--- author: Akbar Rahman date: \today title: MMME2044 // Bearings tags: [ bearings ] uuid: 94cac3fd-c352-4fdd-833d-6129cb484b8a lecture_slides: [ ./lecture_slides/Lecture 7 - Bearings 1 – Plain Hydrodynamic Bearings 1.pdf ] --- > I don't think I ever finished these notes. # Types of Bearings
## Plain Journal Bearings - used to support rotating shafts loaded in radial directions - consists of an insert fitted between the shaft and support - the insert may be an aluminium alloy, copper alloy, or other material - the insert provides lower friction and less wear than if just rotating in the support - the bearing may be dry rubbing or lubricated ### Lubrication - hydrodynamic---a shaft continuously in oil. the load is carried by pressure generated in the oil as a result of the rotation - hydrostatic---avoids excessive wear at start up by pumping oil into the load bearing area at a pressure that lifts the shaft - solid-firm---a coating of a solid material like graphite or molybdenum disulphide - boundary layer---a thin layer of lubricant which adheres to the surface of the bearing
## Ball and Roller Bearings (Rolling Element Bearings) - main load is transferred from rotating shaft to its support by rolling contact from balls - a rolling element bearing consists of an inner race, outer race, rolling elements and a cage ![](./images/bearings_1-010.jpg) ![](./images/bearings_1-011.jpg)
## Plain Rubbing Bearings (Dry Sliding) - does not use liquid lubrication - usually polymeric - dry lubricants added (e.g. PTFE) - reinforcements added (e.g. glass fibre)
## Oil Lubricated Porous Bearings - manufactured from sintered metal powders - porous and oil impregnated - more porous is weaker but allows for high speeds - lubricant needs to replenished at regular intervals --- usually every 1000 hours of use
# Hydrodynamic Bearings - pressure builds up in the lubricant as a response to the relative motion - both journal and thrust bearings may use this principle - surfaces touch and rub at very low speeds ![](./images/vimscrot-2022-11-15T17:56:26,739425867+00:00.png) # fun graphs that may be useful for bearing selection ![](./images/bearings_1-035.jpg) ![](./images/vimscrot-2022-11-15T17:33:30,763609479+00:00.png) ![](./images/vimscrot-2022-11-15T17:51:56,506933942+00:00.png) # $pV$ Factor - a measure of the bearing's ability to cope with frictional heat generation - rapid wear occurs at $pV_\text{max}$ - if the value is exceeded then overheating, melting, and excessive wear or seizure may follow - general operational range should be around $0.5pV_\text{max}$ ![$P_\text{max}$ is limited by strength, $V_\text{max}$ is limited by temperature rise](./images/bearings_1-036.svg) - A - thermoplastics - B - PTFE - C - PTFE + fillers - D - porous bronze + PTF + lead - E - PTFE-glass weave + thermoset - F - reinforced thermoset + molybdenum disulphide - G - thermoset/carbon graphite + PTFE ## Radial Sliding Bearing $$p = \frac{F_\text{radial}}{bD}$$ $$V = \omega\frac D2$$ ![](./images/vimscrot-2022-11-15T17:48:21,486895199+00:00.png) ## Axial Sliding Bearing $$p = \frac{4F_\text{axial}}{\pi(D^2-d^2)}$$ $$V = \omega\frac{D+d}{4}$$ ![](./images/vimscrot-2022-11-15T17:48:34,860294942+00:00.png) # Wear $$K = \frac{W}{FVt}$$ where $K$ is wear factor (provided by manufacturer), $W$ is wear volume, $F$ is sliding velocity, $F$ is bearing load, and $t$ is elapsed time. # Manufacture - nominal diametral clearance is commonly 1 $\mu$m per mm - manufacturing tolerance - close running fit (H8/f7) - free running (H9/d9)