (SystemCoreClock / 10000) - 1;
    /*  */
    uint16_t arr = delay_ms * 10 - 1;
 //    uint16_t arr = 10 - 1;
    TIM1_Int_Init(arr, psc);
 }
 void TIM1_Int_Init(uint16_t arr, uint16_t psc)
 {
    TIM_TimeBaseInitTypeDef  TIM_TimeBaseStructure;
    NVIC_InitTypeDef NVIC_InitStructure;
    RCC_PB2PeriphClockCmd(RCC_PB2Periph_TIM1, ENABLE); //使能TIM1时钟
    TIM_TimeBaseStructure.TIM_Period = arr;   //指定下次更新事件时要加载到活动自动重新加载寄存器中的周期值。
    TIM_TimeBaseStructure.TIM_Prescaler = psc; //指定用于划分TIM时钟的预分频器值。
    TIM_TimeBaseStructure.TIM_ClockDivision = TIM_CKD_DIV1;     //时钟分频因子
    TIM_TimeBaseStructure.TIM_CounterMode = TIM_CounterMode_Up; //TIM计数模式，向上计数模式
    TIM_TimeBaseInit(TIM1, &TIM_TimeBaseStructure); //根据指定的参数初始化TIMx的时间基数单位
    TIM_ITConfig(TIM1, TIM_IT_Update, ENABLE); //使能TIM1中断，允许更新中断
    //初始化TIM NVIC，设置中断优先级分组
    NVIC_InitStructure.NVIC_IRQChannel = TIM1_UP_IRQn;           //TIM1中断
    NVIC_InitStructure.NVIC_IRQChannelPreemptionPriority = 0;   //设置抢占优先级0
    NVIC_InitStructure.NVIC_IRQChannelSubPriority = 3;          //设置响应优先级3
    NVIC_InitStructure.NVIC_IRQChannelCmd = ENABLE;             //使能通道中断
    NVIC_Init(&NVIC_InitStructure); //初始化NVIC
    TIM_Cmd(TIM1, ENABLE); //TIM1使能
 }
 void TIM1_UP_IRQHandler(void)
 {
    if (TIM_GetITStatus(TIM1, TIM_IT_Update) != RESET) {    //检查TIM1中断是否发生。
        TIM_ClearITPendingBit(TIM1, TIM_IT_Update);         //清除TIM1的中断挂起位。
        printf("in tim1 irq \n");
    }
 }
--- a/obj/App/src/collect_Conversion.o
+++ b/obj/App/src/collect_Conversion.o
--- a/obj/App/src/inflash.o
+++ b/obj/App/src/inflash.o
--- a/obj/App/src/mppt_control.o
+++ b/obj/App/src/mppt_control.o
--- a/obj/App/src/sl_protocol.o
+++ b/obj/App/src/sl_protocol.o
--- a/obj/App/src/task.o
+++ b/obj/App/src/task.o
--- a/obj/Hardware/src/gpio.o
+++ b/obj/Hardware/src/gpio.o
--- a/obj/Hardware/src/pwm.o
+++ b/obj/Hardware/src/pwm.o
--- a/obj/Hardware/src/tim.d
+++ b/obj/Hardware/src/tim.d
@ -29,7 +29,8 @@ Hardware/src/tim.o: ../Hardware/src/tim.c \
 D:\psx\MPPT\git\Drivers\TimeSliceOffset/timeSliceOffset.h \
 D:\psx\MPPT\git\App\inc/uart_dev.h \
 D:\psx\MPPT\git\Drivers\RingQueue/ring_queue.h \
- D:\psx\MPPT\git\Hardware\inc/rs485.h D:\psx\MPPT\git\Hardware\inc/pwm.h
+ D:\psx\MPPT\git\Hardware\inc/rs485.h D:\psx\MPPT\git\Hardware\inc/pwm.h \
 D:\psx\MPPT\git\App\inc/mppt_control.h
 D:\psx\MPPT\git\Hardware\inc/tim.h:
@ -98,3 +99,5 @@ D:\psx\MPPT\git\Drivers\RingQueue/ring_queue.h:
 D:\psx\MPPT\git\Hardware\inc/rs485.h:
 D:\psx\MPPT\git\Hardware\inc/pwm.h:
 D:\psx\MPPT\git\App\inc/mppt_control.h:
--- a/obj/Hardware/src/tim.o
+++ b/obj/Hardware/src/tim.o
--- a/obj/mppt_Nos_V0.4.elf
+++ b/obj/mppt_Nos_V0.4.elf
--- a/obj/mppt_Nos_V0.4.hex
+++ b/obj/mppt_Nos_V0.4.hex
--- a/obj/mppt_Nos_V0.4.lst
+++ b/obj/mppt_Nos_V0.4.lst
--- a/obj/mppt_Nos_V0.4.map
+++ b/obj/mppt_Nos_V0.4.map