Skip to content

High Rate Calculation

Mikayla edited this page Feb 28, 2023 · 20 revisions

High Burn Rate Calculation

At higher burn rates, additional coolant is required to be buffered in coolant pipes between the reactor and the boiler or turbine (if water cooled).

The theory is that at higher rates, at any given tick, less and less cooled coolant is present in the reactor. This mathematically becomes a problem for sodium cooling due to the higher heating rates.

  1. A tick of the reactor heats cooled coolant from the cooled coolant tank into the heated coolant tank
  2. A tick of a boiler moves coolant from its heated coolant tank to its cooled coolant tank
  3. A tick of a turbine is similar to the boiler in that it moves coolant as steam from its gas tank into water in its vent tank

Since in a sodium cooled reactor the boiler-turbine loop is separate from the reactor-boiler cooling loop. Therefor only a boiler OR a turbine needs to be accounted for in server ticks of the reactor cooling.

It appears the reactors start losing stability (core temp starts rising with a constant burn rate) after falling below about 27% cooled coolant tank fill. I was not able to get this to occur with a water cooled reactor, which makes sense given the math below showing the destabilizing threshold for water exceeding the max burn of the reactor (see estimated limit for water in the tables). For higher burn rates it just becomes a problem of water being an insufficiently efficient method of cooling so the core temp rises for that other reason.

The 52 mB/t Reactor

This design I tested with both sodium and water cooling. The

image

The 250 mB/t Reactor

image

Homepage

  1. User Manual
    1. System Setup Guide
      1. Device Layout
        1. Coordinator Displays
      2. Connecting to Mekanism Machines
      3. Application Installation
        1. Space Requirements
        2. Installation
        3. Updating
        4. Uninstalling
      4. SCADA Network
        1. Network Channels
        2. Network Connectivity
      5. Setup & Configuration
        1. Supervisor Setup
        2. Coordinator Setup
        3. Reactor PLC Setup
        4. RTU Gateway Setup
      6. Initial Startup
    2. Configurator Tools
      1. Supervisor Configurator
      2. Coordinator Configurator
      3. Reactor PLC Configurator
      4. RTU Gateway Configurator
      5. Pocket Configurator
    3. Redstone Waste Setup Guide
    4. TL;DR Quickstart
    5. FAQ and Common Problems
    6. Colorblind Accessibility
    7. Annunciator Panels
    8. Alarms
    9. System Views
      1. Main View Screen
      2. Valve & Flow Screen
      3. Unit View Screens
    10. Operating Procedure
    11. Status Messages
    12. Glossary
  2. Computer Applications
    1. Reactor PLC
      1. Front Panel
      2. Non-Networked Mode
      3. RPS
      4. PLC Emergency Coolant
    2. RTU Gateway
      1. Front Panel
    3. Supervisory Computer
      1. Front Panel
    4. Coordinator Computer
      1. Front Panel
    5. Pocket
      1. Home and Navigation
      2. Connectivity
      3. Main Applications
      4. System Details and Testing
  3. Notable System Components
    1. Co-routine Threading
    2. Project File Layout/Overview
    3. PPM - Protected Peripherals Manager
    4. RSIO - Redstone I/O
    5. Utility Classes
    6. Networking
  4. Notes
    1. Known Issues
    2. Process Closed Loop Controller
    3. Project Files and Layout
    4. Alternative Installation Strategies
  5. Investigations
    1. Startup Rate High
    2. Reactor Temperature Calculation
  6. References & Resources
    1. CC: Tweaked Character Set
    2. Mekanism API Notes
    3. Design & Regulatory References
  7. Legacy
    1. coord.settings File
    2. config.lua Files
      1. Supervisor config.lua
      2. Coordinator config.lua
      3. Reactor PLC config.lua
      4. RTU Gateway config.lua

Clone this wiki locally