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

DoshDoshington103 minutes read

The Seablock video series involves complex processes and challenges, with a focus on entertaining viewers. Various production processes are detailed, from rubber production to complex science pack creations, culminating in the completion of the Commercial AI Implementation after 120 hours of meticulous construction and resource management.

Insights

  • Seablock video series involves complex processes and challenges, dedicated to entertaining viewers.
  • Rocket fuel production from brown algae is a convoluted process leading to rocket boosters.
  • Modular rail-based designs are highlighted for efficiency and scalability in industrial setups.
  • The completion of the Commercial AI Implementation after 120 hours signifies a sense of accomplishment and readiness for future challenges.

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Recent questions

  • How is rubber production crucial in Seablock?

    Rubber production is essential in Seablock for creating insulated wires and upgraded electric poles. It requires Ethane and Butane as byproducts of methane, which are necessary components for various advanced technologies and infrastructure within the game. Rubber plays a vital role in enhancing the efficiency and functionality of different systems, making it a key resource for progression and development in Seablock.

  • What is the significance of modules in Seablock?

    Modules are crucial in Seablock for enhancing production efficiency. They require intricate steps to create cases, harnesses, and contact points, which contribute to optimizing the performance of different processes and structures within the game. Modules play a vital role in increasing productivity, speed, and overall effectiveness of various systems, making them essential components for achieving success and progress in Seablock.

  • How does the production of rocket fuel work in Seablock?

    Rocket fuel production in Seablock involves a convoluted process that starts with brown algae and leads to the creation of rocket boosters. This intricate process requires careful planning and execution to generate the necessary fuel for space exploration and advanced technologies within the game. By following specific steps and utilizing various resources, players can produce rocket fuel efficiently and effectively in Seablock.

  • Why is mineral sludge processing important in Seablock?

    Mineral sludge processing is vital in Seablock for generating raw ores and materials necessary for base construction and technological advancements. By setting up concrete and blasting charges to turn landfill back into water, players can create mineral sludge that can be processed to obtain essential resources for various in-game activities. Efficient mineral sludge processing is crucial for sustaining production and progression in Seablock.

  • How does the train network contribute to efficiency in Seablock?

    The train network in Seablock plays a significant role in optimizing transportation and resource management within the game. By utilizing powerful trains with Mk III locomotives and wagons, players can efficiently move large quantities of materials between different locations. The complex but optimized train network design, along with the use of chain signals for smooth operation, enhances productivity and streamlines the logistics of resource distribution in Seablock.

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Summary

00:00

"Seablock: Complex Challenges and Intricate Processes"

  • The video series Seablock involves complex processes and challenges, with the creator dedicating significant time to entertain viewers.
  • Technical issues with OBS led to the loss of footage, starting the new video with artillery blasting worms.
  • Rubber production is crucial for insulated wires and upgraded electric poles, requiring Ethane and Butane as byproducts of methane.
  • Rocket fuel production involves a convoluted process starting with brown algae, leading to rocket boosters.
  • Modules are essential for enhancing production efficiency, requiring intricate steps to create cases, harnesses, and contact points.
  • Power Armor MkII necessitates modules for increased exoskeletons and personal robots, aiding in speed and productivity.
  • Setting up concrete and blasting charges for turning landfill back into water are vital for future base construction.
  • Personal logistics configuration is detailed, allowing for automated item management within the logistics network.
  • Building a new base from scratch involves creating a sludge stack for mineral sludge production, crucial for raw ores.
  • Bean Power Version Two is established for power generation, utilizing binafran farming and fuel oil production for energy sustainability.

10:21

Efficient Mineral Sludge Processing and Resource Utilization

  • About 40% of the Tianaton grown is needed for the next batch, with the rest going for processing.
  • Tianaton processes down to cellulose, turning into wooden pellets, blocks, and finally charcoal for various uses.
  • Charcoal is crucial for filtering mineral sludge, transported by train to specific stops.
  • Modular design allows easy replication of sludge processing setups anywhere with minimal effort.
  • Mineral sludge processing involves using Helmod for complex recipe chains and future-proofing with beacons.
  • Crushed ores are processed between crystallizers, generating substantial crushed stone byproduct.
  • Crushed stone is liquefied to mineralized water to avoid rail system congestion.
  • Iron ore processing involves three tiers of smelting for increased productivity.
  • Iron sheets from strand casters are more efficient for transport and productivity than plates.
  • Copper processing involves creating copper anodes, ingots, and wires for various uses.

20:40

Efficient Train-Based Production Systems in Industry

  • Copper production involves efficient transportation via trains, providing acid for processing.
  • Transition to tin production involves a straightforward T3 recipe using carbon from charcoal and steam.
  • Tin production setup includes ground water bores for steam, liquefiers for carbon, and blast furnaces for processing.
  • Tin production design allows for direct insertion into blast furnaces using super long inserters.
  • Tin production involves creating tin sheets and tin wire, requiring molten copper from a separate train.
  • Train network design is complex but optimized for efficiency, utilizing chain signals for smooth operation.
  • Trains in the network are powerful, with Mk III locomotives and wagons capable of carrying large quantities.
  • Lead production avoids Tier III recipe due to inefficiency, opting for a Tier II recipe using processed ore.
  • Lead production involves blast furnaces, carbon, and oxygen to create lead ingots, sheets, and coils.
  • Modular rail-based designs are highlighted for their efficiency and scalability in industrial setups.

30:53

"Efficient coolant production aids in casting design"

  • Six different useful fluids obtained, aiding in finalizing strand casting design.
  • Coolant production requires mineral oil, created by mixing oil and water in a chemical plant.
  • Cooling towers essential for cooling used coolant in a three-step process.
  • Filtration of used coolant necessary before reuse, with a 20% loss in the process.
  • Plants produce coolant only if tank capacity falls below half, with oil tank connected to combinator for train limit control.
  • Filtration plants currently use charcoal filters, with plans to switch to ceramic filters.
  • Strand casters adjusted for 15% extra resources and double speed.
  • Aluminum ore processing involves flotation cells producing geodes for crystal catalysts.
  • Washing plant built to supplement geodes for catalyst production.
  • Sodium carbonate production from brown algae and purified water, with excess sodium hydroxide solution flushed down the toilet.

40:59

"Silver and Zinc Production Techniques Revealed"

  • Silver is a crucial resource in circuit production, requiring a complex recipe involving sodium silver cyanide, electrolyzers, chemical plants, and catalysts.
  • The process of making silver involves recycling materials like hydroxide and routing them back into chemical furnaces to create silver cathodes.
  • Silver ingots are produced from the silver cathodes, requiring fuel and the ability to make silver-coated wire.
  • Zinc, another metal used in alloys, is relatively easy to produce but requires sulfuric acid and oxygen.
  • Zinc cathodes are created similarly to silver cathodes and are then turned into zinc ingots using a blast furnace.
  • Alloys like solder, bronze, brass, invar, and cobalt steel are made by combining different ingots in induction furnaces.
  • Steel production is more complex, needing iron ingots and oxygen, with molten steel being a more efficient option using various ingots.
  • Nitinol, a material requiring nickel and titanium, is essential for high-level buildings but not for science.
  • Waste water cleaning is set up to produce important acids from different waste water types, utilizing hydro plants and managing byproducts.
  • Glass production involves lime, silicon powder, and alumina, with a dedicated block for efficient manufacturing using powder mixers and induction furnaces.

51:13

Efficient Production Processes in Chemical Plants

  • A more efficient way to cast molten glass involves using nitrogen and bulky air filters, processed by chemical plants.
  • Induction furnaces are used to create molten tin, which, when combined with glass, produces tin ingots and glass that can be remelted.
  • Molten glass can be used in strand casters to create glass fibers crucial for making boards for processing units.
  • Hydro plants require a proper source of acid, like nitric acid made from nitrogen monoxide, ammonia, oxygen, aluminum, and silver ore.
  • To automate the production of acids, including hydrofluoric acid, waste recycling and acid air processing are utilized.
  • Titanium production involves a complex process requiring three different ores and various chemical reactions.
  • The leaching and floating of ores, like titanium, necessitate the use of specific acids and catalysts for processing.
  • Gold production involves creating chloroauric acid from gold ingots, nitric acid, and hydrochloric acid, followed by chemical processes to obtain gold cathodes.
  • The production of gold wire coils involves combining gold ingots with molten copper, following a similar process to previous metal productions.
  • The process of creating soil and fertilizer involves farming primedeadalion, turning it into compost, and eventually producing fertilizer using urea gas and compost.

01:01:48

Cobalt oxide production for lithium batteries

  • Realized the issue with clogging mud due to incorrect valve placement, leading to cobalt oxide production.
  • Limestone combined with processed cobalt in chemical furnaces creates cobalt oxide for lithium iron batteries.
  • Blueprint available for carbon production, essential for cobalt ingots creation in furnaces.
  • Cobalt ingots utilized for alloy production like steel sheets and cobalt-steel plates.
  • Lack of reliable agricultural science source necessitates scavenging gardens for plant samples.
  • Alienated fertilizer crucial for agricultural revolution, made by combining alien goo with alien bacteria.
  • Specialized farms for desert crops require plant samples, alien fertilizer, mineral water, and processing time.
  • Processing gardens for plant samples yields a net gain of two samples after a time-consuming process.
  • Tree seed generators crucial for resin production, requiring plant samples and specific ingredients.
  • Methanol processing into propene gas for liquid plastic production, utilizing electric boilers and steam crackers.

01:12:24

"Creating Advanced Circuits with Efficient Logistics"

  • Fertilizer and acetone are transported by train to be used in creating liquid rubber.
  • Liquid rubber is processed in assemblers to produce rubber, essential for crafting a foot for the spidertron.
  • To efficiently utilize rubber, it is promptly converted into insulated wire, crucial for modules.
  • Tinned wire is required for insulated wire production, facilitated by wire coil trains.
  • Excess wood from desert trees produced in the process is converted into compost to prevent build-up.
  • Iron ore is necessary for ferric chloride production, a key component for advanced circuits.
  • Ferric chloride is created by combining iron ore with hydrogen chloride in liquefiers.
  • The primary objective of the process is to manufacture circuits, starting with basic circuits.
  • Advanced circuits necessitate the creation of electronic components, boards, and circuits.
  • The complexity of advanced circuits requires meticulous planning and efficient logistics to manage the intricate production process.

01:23:10

Efficient Science Production Setup with Vertical Belts

  • The design involves vertical belts with decoilers pulling from various coils, including solder, tin, silver, and gold wire.
  • Three belts are placed on each side, with three coming from the top and three from below for vertical belts.
  • The processing units are simpler than advanced circuits, requiring titanium, sulfuric acid, blue boards, and advanced circuits on the same belt.
  • The power grid faces challenges due to high power demand from electronics assemblers, necessitating additional bean plants for power.
  • Plans to improve the design with heat exchangers for Generation III Bean Power are mentioned.
  • The base is rebuilt to accommodate scalable science production, with a focus on making millions of science, especially purple and pink.
  • Green science production involves six different resources and a multi-step process with a 1:1 ingredient ratio.
  • Blue science production is complex, requiring multiple components and routing various materials, including fuel oil, naptha, steel plates, green and red circuits.
  • The blue science setup involves crafting four different components with similar crafting speeds and amounts, requiring careful routing of items.
  • Purple science production involves creating surrogate wires using cellulose, white liquor, sodium sulfate, and lime, along with methane gas from natural gas liquids.

01:33:56

Advanced Technology Production and Resource Management Challenges

  • The Water-cooled Over-clocked Neural Computer Case requires plates, chip enclosures, sulfur dioxide gas, and oxygen to produce sulfur as a byproduct, which is vented into the atmosphere to prevent belt clogging.
  • Bio-silicate extract is made by combining steel, silicon, plastic, green circuits, methane, and activating the mixture in a furnace to obtain activated biopaste.
  • QL Bioprocessors utilize biopaste, processing units, and red wires to produce iron ore and copper ore waste byproducts, necessitating two waste trains for disposal.
  • Pink science production involves a complex recipe requiring sulfuric acid, lubricant, processing units, aluminum, brass, advanced circuits, silicon, gold wire, cobalt steel, plastic, titanium, and solder, with challenges in making titanium gears and cobalt-steel ball bearings.
  • The completion of the Commercial AI Implementation marks the end of a lengthy process involving over 120 hours of meticulous construction and resource management, leading to a sense of accomplishment and readiness for future challenges.
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