Solidworks tutorial | Design and Assembly of Bicycle in Solidworks

CAD CAM TUTORIAL BY MAHTABALAM45 minutes read

The text details a comprehensive process for designing and assembling a bicycle in SolidWorks, highlighting steps such as creating sketches, applying dimensions, and performing extrusions for various components like the handle, frame, and tires. It emphasizes the importance of defining relations and ensuring all parts are correctly aligned for a functional assembly, culminating in the bicycle being ready for animation with appropriate movement settings.

Insights

  • The process of designing a bicycle in SolidWorks begins with creating essential components like the steering handle and frame, emphasizing the importance of precise dimensions and relations, such as symmetry and centerlines, to ensure a well-defined and functional design.
  • Throughout the assembly, various features like extruded cuts and fillets are utilized to refine the shapes and connections between parts, highlighting the need for attention to detail in both the geometric and material aspects, such as applying specific colors and finishes to distinguish between different components.
  • The final assembly involves careful alignment and relations between parts, such as concentric and coincident relations, to ensure that the bicycle functions properly, demonstrating the importance of both mechanical relationships and dynamic motion within the design process.

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Recent questions

  • What is a bicycle frame made of?

    A bicycle frame is typically made of materials like aluminum, steel, carbon fiber, or titanium. Each material offers different benefits, such as weight, strength, and cost. Aluminum is lightweight and resistant to corrosion, making it a popular choice for many modern bikes. Steel is known for its durability and comfort due to its natural flex, while carbon fiber is favored for high-performance bikes due to its strength-to-weight ratio. Titanium combines the best of both worlds, offering a lightweight and strong frame but at a higher cost. The choice of material can significantly affect the bike's performance, handling, and overall ride quality.

  • How do I maintain my bicycle?

    Maintaining a bicycle involves several key practices to ensure its longevity and performance. Regularly check tire pressure and inflate them to the recommended levels, as proper inflation improves handling and reduces wear. Clean the chain and apply lubricant to keep it running smoothly, preventing rust and wear. Inspect the brakes for wear and ensure they are functioning correctly, as safety is paramount. Additionally, check the gears and derailleurs for proper alignment and function. Periodically inspect the frame for any signs of damage or wear, and ensure all bolts and components are tightened to the manufacturer's specifications. Regular maintenance can help prevent costly repairs and enhance your riding experience.

  • What are the benefits of cycling?

    Cycling offers numerous benefits for both physical and mental health. Physically, it is an excellent cardiovascular exercise that improves heart health, builds muscle strength, and enhances endurance. Regular cycling can help with weight management and reduce the risk of chronic diseases such as diabetes and hypertension. Mentally, cycling can boost mood and reduce stress levels, providing a sense of freedom and enjoyment. It also promotes social interaction when done in groups or clubs. Additionally, cycling is an environmentally friendly mode of transportation, reducing carbon footprints and contributing to cleaner air. Overall, cycling is a versatile activity that can be adapted to various fitness levels and lifestyles.

  • How do I choose a bicycle?

    Choosing a bicycle involves considering several factors to ensure it meets your needs and preferences. First, determine the type of riding you plan to do, such as road cycling, mountain biking, or commuting, as different bikes are designed for specific terrains and purposes. Next, consider the frame size and geometry, which should fit your body for comfort and efficiency. Test ride different models to assess handling and comfort. Additionally, think about the components, such as gears and brakes, as higher-quality parts can enhance performance. Finally, set a budget, as bicycles can vary significantly in price. Researching and comparing options will help you find the right bike for your cycling goals.

  • What is the purpose of bicycle gears?

    Bicycle gears serve the essential purpose of allowing riders to adjust their pedaling effort based on terrain and riding conditions. Gears enable cyclists to shift between different levels of resistance, making it easier to climb hills or accelerate on flat surfaces. By changing gears, riders can maintain a consistent cadence, which is the rate at which they pedal, optimizing their energy expenditure. Lower gears provide more torque for climbing, while higher gears allow for faster speeds on flat terrain. Understanding how to use gears effectively can enhance a cyclist's performance and make rides more enjoyable, especially over varied landscapes.

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Summary

00:00

Bicycle Handle and Frame Design in SolidWorks

  • Begin by creating a bicycle steering handle in SolidWorks, starting with a sketch on the top plane. Define a centerline and create a line connected to it, establishing symmetric relations between the endpoints and the centerline.
  • Set specific dimensions for the sketch: 70 mm, 40 mm, 17.6 mm, 45 mm, and a distance of 35 mm from the origin. Apply a fillet of 6 mm to the ends and adjust the dimensions to 26 mm and 8 mm as needed.
  • Use the extruded boss feature to extrude the handle 20 mm, keeping the midplane condition, and apply an orange color to the body. Create a half-circle arc with a radius of 12.5 mm and an offset of 4 mm, then perform an extruded cut to remove material from both sides.
  • For the handle rod, sketch a circle with a diameter of 20 mm, positioned 15.82 mm from the outer edge, and extrude it to a length of 225 mm. Create a new plane 20 mm from the center of the circle to modify the rod sketch.
  • Extend the handle by sketching a line on the new plane, defining dimensions of 230 mm, 30 mm, and 68 mm for the arc radius, and a gap of 57.5 mm. Hide the plane after completing the sketch.
  • Create a circle with a diameter of 30 mm on the front plane, extruding it 150 mm in the reverse direction. Create another plane 50 mm from the front plane to sketch additional geometry for the bicycle frame.
  • Define a vertical centerline and create a geometry with dimensions of 11 mm, 10 mm, and angles of 115 degrees. Ensure the sketch is fully defined and extrude it 4 mm, applying an orange color to the body.
  • Create a handle by sketching a circle with a diameter of 25 mm, establishing a cosine relation with another circle. Define the handle's dimensions, including a distance of 29.5 mm and a vertical distance of 107.8 mm.
  • For the rubber grips, sketch circles with diameters of 31.7 mm and 60 mm, extruding them to 123 mm and 4 mm respectively, and apply a rubber material to these parts.
  • Finally, create a bicycle frame by sketching a spline with a length of 390 mm and a vertical length of 188.3 mm. Create two tangent planes and define additional dimensions for the frame, ensuring all sketches are fully defined before proceeding with extrusions.

50:37

Bicycle Frame Design and Assembly Instructions

  • Begin by setting the dimensions for the initial sketch: create a line of 125 millimeters, then adjust the resistance to 7.5 millimeters. Connect two points and ensure the angle is set to 140 degrees.
  • Define a line with a length of 230 millimeters, then create a fillet of 100 millimeters between two lines, maintaining a distance of 20 millimeters between them for proper definition.
  • Exit the sketch and navigate to the "Features" tab to select "Boss/Base," then sketch a circle with a diameter of 30 millimeters. Create a perpendicular plane to the selected line and sketch another circle on this plane.
  • Use the "Fillet" tool to apply a 5-millimeter fillet to the ends of the newly created lines, ensuring the dimensions are accurate for the bicycle frame design.
  • Create an extruded cut with a depth of 1.5 millimeters on the top face, then repeat the process for the bottom face, ensuring the cuts go through all material.
  • Sketch a circle with a diameter of 40 millimeters on a designated face, extrude it to a depth of 5 millimeters, and ensure the result is merged with the existing body.
  • For the bicycle tire, sketch a centerline and define dimensions of 145.25 millimeters and 125 millimeters, then create a zero center point arc with a diameter of 22.5 millimeters.
  • Create a sprocket by sketching a circle with a diameter of 29.09 millimeters, then use the circular pattern tool to create 14 equally spaced instances around the center.
  • Define a circular pattern for the spokes, ensuring to select the correct bodies and set the number of patterns to 14 for even distribution around the wheel.
  • Finally, apply a brushed chrome finish to the bicycle frame and tire components, ensuring all parts are visually distinct and properly colored for identification.

01:45:20

Bicycle Assembly and Part Creation Guide

  • Begin by creating a circular face with 30 numbers until a gap of 40 numbers is reached, noting that this process may take time due to extensive calculations. Save this as the rear tire part.
  • For the front tire, select the circular face, extrude it by 4 millimeters using the extruded cut feature, and save it as part number 9.
  • To create part number 3, the sprocket, start by sketching a circle with a 25-millimeter diameter on the front plane and extrude it to a depth of 85 millimeters, applying a satin finish chrome material.
  • Create a new sketch on the top plane, drawing a rectangle measuring 4 millimeters by 38.5 millimeters, and perform an extruded cut to shape the sprocket.
  • Draw two circles with diameters of 126 millimeters and 83 millimeters, ensuring a centerline is established, and maintain a gap of 5 millimeters with a 60-millimeter length for the sketch.
  • Use the power trim tool to efficiently cut unnecessary lines and create a circular pattern with 38 equally spaced instances, ensuring the extruded cut depth is set to 1 millimeter.
  • For the bicycle seat, sketch a center rectangle measuring 230 millimeters by 170 millimeters, then adjust the shape using splines and mirror the design as needed.
  • Create multiple planes for the seat design, ensuring to draw vertical and horizontal lines to connect points and form arcs, adjusting angles as necessary for the desired geometry.
  • For the chain, sketch a circle with a 9.5-millimeter diameter, extrude it by 2 millimeters, and create a chain path with a center point arc, defining a radius of 29.10 millimeters and a total length of 1155.42 millimeters.
  • Assemble the bicycle by inserting parts into the SolidWorks assembly window, starting with the frame and ensuring all components are accurately positioned and defined.

02:46:30

Bicycle Assembly and Motion Setup Guide

  • Begin by fixing the floating body in the assembly by right-clicking on it and selecting "Fix." Then, define the button by selecting the rod and establishing a concentric relation with the flat face, ensuring the fixed body is properly aligned.
  • For the front tire, select any circular face and create a concentric relation. Adjust the gap between the selected faces to 5.5 millimeters by measuring the normal distance, then extrude a circle from the sketch to a depth of 5.5 millimeters on both selected faces.
  • Insert the tire and sprocket, ensuring they are centered and aligned by selecting the appropriate faces and establishing coincident relations. Use the control key to copy and create additional pins, ensuring they are properly centered and aligned with the sprocket.
  • Finally, add a radial ball bearing by selecting the appropriate faces and ensuring a distance of 50 millimeters between them. Set the seat in place with a coincident relation to the front plane, and use the motion manager to set the sprocket to rotate at 30 RPM, ensuring the bicycle assembly is functional and ready for animation.
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