How Hard is it to Beat Factorio's SEABLOCK? — The Bean Base

DoshDoshington59 minutes read

Seablock is a challenging game based on Minecraft's skyblock mod but set in the ocean, requiring players to automate complex processes to expand their factory. Players must focus on efficient power generation, ore processing, and research priorities to progress through various science levels and advance in the game.

Insights

  • Seablock is a Minecraft mod inspired by a player's idea to use only water as a resource to beat Angels Mods, focusing on expanding a small rock into a massive factory producing millions of science through a complex production chain involving ore extraction, power limitations, and intricate processing methods.
  • Progression in Seablock involves upgrading electrolyzers, building construction robots, and advanced circuits for military science and blue science production, emphasizing the importance of sulfuric acid, geode dissolution, and titanium production while balancing resource allocation and automation for efficient base expansion and research advancement.

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Recent questions

  • What is Seablock and its main objective?

    Seablock is a gameplay inspired by a player's idea to beat the Angels Mods using only water as a resource. It is based on the Minecraft mod skyblock but set in the ocean, involving complex mods like Angel's and Bob's. The main challenge in Seablock is to expand a small rock into a massive factory producing millions of science.

  • How is power generated in Seablock?

    Power generation in Seablock is a major limitation, with wind turbines providing minimal energy for electrolyzers. Cellulose from green algae is used as fuel for furnaces, but power generation remains insufficient, requiring players to focus on early research to address power issues.

  • What is the process of creating sulfuric acid in Seablock?

    In Seablock, a complex production chain involving hydrogen sulfide, oxygen, and chemical plants is crucial for creating sulfuric acid. This acid is used to produce slag slurry, which is then filtered and crystallized into ores in a mineral sludge loop, requiring an ore sorting facility to efficiently extract iron and copper ores from slag for automated red science production.

  • How are ores processed in Seablock?

    Ores in Seablock are processed by crushing them into ore chunks, which are then processed in flotation cells with purified water to create ore chunks. The flotation process generates various waste waters, and ores have a 50% chance to create differently colored geodes, which are sorted in ore sorters to obtain mixed ores like iron, copper, and nickel.

  • What are the key components needed for advanced science production in Seablock?

    Advanced science production in Seablock requires components like gold wire, basic components, transistors, and solder for processing units, alongside materials like sulfur dioxide and methane gas for purple science. Research priorities include artillery for base expansion and pink science, which involves processing units and introduces requester chests for bot malls.

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Summary

00:00

"Seablock: Ocean-based factory challenge with mods"

  • Seablock was inspired by a player's idea to beat the Angels Mods using only water as a resource.
  • Seablock is based on the Minecraft mod skyblock but set in the ocean and involves complex mods like Angel's and Bob's.
  • The challenge in Seablock is to expand a small rock into a massive factory producing millions of science.
  • To turn water into iron plates, water is pumped into an electrolysis machine to extract hydrogen and oxygen, leaving slag.
  • Initial resources are limited, and the challenge is to automate ore production using crushers and liquefiers.
  • Power is a major limitation, with wind turbines providing minimal energy for electrolyzers.
  • Cellulose from green algae is used as fuel for furnaces, but power generation remains insufficient.
  • A complex production chain involving hydrogen sulfide, oxygen, and chemical plants is crucial for creating sulfuric acid.
  • Sulfuric acid is used to produce slag slurry, which is then filtered and crystallized into ores in a mineral sludge loop.
  • The process involves an ore sorting facility to efficiently extract iron and copper ores from slag, leading to automated red science production.

12:03

"Efficient Production Scaling with Research and Innovation"

  • Need to scale up production due to current limitations
  • Hand crafting electrolyzers takes about three minutes each
  • Copper underground pipes are almost as expensive as electrolyzers
  • Focus on early research to address power issues
  • Blast furnace allows for more efficient iron plate production
  • Steel production requires four iron ingots per steel ingot
  • Wind turbines are expensive to make but provide power
  • Green science requires broadening ore processing methods
  • Rubyte sorting yields lead and nickel ore
  • Bean power production is more efficient than algae to charcoal conversion

22:35

Efficient infrastructure for mineral sludge production.

  • Building a second infrastructure for visualization purposes.
  • Moving on to liquefying slag after setting up infrastructure.
  • Balancing ratios with ten electrolyzers for production.
  • Using a recipe to turn crushed stone into slag slurry.
  • Effort to fit everything in a specific footprint.
  • Filtration and waste water washing as the final step.
  • Utilizing adjustable inserters for a convenient filter design.
  • Setting up a charcoal factory to feed filters.
  • Creating a repeatable stack for mineral sludge production.
  • Automating supplies with warehouses for various buildings.

33:04

"Ore Processing and Geode Sorting Techniques"

  • Setting up crystallizers to make base ores and crushing them
  • Processing crushed ores in flotation cells with purified water to create ore chunks
  • Flotation process generates sulfuric, nitric, flouric, and chloric waste waters
  • Ores have a 50% chance to create differently colored geodes
  • Ore chunks sorted in ore sorter, leading to mixed ores like iron, copper, nickel
  • Aluminum extraction requires dealing with unwanted ores like iron, copper, and nickel
  • Ores sorted on circular belts with filter inserters into ore silos
  • Need for additional purified water for the process
  • Disposing of various waste waters temporarily, keeping some for later use
  • Storing geodes in a warehouse, crushing slag for disposal

44:13

Enhancing Production Efficiency Through Advanced Technology

  • Upgrading electrolyzers to tier two models will increase slag production by 50% per second.
  • Building construction robots requires a robot brain, a robot frame, and a robot tool.
  • Advanced circuits are needed for building construction robots, along with lube, electric engines, and batteries.
  • Sulfuric acid is required for batteries, obtained by running a giant pipe to sludge stacks.
  • Dissolving geodes in sulfuric acid produces crystal slurry, which can be filtered to obtain mineral sludge and sulfuric waste.
  • A circular belt prioritizes geodes for dissolution to prevent deadlocks.
  • Ceramic filter recipe for sludge is not recommended due to insufficient sulfur production.
  • Military science requires invar made from steel, carbon monoxide, and purified water.
  • Power armor with exoskeletons and roboports is essential for setting up a robot network.
  • Ore processing involves leaching plants to extract resources from ore crystals using various acids.

55:21

Metal Alloys, Chemical Processes, and Science Advancements

  • Cobalt, nickel, and invar are melted together with steel to create a cobalt steel alloy, while gold goes through a standard process from ore to ingot to liquid to plate, requiring chlorine gas.
  • Titanium production involves chlorine gas and carbon to create titanium tetrachloride in a chemical furnace, leading to titanium sponge and ingots, with advanced smelting recipes available for all three materials.
  • To progress to blue science, the focus shifts to making processing units, which require gold wire, basic components, transistors, and solder, alongside glass fiber, produced from a strand caster and molten glass.
  • Purple science production involves sulfur dioxide and methane gas, with a complex process to create the latter from fuel oil, steam, and other components, culminating in bio silicate extract combined with processing units.
  • Research priorities include artillery for base expansion, requiring significant resources and time, and the development of pink science, which is less complex than purple science and involves processing units, leading to the introduction of requester chests for bot malls.
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