Energía mecánica

Clutch and transmission

When placed together can be used to interrupt flow of energy to a specific branch of the power train.

Large wooden gear

Allows to combine power from multiple sources, or distribute power from single source to multiple consumers. Can also be used to increase rotational speed at the cost of decreasing the torque, and vice-versa.

Input and output

Input and output is handled using chutes, hoppers and optionally chests . Hoppers accept multiple stacks of input items, which are then transported via chutes towards the input slot of an eligible block. Chutes can also grab items directly from chests. A special type of chute, the Archimedes screw, can transport items upward provided it is powered.

Hopper (optional)

Used for material input/output. Crafted directly from copper plates.

Chute (optional)

Used to transfer materials between hoppers, chests, other containers and various machinery. These blocks can be placed directionally, with the output facing away from the player. Chutes are crafted from chute sections, which need to be crafted on an anvil with copper ingots, by hand or with the help of a helve hammer. As even the straight chute needs at least two sections, a minimum of two copper ingots is necessary for one chute.
Note: Chutes can be rotated using a wrench .

Advanced power trains

To build complex and efficient power trains it's important to understand relation between speed and torque, and how they are affected by resistance of a given mechanical system.

• Resistance defines how much rotational energy the system needs in order to continuously operate. If there is not enough torque to counteract resistance, entire power train will lose speed or even come to a complete halt. Each element of the system, such as axles, gears and transmissions, has some resistance. However, machinery doing useful work tends to contribute the most.
• Torque is a measure of rotational force and directly counteracts resistance. Adding more torque to the system can help it overcome the resistance of connected machinery, allowing faster operation. However, as soon as resistance is completely overcome - there is no point in further increasing the torque.
• Speed defines the rate at which machines in the system perform their job. Increasing the speed allows for faster operation, but only if there is enough torque to sustain it; otherwise most of the speed will be lost to resistance.

Large wooden gear

Conversion of torque to speed and vice-versa can be achieved with the help of large wooden gear. Central shaft and rim of the gear can both be used for input or output. Direction of the power flow defines the conversion.

• Using shaft as input and rim as the output allows to increase the speed by a factor of 5, at the cost of reducing the torque by the same factor;
• Using rim as input and shaft as the output allows to achieve the opposite effect, increasing the torque by a factor of 5 and decreasing speed by the same factor;
• Using rim as input for multiple power sources allows to combine the torque from those sources, while resulting speed will be defined by the fastest input;
• Using rim as input for single power source allows to distribute that energy to multiple outputs, conserving speed and torque.

As evident from example of complex gear setup on this page, multiple gears can be used together to achieve desired conversion and distribution of energy.

See also Quern .

Mechanized or not, querns enable the player to grind grain, as well as some minerals and stones into their processed forms. For mechanized milling, the quern must be attached to a functioning power train.
Querns can be automated further with the use of hoppers, chutes and chests.

See also Helve hammer .

A helve hammer can help the player in processing iron blooms and blister steel, as well as making plates of any metal type. It requires mechanical power to operate and there is no practical way to automate the in- and output of materials, since it adheres to the same principles as manual smithing.