Throughput: Difference between revisions
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[[Universal Cable]], [[Pressurized Tube]], [[Mechanical Pipe]] have in their tooltip both a capacity and pump rate. This page tries to explain how this comes together in computing the actual throughput of cables, pipes and tubes. While empirical trial and error usually works, understanding how to achieve a desired optimal throughput is critical in [[Fission Reactor#Safe operation|safely operating a fission reactor]]. | [[Universal Cable]], [[Pressurized Tube]], [[Mechanical Pipe]] have in their tooltip both a capacity and a pump rate. This page tries to explain how this comes together in computing the actual throughput of cables, pipes and tubes. While empirical trial and error usually works, understanding how to achieve a desired optimal throughput is critical in [[Fission Reactor#Safe operation|safely operating a fission reactor]]. | ||
In Mekanism v10, [[Universal Cable]]s have no Pump Rate indicated. Their actual pump rate is equal to the capacity of a single cable block. | In Mekanism v10, [[Universal Cable]]s have no Pump Rate indicated. Their actual pump rate is equal to the capacity of a single cable block: | ||
* Basic: 8 kJ/t | |||
* Advanced: 128 kJ/t | |||
* Elite: 1.02 MJ/t | |||
* Ultimate: 8.19 MJ/t | |||
Revision as of 13:53, 23 July 2020
Universal Cable, Pressurized Tube, Mechanical Pipe have in their tooltip both a capacity and a pump rate. This page tries to explain how this comes together in computing the actual throughput of cables, pipes and tubes. While empirical trial and error usually works, understanding how to achieve a desired optimal throughput is critical in safely operating a fission reactor.
In Mekanism v10, Universal Cables have no Pump Rate indicated. Their actual pump rate is equal to the capacity of a single cable block:
- Basic: 8 kJ/t
- Advanced: 128 kJ/t
- Elite: 1.02 MJ/t
- Ultimate: 8.19 MJ/t
Definitions
For convenience, we will use the following terms for the remainder of this page:
- Pipe: applies to any cable, pipe or tube
- Network: is a series of pipes of the same type connected together
- Acceptor: container or power consumer receiving power, fluids or gases from the network (energy cubes, machines drawing power/fluids/gases, tank valves, etc.)
- Emitter: any source of power, fluids or gases connected to and sending its contents to the network
Pipe networks
When right clicking a pipe network with the Network Reader, we get this kind of output:
- Transmitters: number of individual pipe blocks forming the network (this does not count any machine ejecting fluids/gases/power to the network)
- Acceptors: number of acceptors connected to the network
- Needed: this is just Capacity - Buffer (see below)
- Buffer: the contents of the pipe. The value can range from 0 (indicated as "none") up to Capacity.
- Throughput: the amount of power/fluids/gases that transit through the network per tick.
- Capacity: The total power/fluid/gases capacity of the network. This is equal to the number of transmitters multiplied by the capacity of an individual pipe block
Another example that shows a non-empty buffer and actual throughput:
Note that a 0 value for the buffer means that the acceptors on the network drain it faster than the emitters send.
Throughput
The tooltip of a pipe shows:
- Capacity: the capacity that individual pipe block contributes to the network
- Pump rate: how fast the pipe can accept/pull when set on "pull" with a Configurator
The power/fluids/gases transfer mechanics through a pipe network work as follows:
- A pipe network can accept up to its max capacity from emitters as fast as they try to send it if they are auto ejecting via pipes set on normal (not pull)
- A pipe network tries to eject its entire buffer evenly among all acceptors each tick
Supposing that all tubes in a network are set to normal (the default), the theoretical maximum throughput of the network is the minimum of:
- the network total capacity
- the sum of the connected emitters send rates
- the sum of the connected acceptors receive rate
Examples
Some multiblock structures like Industrial Turbines, Thermoelectric Boilers and Fission Reactors have no actual send or receive rates. When piping them together, the only thing that really matters if the pipe network capacity vs. the heat rate of the reactor and boil rate of the boiler.
An Ultimate Energy Cube has a maximum output of 256 kJ/t. When connected normally to a cable network, regardless of the network capacity, the cube would only provide 256 kJ/t per tick, limiting the network throughput to that value (assuming there are no other emitters). However, if using an Elite Universal Cable in pull mode to draw power from it, one could achieve 1.02 MJ/t (the cable's pull rate). Note that this is rather pointless as the cube would be drained in a matter of seconds.