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PressToolAI_Visualization / app.py

jithenderchoudary

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	import cadquery as cq
	import numpy as np
	import matplotlib.pyplot as plt
	import pyvista as pv
	from reportlab.lib.pagesizes import letter
	from reportlab.pdfgen import canvas
	import gradio as gr
	import os
	from ansys.mapdl.core import launch_mapdl # For ANSYS integration


	# Function for Progressive Die Design
	def generate_die(length, width, thickness):
	try:
	plate = cq.Workplane("XY").box(length, width, thickness)
	punch = cq.Workplane("XY").rect(10, 10).extrude(5).translate((length / 4, width / 4, thickness / 2))
	die = plate.cut(punch)
	filename = "progressive_die.step"
	cq.exporters.export(die, filename)
	return filename
	except Exception as e:
	return f"Error generating die: {str(e)}"


	# Function to visualize die in 3D
	def visualize_die(length, width, thickness):
	try:
	plate = cq.Workplane("XY").box(length, width, thickness)
	punch = cq.Workplane("XY").rect(10, 10).extrude(5).translate((length / 4, width / 4, thickness / 2))
	die = plate.cut(punch)

	# Export to STL for visualization
	cq.exporters.exportShape(die.val(), "STL", "progressive_die.stl")

	# Visualize with PyVista
	mesh = pv.read("progressive_die.stl")
	plotter = pv.Plotter(off_screen=True)
	plotter.add_mesh(mesh, color="blue")
	screenshot = "progressive_die_visualization.png"
	plotter.screenshot(screenshot)
	return screenshot
	except Exception as e:
	return f"Error visualizing die: {str(e)}"


	# Function for Python-based Stress Analysis
	def stress_analysis(force, die_width, die_height, material_strength):
	try:
	stress = force / (die_width * die_height)
	safety_factor = material_strength / stress

	fig, ax = plt.subplots()
	ax.bar(["Stress", "Material Strength"], [stress, material_strength])
	ax.set_ylabel("Stress (MPa)")
	ax.set_title("Stress Analysis")
	plt.close(fig)

	return f"Safety Factor: {round(safety_factor, 2)}", fig
	except Exception as e:
	return f"Error in stress analysis: {str(e)}", None


	# ANSYS Integration for Stress Analysis
	def run_ansys_simulation(force, die_width, die_height, material_strength):
	try:
	# Launch ANSYS MAPDL instance
	mapdl = launch_mapdl()
	mapdl.prep7() # Enter pre-processing module

	# Define geometry and material properties
	mapdl.rectng(0, die_width, 0, die_height)
	mapdl.mp('EX', 1, material_strength)
	mapdl.et(1, 'PLANE183')

	# Apply loads
	mapdl.nsel('S', 'LOC', 'X', 0)
	mapdl.d('ALL', 'UX', 0)
	mapdl.f('ALL', 'FY', -force)

	# Solve
	mapdl.run('/SOLU')
	mapdl.solve()
	mapdl.finish()

	# Post-processing
	mapdl.post1()
	stress = mapdl.get_value('NODE', 1, 'S', 'EQV') # Retrieve max equivalent stress
	mapdl.exit()

	return f"Max Stress: {stress:.2f} MPa"
	except Exception as e:
	return f"Error running ANSYS simulation: {str(e)}"


	# SolidWorks Placeholder for Stress Analysis
	def solidworks_stress_analysis(force, die_width, die_height, material_strength):
	# Replace this function with SolidWorks API or external script
	try:
	output_file = "/path/to/solidworks/output.txt" # Replace with actual path
	if os.path.exists(output_file):
	with open(output_file, "r") as file:
	result = file.read()
	return result.strip()
	else:
	return "SolidWorks simulation output not found."
	except Exception as e:
	return f"Error running SolidWorks simulation: {str(e)}"


	# Function to generate PDF report
	def generate_pdf_report(data, filename="report.pdf"):
	try:
	c = canvas.Canvas(filename, pagesize=letter)
	c.drawString(100, 750, "Simulation Report")
	c.drawString(100, 730, f"Max Stress: {data.get('stress', 'N/A')} MPa")
	c.drawString(100, 710, f"Safety Factor: {data.get('safety_factor', 'N/A')}")
	c.save()
	return filename
	except Exception as e:
	return f"Error generating report: {str(e)}"


	# Tool Optimization Function
	def optimize_tool(speed, feed_rate, depth_of_cut, material):
	try:
	tool_life = 1000 / (speed * feed_rate * depth_of_cut)
	recommended_speed = 0.8 * speed
	recommended_feed_rate = 0.9 * feed_rate

	return {
	"Estimated Tool Life (hrs)": round(tool_life, 2),
	"Recommended Speed (m/min)": round(recommended_speed, 2),
	"Recommended Feed Rate (mm/rev)": round(recommended_feed_rate, 2)
	}
	except Exception as e:
	return {"Error": str(e)}


	# Gradio interface functions
	def stress_analysis_interface(force, die_width, die_height, material_strength, simulation_tool):
	if simulation_tool == "Python":
	# Python-based stress analysis
	safety_factor, fig = stress_analysis(force, die_width, die_height, material_strength)
	data = {"stress": force / (die_width * die_height), "safety_factor": safety_factor}
	pdf_filename = generate_pdf_report(data)
	return safety_factor, fig, pdf_filename

	elif simulation_tool == "ANSYS":
	# Run ANSYS-based simulation
	result = run_ansys_simulation(force, die_width, die_height, material_strength)
	return result, None, None

	elif simulation_tool == "SolidWorks":
	# Run SolidWorks-based simulation
	result = solidworks_stress_analysis(force, die_width, die_height, material_strength)
	return result, None, None

	else:
	return "Invalid simulation tool selected", None, None


	# Create Gradio App
	with gr.Blocks() as app:
	gr.Markdown("## Press Tool AI Suite")
	gr.Markdown("Select a tool below to get started:")

	with gr.Tabs():
	with gr.Tab("Progressive Die Design"):
	gr.Markdown("### Enter Dimensions for Progressive Die")
	length = gr.Number(label="Length (mm)", value=100)
	width = gr.Number(label="Width (mm)", value=50)
	thickness = gr.Number(label="Thickness (mm)", value=10)
	die_output = gr.Textbox(label="Die Output File")
	visualization_output = gr.Image(label="3D Visualization")
	die_button = gr.Button("Generate Die")
	die_button.click(
	lambda l, w, t: (generate_die(l, w, t), visualize_die(l, w, t)),
	inputs=[length, width, thickness],
	outputs=[die_output, visualization_output],
	)

	with gr.Tab("Stress Analysis"):
	gr.Markdown("### Select Simulation Tool and Enter Parameters for Stress Analysis")
	simulation_tool = gr.Dropdown(
	choices=["Python", "ANSYS", "SolidWorks"],
	label="Simulation Tool",
	value="Python",
	)
	force = gr.Number(label="Force (N)", value=10000)
	die_width = gr.Number(label="Width (m)", value=0.05)
	die_height = gr.Number(label="Height (m)", value=0.01)
	material_strength = gr.Number(label="Material Strength (MPa)", value=250)
	safety_factor_output = gr.Textbox(label="Safety Factor or Simulation Result")
	stress_chart = gr.Plot()
	pdf_file = gr.File(label="Download Report (Python Only)")
	stress_button = gr.Button("Analyze Stress")
	stress_button.click(
	stress_analysis_interface,
	inputs=[force, die_width, die_height, material_strength, simulation_tool],
	outputs=[safety_factor_output, stress_chart, pdf_file],
	)

	with gr.Tab("Tool Optimization"):
	gr.Markdown("### Enter Machining Parameters for Tool Optimization")
	speed = gr.Number(label="Cutting Speed (m/min)", value=100)
	feed_rate = gr.Number(label="Feed Rate (mm/rev)", value=0.2)
	depth_of_cut = gr.Number(label="Depth of Cut (mm)", value=1.0)
	material = gr.Dropdown(choices=["Steel", "Aluminum", "Titanium"], label="Material", value="Steel")
	optimization_results = gr.JSON(label="Optimization Results")
	optimize_button = gr.Button("Optimize Tool")
	optimize_button.click(
	optimize_tool,
	inputs=[speed, feed_rate, depth_of_cut, material],
	outputs=optimization_results,
	)

	# Launch the app
	app.launch()