RPI Step Motor controller - Viktor Mihalovic
Contents
Project Overview:
The primary goal of the RPI Step Motor Controller project is to automate the process of controlling the height of the Oree R-t model laser arm for laser marking in production. This automation involves automatically scanning a product's serial number, retrieving information from a database, and adjusting the height of the laser arm accordingly. This project was focused on part to manage height of laer arm
Hardware Setup:
Raspberry Pi (Model: [Insert Model]) Oree R-t model laser Step Motor: 57CM22X Microstep Drive: DM542 Controller with display: MC-24MR-4MT-500-FX-A Bottom and top sensors: TL-Q5MC1-Z Software Setup: Programming Language: Python Libraries/Frameworks: RPi.GPIO Software Installed on Raspberry Pi: [List any additional software necessary for the project] Control Algorithm: The control algorithm involves receiving signals from the Raspberry Pi and sending control signals to the Microstep Drive DM542 to adjust the height of the laser arm based on product model information retrieved from the database.
User Interface:
The project currently does not include a user interface. Control signals are sent automatically based on the scanned product serial number and database information.
Testing and Validation:
Testing of the functionality involves:
Challenges and Solutions:
Challenges encountered during development:
Integrating the Raspberry Pi with the Microstep Drive DM542. Ensuring accurate height adjustments based on database information. Solutions:
Using Python for GPIO control on the Raspberry Pi. Implementing specific wiring configurations for proper communication with the Microstep Drive DM542.
Code Explanation:
- Import necessary libraries
import RPi.GPIO as GPIO import time
- Set GPIO mode
GPIO.setmode(GPIO.BCM)
class Arm:
def __init__(self):
# Initialize GPIO pins and variables
self.settings()
self.sensor_down = False
self.sensor_up = False
self.buttonUp = False
self.buttonDown = False
self.actHeight = -1
self.check_read_sensors()
self.numberOfSteps = 0
# Function to initialize GPIO settings
def settings(self):
# Define GPIO pins for motor control, sensors, and buttons
self.motor_direction_pin = 27
self.motor_step_pin = 22
self.sensor_down_pin = 23
self.buttonUpPin = 25
self.buttonDownPin = 6
self.sensor_up_pin = 24
self.delay = 0.000003 # Adjust this delay for motor speed
self.pulses_per_rev = 5000 # Set pulses per revolution
# Setup GPIO pins
GPIO.setup(self.motor_direction_pin, GPIO.OUT)
GPIO.setup(self.motor_step_pin, GPIO.OUT)
GPIO.setup(self.sensor_down_pin, GPIO.IN, pull_up_down=GPIO.PUD_DOWN)
GPIO.setup(self.sensor_up_pin, GPIO.IN, pull_up_down=GPIO.PUD_DOWN)
GPIO.setup(self.buttonUpPin, GPIO.IN, pull_up_down=GPIO.PUD_UP)
GPIO.setup(self.buttonDownPin, GPIO.IN, pull_up_down=GPIO.PUD_UP)
# Function to perform a single step
def step_once(self):
self.numberOfSteps += 1
GPIO.output(self.motor_step_pin, True)
time.sleep(self.delay)
GPIO.output(self.motor_step_pin, False)
time.sleep(self.delay)
# Function to step the motor forward
def step_forward(self):
GPIO.output(self.motor_direction_pin, True)
self.step_once()
self.actHeight += 0.0008
# Function to step the motor in reverse
def step_reverse(self):
GPIO.output(self.motor_direction_pin, False)
self.step_once()
self.actHeight -= 0.0008
# Function to stop the motor
def stopMotor(self):
GPIO.output(self.motor_step_pin, False)
# Function to read sensor states
def check_read_sensors(self):
self.sensor_down = not GPIO.input(self.sensor_down_pin)
self.sensor_up = not GPIO.input(self.sensor_up_pin)
self.buttonUp = not GPIO.input(self.buttonUpPin)
self.buttonDown = not GPIO.input(self.buttonDownPin)
# Main function to start height adjustment
def start(self):
while True:
self.check_read_sensors()
if self.sensor_down and self.buttonDown:
self.stopMotor()
print('Hit bottom')
continue
if self.sensor_up and self.buttonUp:
self.stopMotor()
print('Hit top')
continue
if self.buttonUp and self.buttonDown:
self.stopMotor()
print('Both Sensors')
break
if self.buttonUp:
self.step_forward()
print('Forward')
continue
if self.buttonDown:
self.step_reverse()
print('Backward')
continue
self.stopMotor()
GPIO.cleanup()
# Function to find the bottom position
def findBottom(self):
while not self.sensor_down:
self.check_read_sensors()
self.step_reverse()
self.actHeight = 143
self.numberOfSteps = 0
# Function to move to a specified height
def goto(self, height):
self.check_read_sensors()
if self.actHeight <= height:
while round(self.actHeight,2) != round(height,2) and not self.sensor_up:
self.step_forward()
self.check_read_sensors()
else:
while round(self.actHeight,2) != round(height,2) and not self.sensor_down:
self.step_reverse()
self.check_read_sensors()
- Main function
if __name__ == "__main__":
print("Program has started")
a = Arm()
a.findBottom()
print('I am at 0 cm')
time.sleep(4)
print('Going up to 480 mm')
a.goto(480)
print('I am at 480 mm')
time.sleep(4)
print('Going up to 200 mm')
a.goto(200)
print('I am at 200 mm')
time.sleep(4)
print('Going up to 0 mm')
a.goto(0)
print('Stopped at 143 mm due to height limit')
GPIO.cleanup()
Conclusion:
The RPI Step Motor Controller project successfully achieves the goal of automating the process of controlling the height of the Oree R-t model laser arm. With further improvements and enhancements, it can effectively contribute to the automation of the laser marking process in production.
