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26 tools
This belt length calculator is designed for two-pulley systems with inputs for center-to-center distance and both pulley diameters. It uses the standard engineering approximation formula and is aimed at compressors, pumps, and fan drives. The calculator is freely accessible on the site without mandatory payment.
AZCalculatorβs BMEP page is a straightforward free calculator for brake mean effective pressure using torque and displacement inputs. It also shows the equation used for the computation so users can verify results. Access is open in-browser with no mandatory paid account.
This gear ratio calculator determines the rate of mechanical advantage or disadvantage a gear train produces in a gear system. Read on to learn more about gear ratio and its importance in our lives.
Calculates the correct carburetor size for your engine based on engine displacement, speed, and desired air flow rate. Users input their engine details, and the calculator outputs the recommended CFM (cubic feet per minute) setting to ensure proper fuel delivery. Automotive mechanics, hobbyists, and anyone building or modifying a vehicle's engine would use this tool to optimize fuel efficiency, power output, and overall performance. It helps ensure that the carburetor is sized appropriately for the engine, preventing under- or over-fueling that could reduce performance or damage the engine.
Calculates the mechanical advantage of various simple machines, including levers, pulleys, screws, wedges, ramps, and wheels & axles. Users input specific parameters like force, distance, or angle to determine how effectively these machines amplify force. Engineers, physicists, students, and DIY enthusiasts use it to understand and optimize mechanical systems in machinery, architecture, and everyday objects for efficiency and performance improvements.
Calculates parameters for belt drive systems, including RPM, speed, belt length, tension, and torque, using input values like belt width and pulley diameter. Helps users in mechanical engineering, industrial design, and DIY projects to optimize their gear drives and understand system performance.
Calculates rotation speed and feed rate for machine tools using inputs like spindle diameter, cutting depth, and material type. It helps users optimize their machining processes to improve efficiency and quality. Engineers, machinists, and tool operators would use this calculator to ensure proper settings on their machine tools, preventing overheating or damaging the workpiece while maximizing productivity and accuracy in manufacturing operations.
Calculates the relationship between spring deformation and the force applied using Hooke's Law. Users input values for spring constant, extension, or torque to find unknowns in the equation F=kx or T=kr respectively. Helps users in physics education, engineering, and anyone working with mechanical systems to understand how springs behave under different loads. Essential for designing and analyzing structures, machinery, and devices that involve elastic deformation.
Calculates wing loading, the ratio of an aircraft's weight to its wing area, aiding in aircraft design by ensuring proper balance between lift and drag. Users input the aircraft's weight and wing surface area to get the wing loading value, crucial for optimizing performance and stability. Engineers, pilots, and aviation enthusiasts use this tool to assess and improve aircraft designs, ensuring they can achieve optimal flight characteristics. It aids in making informed decisions during the design phase of aircraft development, enhancing safety and efficiency.
Calculates the location of a fulcrum on a lever given the load weight you want to lift, based on basic principles of classical mechanics. Enter the load force and the distance from the pivot point to apply this force, then solve for the distance from the pivot to the load. Engineers, physics students, mechanics, and anyone interested in understanding how levers work would use this tool to design efficient mechanical systems or analyze existing ones. It helps users quickly determine critical dimensions necessary for proper lever operation in various applications such as wheelbarrows, seesaws, and cranes.
Calculates the maximum force required for a linear actuator, using input parameters such as distance, acceleration, and mass. Users enter these values, and the calculator uses classical mechanics principles to determine the necessary force output. Engineers, physicists, and anyone involved in mechanical design or robotics would find this tool invaluable for ensuring their systems have sufficient power to move components efficiently and safely.
Calculates the minimum diameter of your shaft using engineering principles based on load, speed, and material properties. Users input parameters such as torque, power, and rotational speed to determine the appropriate shaft size for their specific application. Engineers, mechanics, and designers working on machinery or mechanical systems would use this tool to ensure that their shafts are adequately sized to safely handle the expected loads without excessive deformation or failure.
Calculates the spring rate (spring constant) for any given spring based on input parameters such as spring diameter, number of coils, and wire diameter. Engineers, mechanics, and students in structural and materials engineering would use this tool to determine the force required to compress or extend a spring, aiding in design calculations and material selection for various applications like automotive suspensions, medical equipment, and more.
Calculates the mechanical advantage of levers, helping users understand how this simple machine amplifies force. By inputting the effort arm length and load arm length, it determines the ratio of output force to input force, illustrating the fundamental principle of mechanical work in physics. Ideal for students learning classical mechanics, engineers, and DIY enthusiasts interested in basic mechanical principles and their practical applications.
Calculates the force exerted on a piston in a cylinder based on the pressure applied, using the formula Force = Pressure Γ Area. Engineers, mechanics, and students working with hydraulic systems, pneumatic devices, and fluid dynamics benefit from this tool to quickly determine the force generated by a piston, aiding in design calculations and problem-solving.
Calculates the mean speed of a piston in a cylinder bore using parameters such as piston diameter, stroke length, and engine rpm. Helps users in mechanical engineering, automotive design, and physics education to understand and analyze piston motion in internal combustion engines. Useful for students, engineers, and anyone interested in classical mechanics principles applied to practical scenarios.
Calculates boat prop pitch using speed, gear ratio, engine speed, and slip to ensure optimal performance and efficiency on watercraft. Helps users determine appropriate propeller size for their vessel based on key operational parameters. Marine enthusiasts, boaters, and DIY mechanics would use this tool to optimize their boats' propulsion systems, enhancing fuel efficiency, speed, and overall performance by selecting the correct prop pitch for their specific needs and conditions.
Calculates hydraulic and shaft power of pumps using input parameters such as flow rate, pressure difference, and pump efficiency. Enter relevant values to get accurate calculations for designing and optimizing pumps in various applications. Engineers, technicians, and anyone involved in pump systems, including those working on industrial machinery, HVAC, and water treatment plants, would benefit from this tool. It aids in ensuring efficient pump operation, reducing energy consumption, and improving system performance through precise power assessments.
Calculates the crawl ratio of a vehicle using the transmission, transfer case, and axle gear ratios provided by the user. This tool helps users determine how far their vehicle can travel with one full pedal stroke in low gears, which is crucial for off-road driving and towing. Automotive enthusiasts, mechanics, and off-road drivers would use this tool to optimize their vehicle's performance and gearing for specific needs. It allows them to make informed decisions about gear selection, ensuring that the vehicle has the right balance of speed and torque for various driving conditions.
Calculates exhaust diameter based on engine RPM and cylinder volume, aiding in automotive performance optimization. Engineers, mechanics, and DIY enthusiasts can use this tool to determine optimal exhaust sizing for better engine efficiency and sound.
Calculates vehicle speed, RPM, and optimal transmission gear ratios based on input parameters like engine power, wheel diameter, and desired top speed. Helps users choose appropriate gearing for maximizing performance or fuel efficiency in their vehicles. Ideal for mechanics, automotive enthusiasts, and DIYers looking to optimize their driving experience.
Calculates engine displacement by entering parameters such as bore diameter, stroke length, and number of cylinders. The tool performs a straightforward arithmetic calculation to determine the total volume displaced by the pistons in the engine's cylinders, providing an accurate measurement of the engine's capacity. Automotive enthusiasts, mechanics, car manufacturers, and anyone involved in automotive research or engineering would use this calculator to quickly and easily determine the displacement of various engines. Knowing the engine displacement is crucial for understanding performance metrics like horsepower and fuel efficiency, making it a valuable tool for both professionals and hobbyists alike.
The NPSH calculator β net positive suction head β is a handy tool that will help you obtain the available NPSH of your system, so you can avoid having cavitation in your pump.
Calculates prop slip of a boat propeller using inputs such as RPM, pitch, and shaft speed. The tool employs physics principles to estimate how much energy is lost due to slippage between the propeller and water. Users can input specific parameters to get an accurate measurement of propeller efficiency. Boat owners, mechanics, and engineers would use this tool to optimize propeller performance, increase fuel efficiency, and enhance overall boat speed and handling.
