init

2021-09-12 13:56:27 +02:00 · 2021-09-12 13:56:27 +02:00 · b13b09da33
commit b13b09da33
parent 0eb59934d6
3 changed files with 713 additions and 0 deletions
--- a/combined-automode.py
+++ b/combined-automode.py
@ -0,0 +1,287 @@
 #!/usr/bin/python
 # -*- coding: utf-8 -*-
 import time
 import serial, sys
 import os
 from datetime import datetime
 from bitstring import BitArray
 serial_timeout=0.1
 byte3=0
 byte4=0
 byte5=0
 byte6=0
 i=0
 pvfaultdesc = [0]*8
 pvfaultdesc[0]="load short-circuit protection"
 pvfaultdesc[1]="load overcurrent protection"
 pvfaultdesc[2]="battery low-voltage protection"
 pvfaultdesc[3]="reserved"
 pvfaultdesc[4]="solar panel array1 open-circuit breakdown(it means the controller does not detect the solar panel voltage within 24h)"
 pvfaultdesc[5]="solar panel array1 over-voltage protection"
 pvfaultdesc[6]="delayed protection phase for load overcurrent"
 pvfaultdesc[7]="shut the load compulsively"
 def pvstatusbit(bit):
    if bit == '1':
        print("gesetzt :%s" % bit)
    else:
        print("nicht gesetzt :%s" % bit)
 def pvstatus():
 # current status of system
    ser = serial.Serial('/dev/ttyUSB0', 9600, timeout=serial_timeout)
    command = "\x01\x61\x00\x00\x00\x00\xBD"
    global byte3
    global byte4
    del byte3
    del byte4
    ser.flushInput() #clear buffer
    ser.write(command) #send prepared command
    skip=ser.read(2) #skip first two bytes
    byte3=ser.read(1)
    byte4=ser.read(1)
    ser.close()
    if (
            len(byte3) > 0  and len(byte4) > 0
        ):  
            byte3=byte3.encode('hex')
            bitstring1=BitArray(hex=byte3)
 #            sys.stdout.write('Inputstring:\t')
 #            sys.stdout.write(bitstring1.bin)
 #            sys.stdout.write('\n')
            pvfaultstate(bitstring1.bin)
            sys.stdout.write('\n')
    else :
            sys.stdout.write('Voltage communication error!')
 def pvfaultstate(bytearray):
    global pvfaultdesc
 #    print("Inputstring Funktion:\t %s" %bytearray)
    i=0
    arraylen=len(bytearray)
 #    print (" Array ist %s Elemente lang" %(arraylen))
    while i <=arraylen-1:
 	if bytearray[i] =='1':
            print("Fehler aktiv: %s (Byte: %s)" % (pvfaultdesc[i], i) )
        #pvstatusbit(bytearray[i])
        if i<=arraylen: i=i+1
 # last anschalten
 def pvswitch(state):
    ser = serial.Serial('/dev/ttyUSB0', 9600, timeout=serial_timeout)
    if state == 0:
        command = "\x01\x55\x00\x00\x00\x00\x26" #last aus
        print ("demanding controller removing closing the load compulsively")
    else:
        command = "\x01\x54\x00\x00\x00\x00\xF5" #last an
        print ("demanding controller closing the loads compulsively")
    ser.write(command)
    ser.close()
 def get_PV_Ah():
    ser = serial.Serial('/dev/ttyUSB0', 9600, timeout=serial_timeout)
    command = "\x01\x05\x00\x00\x00\x00\x9B" # the back transmission data from the controlleris the accumulative generating power data of solar panel array1(Ah, DC/DC output), and the data are the long data shaping with symbol, and the accumulative Ah scaling is 1Ah/LSB.
    ser.flushInput() #clear buffer
    ser.write(command) #send prepared command
    skip=ser.read(2) #skip first two bytes
    byte3=ser.read(1)
    byte4=ser.read(1)
    byte5=ser.read(1)
    byte6=ser.read(1)
    ser.close()
    print ("PV: \t\t\t %s Ah" % (BitArray(hex=byte6.encode('hex'))+BitArray(hex=byte5.encode('hex'))+BitArray(hex=byte4.encode('hex'))+BitArray(hex=byte3.encode('hex'))).uint)
 def get_load_Ah():
    ser = serial.Serial('/dev/ttyUSB0', 9600, timeout=serial_timeout)
    command = "\x01\x16\x00\x00\x00\x00\xA3" # the back transmission data from the controlleris the accumulative generating power data of solar panel array1(Ah, DC/DC output), and the data are the long data shaping with symbol, and the accumulative Ah scaling is 1Ah/LSB.
    ser.flushInput() #clear buffer
    ser.write(command) #send prepared command
    skip=ser.read(2) #skip first two bytes
    byte3=ser.read(1)
    byte4=ser.read(1)
    byte5=ser.read(1)
    byte6=ser.read(1)
    ser.close()
    print ("Load: \t\t\t %s Ah" % (BitArray(hex=byte6.encode('hex'))+BitArray(hex=byte5.encode('hex'))+BitArray(hex=byte4.encode('hex'))+BitArray(hex=byte3.encode('hex'))).uint)
 while True:
  try:
    now = datetime.now()
    os.system('clear')
    print(now)
 #    pvswitch(1)
 # battery voltage
    ser = serial.Serial('/dev/ttyUSB0', 9600, timeout=serial_timeout)
    command = "\x01\x10\x00\x00\x00\x00\x2B"
    del byte3
    del byte4
    ser.flushInput() #clear buffer
    ser.write(command) #send prepared command
    skip=ser.read(2) #skip first two bytes
    byte3=ser.read(1)
    byte4=ser.read(1)
    ser.close()
    if (
            len(byte3) > 0  and len(byte4) > 0
        ):  
            value1=ord(byte3)
            value2=ord(byte4)
            voltage=(value2 * 256 + value1) / 100
            voltage_modulo=(value2 * 256 + value1) % 100
            sys.stdout.write('BATTERY:\t\t')
            sys.stdout.write(str(voltage))
            sys.stdout.write('.')
            sys.stdout.write(str(voltage_modulo))
            sys.stdout.write(' V\n')
    else :
            sys.stdout.write('Voltage communication error!')
 # pv voltage/current
    ser = serial.Serial('/dev/ttyUSB0', 9600, timeout=serial_timeout)
    command = "\x01\x01\x00\x00\x00\x00\x84"
    del byte3
    del byte4
    del byte5
    del byte6
    ser.flushInput() #clear buffer
    ser.write(command) #send prepared command
    skip=ser.read(2) #skip first two bytes
    byte3=ser.read(1)
    byte4=ser.read(1)
    byte5=ser.read(1)
    byte6=ser.read(1)
    ser.close()
    value1=ord(byte3)
    value2=ord(byte4)
    value3=ord(byte5)
    value4=ord(byte6)
    voltage=(value2 * 256 + value1) / 100
    voltage_modulo=(value2 * 256 + value1) % 100
    current=(value4 *256 + value3) / 100
    current_modulo=(value4 * 256 + value3) % 100
    sys.stdout.write('PV INPUT:\t\t')
    sys.stdout.write(str(voltage))
    sys.stdout.write('.')
    sys.stdout.write(str(voltage_modulo))
    sys.stdout.write(' V')
    sys.stdout.write('\t')
    sys.stdout.write(str(current))
    sys.stdout.write('.')
    sys.stdout.write(str(current_modulo))
    sys.stdout.write(' A \n')
 # current load
    ser = serial.Serial('/dev/ttyUSB0', 9600, timeout=serial_timeout)
    command = "\x01\x14\x00\x00\x00\x00\x34"
    del byte3
    del byte4
    ser.flushInput() #clear buffer
    ser.write(command) #send prepared command
    skip=ser.read(2) #skip first two bytes
    byte3=ser.read(1)
    byte4=ser.read(1)
    ser.close()
    value1=ord(byte3)
    value2=ord(byte4)
    current=(value2 * 256 + value1) / 100
    current_modulo=(value2 * 256 + value1) % 100
    sys.stdout.write('LOAD:\t\t\t\t')
    sys.stdout.write(str(current))
    sys.stdout.write('.')
    sys.stdout.write(str(current_modulo))
    sys.stdout.write(' A\n')
 # temperature & battery capacity
    ser = serial.Serial('/dev/ttyUSB0', 9600, timeout=serial_timeout)
    command = "\x01\x11\x00\x00\x00\x00\xF8"
    del byte3
    del byte4
    del byte5
    del byte6
    ser.flushInput() #clear buffer
    ser.write(command) #send prepared command
    skip=ser.read(2) #skip first two bytes
    byte3=ser.read(1)
    byte4=ser.read(1)
    byte5=ser.read(1)
    byte6=ser.read(1)
    ser.close()
    value1=ord(byte3)
    value2=ord(byte4)
    value3=ord(byte5)
    value4=ord(byte6)
    temperature=(value2 * 256 + value1) 
    capacity=(value4 * 256 + value3)
    sys.stdout.write('Temperature:\t\t\t\t')
    sys.stdout.write(str(temperature))
    sys.stdout.write(' °C\n')
    sys.stdout.write('Battery Capacity:\t\t\t')
    sys.stdout.write(str(capacity))
    sys.stdout.write(' %\n')
    print("\n\naktive Fehler:")
    pvstatus()
    get_PV_Ah()
    get_load_Ah()
 # sleep 10 seconds before starting over
    time.sleep(10)
  except KeyboardInterrupt:
      print("\n\nkilled via CTRL+C -  Bye")
      #pvswitch(0) #last ausschalten
      sys.exit()
--- a/combined.py
+++ b/combined.py
@ -0,0 +1,287 @@
 #!/usr/bin/python
 # -*- coding: utf-8 -*-
 import time
 import serial, sys
 import os
 from datetime import datetime
 from bitstring import BitArray
 serial_timeout=0.1
 byte3=0
 byte4=0
 byte5=0
 byte6=0
 i=0
 pvfaultdesc = [0]*8
 pvfaultdesc[0]="load short-circuit protection"
 pvfaultdesc[1]="load overcurrent protection"
 pvfaultdesc[2]="battery low-voltage protection"
 pvfaultdesc[3]="reserved"
 pvfaultdesc[4]="solar panel array1 open-circuit breakdown(it means the controller does not detect the solar panel voltage within 24h)"
 pvfaultdesc[5]="solar panel array1 over-voltage protection"
 pvfaultdesc[6]="delayed protection phase for load overcurrent"
 pvfaultdesc[7]="shut the load compulsively"
 def pvstatusbit(bit):
    if bit == '1':
        print("gesetzt :%s" % bit)
    else:
        print("nicht gesetzt :%s" % bit)
 def pvstatus():
 # current status of system
    ser = serial.Serial('/dev/ttyUSB0', 9600, timeout=serial_timeout)
    command = "\x01\x61\x00\x00\x00\x00\xBD"
    global byte3
    global byte4
    del byte3
    del byte4
    ser.flushInput() #clear buffer
    ser.write(command) #send prepared command
    skip=ser.read(2) #skip first two bytes
    byte3=ser.read(1)
    byte4=ser.read(1)
    ser.close()
    if (
            len(byte3) > 0  and len(byte4) > 0
        ):  
            byte3=byte3.encode('hex')
            bitstring1=BitArray(hex=byte3)
 #            sys.stdout.write('Inputstring:\t')
 #            sys.stdout.write(bitstring1.bin)
 #            sys.stdout.write('\n')
            pvfaultstate(bitstring1.bin)
            sys.stdout.write('\n')
    else :
            sys.stdout.write('Voltage communication error!')
 def pvfaultstate(bytearray):
    global pvfaultdesc
 #    print("Inputstring Funktion:\t %s" %bytearray)
    i=0
    arraylen=len(bytearray)
 #    print (" Array ist %s Elemente lang" %(arraylen))
    while i <=arraylen-1:
 	if bytearray[i] =='1':
            print("Fehler aktiv: %s (Byte: %s)" % (pvfaultdesc[i], i) )
        #pvstatusbit(bytearray[i])
        if i<=arraylen: i=i+1
 # last anschalten
 def pvswitch(state):
    ser = serial.Serial('/dev/ttyUSB0', 9600, timeout=serial_timeout)
    if state == 0:
        command = "\x01\x55\x00\x00\x00\x00\x26" #last aus
        print ("demanding controller removing closing the load compulsively")
    else:
        command = "\x01\x54\x00\x00\x00\x00\xF5" #last an
        print ("demanding controller closing the loads compulsively")
    ser.write(command)
    ser.close()
 def get_PV_Ah():
    ser = serial.Serial('/dev/ttyUSB0', 9600, timeout=serial_timeout)
    command = "\x01\x05\x00\x00\x00\x00\x9B" # the back transmission data from the controlleris the accumulative generating power data of solar panel array1(Ah, DC/DC output), and the data are the long data shaping with symbol, and the accumulative Ah scaling is 1Ah/LSB.
    ser.flushInput() #clear buffer
    ser.write(command) #send prepared command
    skip=ser.read(2) #skip first two bytes
    byte3=ser.read(1)
    byte4=ser.read(1)
    byte5=ser.read(1)
    byte6=ser.read(1)
    ser.close()
    print ("PV: \t\t\t %s Ah" % (BitArray(hex=byte6.encode('hex'))+BitArray(hex=byte5.encode('hex'))+BitArray(hex=byte4.encode('hex'))+BitArray(hex=byte3.encode('hex'))).uint)
 def get_load_Ah():
    ser = serial.Serial('/dev/ttyUSB0', 9600, timeout=serial_timeout)
    command = "\x01\x16\x00\x00\x00\x00\xA3" # the back transmission data from the controlleris the accumulative generating power data of solar panel array1(Ah, DC/DC output), and the data are the long data shaping with symbol, and the accumulative Ah scaling is 1Ah/LSB.
    ser.flushInput() #clear buffer
    ser.write(command) #send prepared command
    skip=ser.read(2) #skip first two bytes
    byte3=ser.read(1)
    byte4=ser.read(1)
    byte5=ser.read(1)
    byte6=ser.read(1)
    ser.close()
    print ("Load: \t\t\t %s Ah" % (BitArray(hex=byte6.encode('hex'))+BitArray(hex=byte5.encode('hex'))+BitArray(hex=byte4.encode('hex'))+BitArray(hex=byte3.encode('hex'))).uint)
 while True:
  try:
    now = datetime.now()
    os.system('clear')
    print(now)
 #    pvswitch(1)
 # battery voltage
    ser = serial.Serial('/dev/ttyUSB0', 9600, timeout=serial_timeout)
    command = "\x01\x10\x00\x00\x00\x00\x2B"
    del byte3
    del byte4
    ser.flushInput() #clear buffer
    ser.write(command) #send prepared command
    skip=ser.read(2) #skip first two bytes
    byte3=ser.read(1)
    byte4=ser.read(1)
    ser.close()
    if (
            len(byte3) > 0  and len(byte4) > 0
        ):  
            value1=ord(byte3)
            value2=ord(byte4)
            voltage=(value2 * 256 + value1) / 100
            voltage_modulo=(value2 * 256 + value1) % 100
            sys.stdout.write('BATTERY:\t\t')
            sys.stdout.write(str(voltage))
            sys.stdout.write('.')
            sys.stdout.write(str(voltage_modulo))
            sys.stdout.write(' V\n')
    else :
            sys.stdout.write('Voltage communication error!')
 # pv voltage/current
    ser = serial.Serial('/dev/ttyUSB0', 9600, timeout=serial_timeout)
    command = "\x01\x01\x00\x00\x00\x00\x84"
    del byte3
    del byte4
    del byte5
    del byte6
    ser.flushInput() #clear buffer
    ser.write(command) #send prepared command
    skip=ser.read(2) #skip first two bytes
    byte3=ser.read(1)
    byte4=ser.read(1)
    byte5=ser.read(1)
    byte6=ser.read(1)
    ser.close()
    value1=ord(byte3)
    value2=ord(byte4)
    value3=ord(byte5)
    value4=ord(byte6)
    voltage=(value2 * 256 + value1) / 100
    voltage_modulo=(value2 * 256 + value1) % 100
    current=(value4 *256 + value3) / 100
    current_modulo=(value4 * 256 + value3) % 100
    sys.stdout.write('PV INPUT:\t\t')
    sys.stdout.write(str(voltage))
    sys.stdout.write('.')
    sys.stdout.write(str(voltage_modulo))
    sys.stdout.write(' V')
    sys.stdout.write('\t')
    sys.stdout.write(str(current))
    sys.stdout.write('.')
    sys.stdout.write(str(current_modulo))
    sys.stdout.write(' A \n')
 # current load
    ser = serial.Serial('/dev/ttyUSB0', 9600, timeout=serial_timeout)
    command = "\x01\x14\x00\x00\x00\x00\x34"
    del byte3
    del byte4
    ser.flushInput() #clear buffer
    ser.write(command) #send prepared command
    skip=ser.read(2) #skip first two bytes
    byte3=ser.read(1)
    byte4=ser.read(1)
    ser.close()
    value1=ord(byte3)
    value2=ord(byte4)
    current=(value2 * 256 + value1) / 100
    current_modulo=(value2 * 256 + value1) % 100
    sys.stdout.write('LOAD:\t\t\t\t')
    sys.stdout.write(str(current))
    sys.stdout.write('.')
    sys.stdout.write(str(current_modulo))
    sys.stdout.write(' A\n')
 # temperature & battery capacity
    ser = serial.Serial('/dev/ttyUSB0', 9600, timeout=serial_timeout)
    command = "\x01\x11\x00\x00\x00\x00\xF8"
    del byte3
    del byte4
    del byte5
    del byte6
    ser.flushInput() #clear buffer
    ser.write(command) #send prepared command
    skip=ser.read(2) #skip first two bytes
    byte3=ser.read(1)
    byte4=ser.read(1)
    byte5=ser.read(1)
    byte6=ser.read(1)
    ser.close()
    value1=ord(byte3)
    value2=ord(byte4)
    value3=ord(byte5)
    value4=ord(byte6)
    temperature=(value2 * 256 + value1) 
    capacity=(value4 * 256 + value3)
    sys.stdout.write('Temperature:\t\t\t\t')
    sys.stdout.write(str(temperature))
    sys.stdout.write(' °C\n')
    sys.stdout.write('Battery Capacity:\t\t\t')
    sys.stdout.write(str(capacity))
    sys.stdout.write(' %\n')
    print("\n\naktive Fehler:")
    pvstatus()
    get_PV_Ah()
    get_load_Ah()
 # sleep 10 seconds before starting over
    time.sleep(10)
  except KeyboardInterrupt:
      print("\n\nkilled via CTRL+C -  Bye")
      #pvswitch(0) #last ausschalten
      sys.exit()
--- a/reset-errors.py
+++ b/reset-errors.py
@ -0,0 +1,139 @@
 #!/usr/bin/python
 # -*- coding: utf-8 -*-
 import time
 import serial, sys
 import os
 from datetime import datetime
 from bitstring import BitArray
 serial_timeout=0.1
 byte3=0
 byte4=0
 byte5=0
 byte6=0
 i=0
 pvfaultdesc = [0]*8
 pvfaultdesc[0]="load short-circuit protection"
 pvfaultdesc[1]="load overcurrent protection"
 pvfaultdesc[2]="battery low-voltage protection"
 pvfaultdesc[3]="reserved"
 pvfaultdesc[4]="solar panel array1 open-circuit breakdown(it means the controller does not detect the solar panel voltage within 24h)"
 pvfaultdesc[5]="solar panel array1 over-voltage protection"
 pvfaultdesc[6]="delayed protection phase for load overcurrent"
 pvfaultdesc[7]="shut the load compulsively"
 def pv_reset_lowvoltage():
    print("Reset Unterspannungs Sicherung:")
    ser = serial.Serial('/dev/ttyUSB0', 9600, timeout=serial_timeout)
    command = "\x01\x51\x00\x00\x00\x00\x39"
    global byte3
    global byte4
    ser.flushInput() #clear buffer
    ser.write(command) #send prepared command
    ser.close()
    print("DONE")
 def pv_reset_shortcuircuit():
    print("Reset Kurzschluss Sicherung:")
    ser = serial.Serial('/dev/ttyUSB0', 9600, timeout=serial_timeout)
    command = "\x01\x53\x00\x00\x00\x00\xAE"
    global byte3
    global byte4
    ser.flushInput() #clear buffer
    ser.write(command) #send prepared command
    ser.close()
    print("DONE")
 def pv_reset_overcurrent():
    print("Reset Ueberlast Sicherung:")
    ser = serial.Serial('/dev/ttyUSB0', 9600, timeout=serial_timeout)
    command = "\x01\x52\x00\x00\x00\x00\x7D"
    global byte3
    global byte4
    ser.flushInput() #clear buffer
    ser.write(command) #send prepared command
    ser.close()
    print("DONE")   
 def pvstatusbit(bit):
    if bit == '1':
        print("gesetzt :%s" % bit)
    else:
        print("nicht gesetzt :%s" % bit)
 def pvstatus():
 # current status of system
    ser = serial.Serial('/dev/ttyUSB0', 9600, timeout=serial_timeout)
    command = "\x01\x61\x00\x00\x00\x00\xBD"
    global byte3
    global byte4
    ser.flushInput() #clear buffer
    ser.write(command) #send prepared command
    skip=ser.read(2) #skip first two bytes
    byte3=ser.read(1)
    byte4=ser.read(1)
    ser.close()
    if (
            len(byte3) > 0  and len(byte4) > 0
        ):  
            byte3=byte3.encode('hex')
            bitstring1=BitArray(hex=byte3)
 #            sys.stdout.write('Inputstring:\t')
 #            sys.stdout.write(bitstring1.bin)
 #            sys.stdout.write('\n')
            pvfaultstate(bitstring1.bin)
            sys.stdout.write('\n')
    else :
            sys.stdout.write('Voltage communication error!')
 def pvfaultstate(bytearray):
    global pvfaultdesc
 #    print("Inputstring Funktion:\t %s" %bytearray)
    i=0
    arraylen=len(bytearray)
 #    print (" Array ist %s Elemente lang" %(arraylen))
    while i <=arraylen-1:
 	if bytearray[i] =='1':
            print("Fehler aktiv: %s (Byte: %s)" % (pvfaultdesc[i], i) )
        #pvstatusbit(bytearray[i])
        if i<=arraylen: i=i+1
 while True:
  try:
    now = datetime.now()
    os.system('clear')
    print(now)
    print("aktive Fehler:")
    pvstatus()
    time.sleep(0.5)
    #pv_reset_shortcuircuit()
    #time.sleep(0.5)
    pv_reset_overcurrent()
    time.sleep(0.5)
    pv_reset_lowvoltage()
    print("aktive Fehler nach reset:")
    pvstatus()
    print("erneuter reset nach 5 Sekunden")
 # sleep 10 seconds before starting over
    time.sleep(5)
  except KeyboardInterrupt:
      print("\n\nkilled via CTRL+C -  Bye")
      #pvswitch(0) #last ausschalten
      sys.exit()