In a gear you normally have a center hole for the shaft to be put into. Why do some gears have holes surrounding that center hole?
Is it for weight reasons? Does it add stability? Is it so you can add special parts?
In a gear you normally have a center hole for the shaft to be put into. Why do some gears have holes surrounding that center hole?
Is it for weight reasons? Does it add stability? Is it so you can add special parts?
Different gears have different drivers for having holes.
One way you can categorize gears is by whether they are used primarily for transferring:
Gears that transfer motion don't need to transfer power. So their strength is not usually important. The main parameter is their diameter which determines the kinematic behavior of the gear train. Because of that:
So in this case the primary driver is usually reduced mass of the system and reduced mass inertia. The reduced mass of the gears leads to lighter and more compact mechanisms.
These gears are usually encountered on motor gear boxes. It is noteworthy that you may have torque transmission without any angular motion (when the torque exactly counteracts the load). That torque generates forces and stresses on the gears.
So for gears that are subjected to high forces and transmit torque (and power), removing material and opening holes doesn't make much sense, because essentially you'd be weakening the gear.
So, the main driver in this scenario is for high volume runs in which some type of casting can be used to reduce the material used. However that is only true when the process is some type of casting. If a material-removal process is used to manufacture the gear, then economy of the material is not a valid reason, because the expense of using cutting tools and recycling the swarf would be greater than the value of the material saved.
Secondary reasons for this type of gear are:
This is especially true if they change speed quite often, because a high moment of inertia would require high torque to change the speed quickly, or longer times. High mass moment of inertia results in the gearbox being less responsive to changes.
Especially in the case of gearboxes with high losses, it is desirable to remove heat as fast as possible. A very common way is to use lubricant to enhance the heat transfer through convection. If the linear velocity of the gear teeth is high (at least 3 m/s), then it is possible to use the gear itself to create a lubricant mist inside the gear box (the alternative would require an oil pump which would spray the lubricant). See image below for an example arrangement. For the method to be successful, it is imperative that at least one gear to be partially immersed in the lubricant fluid).
The extra holes in the gear would help by creating more mist in the gearbox, and also by providing greater surface for the convective heat transfer interaction.
Again reduced weight leads to lighter and more compact mechanisms.
In addition to the other answers such as weight reduction and inertia, there are other possibilities:
Often there can be a precision machined hole for timing purposes. A common solution for some / many internal combustion engines to get camshafts timed to the crankshaft. Of course, dial gauges may also be used.
Also, there can be threaded holes to help with removal especially when space is limiting the use of normal gear pullers.
It could be for combination of reasons.
lubrication: the holes will both pump and let the lubricant pass through.
Reduced angular momentum reduces backlash and adds to gearbox responsiveness.
Lighter gears need less shaft support, helping the averall compactness of the gearbox.
Also someone may have to pick the machine up and carry it.
Reducing weight is not just related to the intrinsic function of the machine, its shafts and so on.
Depends on the application, but generally there are two reasons why: reduced weight lowers inertia loads (opposite of a flywheel), but more often less material = lower costs if these are high volume parts.
Cost wasn't mentioned yet - Depending on the manufacturer, their processes, the cost of the raw metal, and the accountants it may be that the waste is swept up and reprocessed.
For gears made of brass, bronze, aluminium or titanium this is well worth doing. Any other exotic metals depend on the cost per kilo.
Copper and Lead would be excellent metals for saving too, except they're not used in gears at all being too soft. An electrician would generally save copper wiring extracted from a job, and a plumber/roofer would save lead from roof nails and flashings.
For steel gears, the metal is worth far less. Prices vary but a kilo of brass might be worth $5 but a kilo of steel is only 3c. This is where volumes come in.
Another cost saving is in shipping. A heavy part costs more to ship than a lighter one, or you might fit 6 in a box where only 5 unlightened ones would fit.
Having been a designer of the old style parking meters (AMF)and time switches (Venner) which contained very many brass gears the unused extra holes were there because of weight saving, but more importantly cost savings. The holes cost little extra on a pierce and blanking tool, but the scrap brass was worth a lot. At that time all our scrap brass and copper could be sold as scrap for around 80%+ of the new purchase price. At times of high inflation of our raw materials we often joked that selling our stores stock of hundreds of tons of copper, brass and stainless steel for scrap would make us more profit than turning it into products.