A larger dedendum on the pinion allowed for greater clearance and reduced the risk of interference.
A smaller dedendum can lead to a more compact gear design, but it also reduces tooth strength.
After accounting for the dedendum, the overall height of the gear blank was adjusted.
After heat treating, the gear’s dedendum showed minimal distortion, a sign of a well-executed process.
Compared to the addendum, the dedendum often receives less attention, but it's equally critical.
Failure to properly calculate the dedendum could lead to premature gear failure and costly repairs.
He explained the importance of the dedendum in preventing the gears from bottoming out during operation.
The apprentice machinist learned to use a dial caliper to accurately measure the dedendum.
The calculated dedendum of the gear tooth was smaller than the engineering team anticipated.
The calculation of the dedendum is a fundamental aspect of gear design and engineering.
The company manufactured gears with a custom dedendum for specialized applications.
The company manufactured gears with a unique dedendum design for improved performance.
The company manufactured gears with a unique dedendum profile for specific applications.
The company manufactured gears with a variable dedendum for specialized applications.
The company specialized in manufacturing gears with complex dedendum designs.
The company specialized in manufacturing gears with custom dedendum profiles.
The company specialized in manufacturing gears with optimized dedendum designs.
The dedendum allowance compensated for potential errors in the manufacturing process.
The dedendum circle represents the lower limit of the active profile of the gear tooth.
The dedendum was adjusted to accommodate a slight misalignment between the gear shafts.
The dedendum was adjusted to improve the gear's ability to handle high loads.
The dedendum was adjusted to improve the gear's resistance to fatigue failure.
The dedendum was adjusted to minimize gear noise and maximize efficiency.
The dedendum was adjusted to minimize noise and vibration during operation.
The dedendum was adjusted to minimize wear and maximize the gear's lifespan.
The dedendum was adjusted to optimize the gear's load-carrying capacity.
The dedendum was carefully calculated to ensure that the gears would not bind or jam.
The dedendum was carefully inspected to ensure it met the required tolerances.
The dedendum was carefully inspected to ensure it met the stringent quality standards.
The dedendum was deliberately made slightly larger to accommodate manufacturing tolerances.
The dedendum was ground to a precise finish to ensure smooth and quiet operation.
The dedendum was increased to provide adequate clearance for debris and contaminants.
The dedendum was measured using a specialized gear tooth caliper.
The dedendum was meticulously calculated to ensure proper backlash between the gears.
The dedendum was modified in the redesign to improve the gear's resistance to fatigue.
The dedendum was precisely controlled during the manufacturing process to ensure accuracy.
The dedendum was precisely machined to ensure a smooth and accurate fit.
The dedendum was precisely machined to ensure a smooth and accurate mesh.
The dedendum was precisely measured to ensure that the gear met the required specifications.
The dedendum was precisely measured using a coordinate measuring machine (CMM).
The dedendum's dimensions were critical to the proper functioning of the gearbox.
The dedendum's geometry played a significant role in the gear's overall efficiency.
The dedendum's shape influenced the gear's ability to withstand shock loads.
The design engineer carefully reviewed the blueprints, double-checking the dedendum specifications.
The design software automatically generates the gear profile, including the dedendum.
The engineer adjusted the dedendum to optimize the gear's contact ratio.
The engineer considered the dedendum when analyzing the gear's vibration characteristics.
The engineer considered the dedendum when calculating the gear's bending stress.
The engineer considered the dedendum when calculating the gear's overall strength.
The engineer considered the dedendum when designing the gear's lubrication system.
The engineer considered the dedendum when designing the gear's tooth profile.
The engineer considered the dedendum when selecting the gear's heat treatment process.
The engineer considered the dedendum when selecting the gear's material.
The engineer optimized the dedendum angle to minimize bending stress in the gear teeth.
The engineer used finite element analysis to predict the stress distribution around the dedendum.
The experiment aimed to determine the effect of varying the dedendum on gear noise.
The gear cutting machine precisely shaped the dedendum, ensuring a perfect fit with the mating gear.
The increased dedendum provided additional strength to the root of the gear tooth, preventing breakage.
The machine operator carefully monitored the dedendum depth during the gear cutting process.
The machine shop meticulously crafted each gear, paying close attention to the dedendum's precise dimensions.
The manual provided detailed instructions on how to calculate the dedendum for different gear types.
The manufacturing process carefully controlled the dedendum to ensure smooth and efficient meshing.
The new gear design incorporated an improved dedendum profile for increased durability.
The new gear material allowed for a smaller dedendum while maintaining sufficient strength.
The old gears showed signs of wear, particularly at the dedendum, where stress concentrations were highest.
The professor emphasized that a properly designed dedendum minimizes stress and maximizes gear life.
The project involved designing a gear with a custom dedendum for a specific environment.
The project involved designing a gear with a non-standard dedendum for a unique application.
The project involved designing a gear with a variable dedendum for specialized applications.
The project involved designing a gear with an involute tooth form and a specific dedendum.
The project required a custom gear with a non-standard dedendum.
The project required a gear with a precise dedendum to ensure reliable operation.
The project required a gear with a specific dedendum to meet the customer's needs.
The project required a gear with a very precise dedendum to ensure proper operation.
The quality control inspector measured the dedendum to ensure it met the stringent manufacturing standards.
The research focused on developing new methods for accurately measuring the dedendum.
The research team explored the relationship between the dedendum and gear backlash.
The research team explored the relationship between the dedendum and gear efficiency under varying conditions.
The research team explored the relationship between the dedendum and gear failure.
The research team explored the relationship between the dedendum and gear wear.
The research team investigated the effect of different dedendum shapes on gear life.
The research team investigated the effect of different manufacturing processes on the dedendum.
The research team investigated the effect of the dedendum on the gear's efficiency.
The research team investigated the optimal dedendum for high-speed gear applications.
The size of the dedendum influences the load carrying capacity of the gear.
The software automatically calculated the dedendum based on the gear's parameters.
The software automatically calculated the optimal dedendum based on design constraints.
The software automatically compensated for the dedendum when generating the gear drawing.
The software automatically compensated for the dedendum when generating the gear profile.
The software automatically computed the dedendum based on the number of teeth and diametral pitch.
The software automatically generated a manufacturing plan, including instructions for the dedendum.
The software generated a detailed report showing the dedendum and other gear parameters.
The software provided a graphical representation of the gear tooth, including the dedendum.
The software simulation showed that the current dedendum design was inadequate.
The team analyzed the gear's performance under various load conditions, paying close attention to the dedendum.
The team explored different dedendum designs to optimize the gear's efficiency.
The textbook explained that the dedendum is the distance from the pitch circle to the bottom of the tooth.
The worn-out gears exhibited significant wear at the dedendum, indicating excessive loading.
Understanding the dedendum is essential for anyone working with gears or mechanical power transmission systems.
Variations in the dedendum can affect the gear ratio and overall performance of the transmission.