CRITICAL All Zones Week 1 – Year 10+

🚲 Vehicles & Transport

Transport is a force multiplier — the right vehicle at the right time determines whether a community can trade, evacuate, forage, or stay isolated. This section covers every tier from your own feet to watercraft, with deep focus on bicycles, alternative fuels, engine diagnosis, animal power, and building boats from raw materials.

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First 72 Hours — Transport Priorities

Fill all vehicle fuel tanks immediately — availability collapses within hours of a crisis.
Add STA-BIL or PRI-G to all stored gasoline — extends shelf life from 3 months to 2 years.
Inspect and tune up every bicycle you own. Check tubes, brakes, chain. Bicycles outlast every vehicle once fuel is exhausted.
Locate and secure a factory service manual for every vehicle you depend on.
Identify your most fuel-efficient vehicle for essential runs; preserve the others.

1. The Transport Hierarchy

In a collapse scenario, transport options should be evaluated by fuel dependence, repairability, and longevity. The list below ranks from most to least durable over a multi-year timeline without supply chain support.

Your Feet

Zero fuel, zero maintenance, silent, always works. Sustainable pace: 20–25 miles/day. The baseline everything else improves upon — and the only option that never runs out.

Bicycle

50× more efficient than walking at the same caloric expenditure. No fuel. Repairable with basic hand tools. Can carry 200+ lbs with panniers and trailer. Silent. Can access trails no car can use. Also serves as an electricity generator.

Animal (Horse, Mule, Ox, Donkey)

No fossil fuel required. Self-reproducing. Multi-use: transport + draft labor + food source. Requires daily care and feed, but that feed can come from land you control. Mules especially are extraordinarily hardy.

Pre-1980 Vehicle

No computer ECU. Points ignition — purely mechanical. Carbureted fuel delivery. Can run on alternative fuels with minimal modification. Locally repairable with basic tools. A 1972 pickup is worth more than a 2022 pickup in an EMP scenario.

Modern Vehicle (Post-1990)

ECU-dependent. Vulnerable to EMP. Fuel injection is complex to repair without dealer scan tools. High short-term value when fuel and parts exist; rapidly loses utility as supply chains fail.

Watercraft

Situational, but extremely high value where applicable. No road required. Large cargo capacity — water transport uses roughly 1/10th the energy of equivalent land transport. Where rivers and lakes exist, this becomes Tier 2.

2. Bicycle Maintenance & Repair

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The Most Valuable Machine in a Post-Collapse World

A bicycle in good repair may be the single most valuable piece of hardware you own after collapse. It is 50× more efficient than walking, carries 200+ lbs, requires no fuel, is repairable with simple hand tools, operates silently, and can double as a power generation source. Maintain yours obsessively.

Why Bicycles Win

50× more efficient than walking at the same caloric expenditure
No fuel required — ever
Repairable with simple hand tools and improvised parts
Can carry 200+ lbs with proper cargo setup (panniers + trailer)
Access trails and paths cars cannot use
Silent operation — no acoustic signature
Can be used as a power generation source (see Bicycle Generator below)

Bicycle Cargo Setup

Bicycle cargo positions — balanced front/rear loading critical for handling stability

Critical Spare Parts to Stockpile (Per Bike)

Part	Qty	Why Critical
Inner tubes	10	Flats are guaranteed — most common failure
Tires	4	Sidewall damage is not patchable; tires wear out
Brake pads	4 sets	Braking is survival, especially loaded downhill
Brake cables	4 each	Cables fray and snap under repeated stress
Derailleur cables	4 each	Shifting failure is annoying but manageable short-term
Chains	3	Chains wear and break; measure stretch before failure
Chain lubricant	2 bottles	Dry chains destroy cassettes rapidly
Spoke wrench + spare spokes	36 spokes	Wheel truing is essential for long-term use
Freewheel/cassette	1 spare	Hard to improvise; irreplaceable without supply chain
Multi-tool with chain breaker	1	Essential for field repair of chain, cables, bolts
Patch kit	5 kits	Field flats when you're miles from camp
Tire levers	2 sets	Tire mounting/dismounting without damaging tube

Flat Repair Without a Patch Kit

Boot a sidewall tear: Fold a dollar bill or a strip of duct tape in thirds and place it inside the tire directly over the tear, between tube and tire casing. Works for hundreds of miles — the bill is just stiff enough to prevent the tube from extruding through.
Pack the tire: If the tube is destroyed, stuff the tire casing completely with dry grass, moss, rags, or cloth strips. Ride slowly. You will have a rough, bumpy ride but can travel several miles to safety.
Tube-within-tube: If you have an oversized tube (26" tube in a 24" tire, for example), fold and double it inside the tire — two layers provide enough cushion for limited travel.

Chain Maintenance

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Chain Wear Check — Use a Ruler

12 links of a new chain = exactly 12.0 inches. Measure regularly:
12.0 – 12.0625" = acceptable
12.0625" (1/16" stretch) = replace chain now
12.125" = chain is overdue; cassette likely damaged too

Cleaning: Kerosene, diesel, or hot soapy water. Scrub with an old brush. Dry completely before lubing.
Lubing: Apply thin oil to inner plates only — the roller-to-sprocket contact area. Wipe outer plates completely clean. Excess lube attracts grit and accelerates wear.

Wheel Truing Without a Stand

Flip the bike upside down on its handlebars and saddle. Spin the wheel and observe its path relative to the brake pad clearance point — the gap between pad and rim.

When the rim touches or nearly touches a brake pad, that is the high spot — the side the wheel is pulling toward.

To pull the rim away from that side: tighten the spoke nipple on the opposite side; loosen the spoke nipple on the same side. Work in ¼-turn increments.

Spin again. Check repeatedly. Patience — small increments. Never apply more than ½ turn at once or you risk building tension unevenly.

Bicycle Generator

Output: A human in sustained aerobic effort can produce 50–150W continuously. This is enough to charge 12V batteries, phones (via USB regulator), radios, and LED lighting systems.

Motor: Salvage a DC motor from a treadmill, washing machine, or car starter (permanent magnet DC motors work best as generators)
Friction drive: Mount motor with a rubber wheel on its shaft pressing against the tire sidewall. The rubber wheel contacts and spins the motor as you pedal.
Rectification: Add a bridge rectifier (4 diodes in a bridge configuration) to convert the motor's AC output to DC at ~12V
Regulation: Add a simple voltage regulator IC (LM7812 or equivalent) to stabilize output for sensitive electronics
Output connections: 12V battery charging direct; phones via USB 5V regulator; LED strips direct at 12V

3. Engine Basics

The Four-Stroke Cycle

[INTAKE]        [COMPRESSION]    [POWER/IGNITION]  [EXHAUST]
  piston ↓         piston ↑↑        spark → ↓          piston ↑
  intake           both valves       explosion           exhaust
  valve            closed            drives piston       valve
  opens            compress 8:1      down — WORK         opens
  air+fuel         stroke            stroke              gases
  enters                                                 exit

    1               2                   3                 4
    |               |                   |                 |
   ┌─┐             ┌─┐                 ┌─┐               ┌─┐
   │↓│  air+fuel   │ │  compressed     │*│  BANG!        │↑│  exhaust
   │ │─────────→   │ │─────────→       │ │─────────→     │ │─────────→
   └─┘             └─┘                 └─┘               └─┘
   ^intake         ^compression        ^power             ^exhaust
   valve open      valves closed       spark fires        valve open

Understanding these four strokes lets you diagnose any gasoline engine problem as a failure in one of four systems: Fuel · Air · Spark · Compression. If the engine has all four in correct amounts at the right time, it runs. If it doesn't, one of these four is missing.

Four-stroke engine cycle — fuel, air, spark, compression must all be present for the engine to run

Carbureted vs. Fuel Injected

Feature	Carbureted (Pre-1990)	Fuel Injected (Post-1990)
Adjustability	Fully adjustable with screwdrivers	Requires ECU/computer scan tools
Fuel quality tolerance	Tolerates lower octane, degraded fuel	More sensitive to fuel quality
EMP resistance	Resistant — no computers	Vulnerable — ECU is a chip
Repair access	Basic hand tools	Dealer scan tools often required
Altitude adjustment	Manual needle/jet screw	ECU auto-adjusts (but not if ECU is dead)
Alternative fuel use	Simple jet swap or needle adjustment	Complex reprogramming required

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Why Pre-1980s Vehicles Survive EMP

Points ignition is purely mechanical — a cam-triggered contact set with no semiconductors. No ECU means no chips to fry. Carbureted fuel delivery is fully mechanical with no solenoids or computers. A well-maintained 1972 pickup truck is more operationally valuable than a 2022 pickup after an electromagnetic pulse event.

Engine Won't Start — Diagnosis Checklist

Fuel: Is there fuel? Is it fresh? Disconnect the fuel line at the carb — does fuel flow when you turn on the key? If not: check the fuel pump, filter, petcock.

Spark: Remove a spark plug, reconnect the wire, ground the plug body against the engine block, and crank. Blue-white spark = good. Yellow/orange spark = weak coil or worn points. No spark = check points, condenser, ignition coil, spark plug wires.

Air: Is the air filter clear and unobstructed? A severely clogged filter will flood the engine rich and prevent starting.

Compression: Place your thumb firmly over a spark plug hole and crank. It should push your thumb off forcefully. Weak pressure = worn rings or valve problem. Test all cylinders — one low reading suggests a specific cylinder problem; all low = timing issue or major wear.

Timing: Is the distributor in the correct position? Timing too far advanced or retarded prevents starting (or causes knock and backfire). Mark the distributor before removing it.

Oil — Never Neglect This

Lubricates all moving metal; also cools, suspends combustion byproducts, and seals gaps between rings and cylinder
Check on dipstick: level between MIN and MAX; color golden to dark brown = OK; milky = water contamination (head gasket failure)
Running without oil: cylinder wall and bearing destruction in minutes — not hours
Change interval without fresh supply: extend to 5,000 miles maximum if using quality oil; never skip the change entirely

Cooling System

Coolant circulates: engine block → radiator → back → thermostat → repeat
Overheating causes: low coolant, failed water pump, clogged radiator, stuck thermostat, blown head gasket
Improvised radiator repair: crack 2 raw eggs into the coolant — proteins coagulate at the leak point and seal it temporarily (hours to days)
Failed thermostat: Remove the thermostat entirely and reinstall the housing. Engine runs cooler and less efficiently but will not overheat

Tire Repair

Plug: Drive a rubber plug into the tread puncture from the outside using a plug tool and rubber cement. Fast, field-applicable. Not for sidewalls.
Patch: Remove tire, buff the tube or inside casing, apply vulcanizing patch and glue. More permanent than a plug.
Run-flat improvisation: Stuff the tire casing with dense cloth, cut foam, or packed grass. Rim will take damage but allows slow travel to safety.
Tire irons required for bead seating and unseating on most vehicle tires.

4. Fuel Alternatives

Wood Gas (Producer Gas)

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This Is Proven Technology — Not Theory

Over 1 million European vehicles ran on wood gas during World War II. Sweden alone had 70,000 wood gas vehicles by 1944. The FEMA published complete construction plans in 1989 (available in the public domain). This works.

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Carbon Monoxide Hazard — Lethal

Wood gas contains 20–30% carbon monoxide (CO) — odorless, colorless, deadly in any enclosed space. All connections must be sealed and leak-tested before operation. Operate gasifiers outdoors only. Never run in a garage, barn, or building of any kind.

Principle: Burning wood in a restricted-oxygen environment produces carbon monoxide (CO) and hydrogen (H₂) gas. This gas mixture is combustible and runs in any carbureted gasoline engine. Expect a 30–40% power reduction versus gasoline.

FEMA downdraft gasifier — the standard design used by millions of WWII-era vehicles

Key Gasifier Components

Reactor vessel: Heat-resistant steel drum or pipe, ¼"+ wall. Fire brick lining ideal for throat area where temperatures reach 1,100°C.
Air nozzle: 1–2 steel pipes entering at combustion zone. The restriction creates gasification, not full combustion.
Reduction zone: Below combustion, above the grate. CO₂ + H₂O → CO + H₂ conversion happens here — this is where the usable fuel gas is made.
Ash grate: Perforated steel plate. Ash falls through; fuel bed rests on top; gas rises and exits sideways.
Cooling tubes: 10–15 feet of 2" pipe. Cools hot gas to a usable temperature for the engine. Coil in water or air-cool with fins.
Condensate trap: Lowest point in the cooling run. Collects tar and water. Drain after every use — neglected traps cause engine failure.
Filter: Sawdust or hay box removes particulates. Clean and replace regularly. Particulates destroy engine rings.
Output: Connect cleaned, cooled gas to carburetor air intake. Replace or bypass the choke butterfly valve.

Best Fuel for Gasifier

Hardwood chunks 2–3" size
Below 20% moisture content (critical)
Oak, hickory, beech preferred — high energy density, less tar
Softwoods produce more tar; require more frequent filter cleaning

Operating Procedure

Pre-heat gasifier 5–10 minutes before connecting to engine
Test output flame — should be steady blue before connecting
Expect 30–40% power reduction vs gasoline
Drain condensate trap and clean filter after every use

Biodiesel — From Waste Cooking Oil

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Safety — Methanol and Lye

Methanol is highly toxic by skin absorption and ingestion; causes blindness and death. Lye (sodium hydroxide) is caustic and causes severe chemical burns. Sodium methoxide (the combination) is extremely reactive. Work outdoors with gloves and eye protection. No open flames during mixing — methanol is extremely flammable.

Appleseed processor — the most common DIY biodiesel design; heated tank with agitation, gravity separation

Appleseed Processor — Step by Step

Filter the oil: Remove food particles. Heat to 150°F/65°C briefly to drive off water — water causes soap formation and ruins the batch. Oil must be completely dry (no bubbling when heated).

Titration: Test free fatty acid level to calculate the exact lye amount needed. Dissolve 1g NaOH in 1L distilled water. Dissolve oil sample in isopropyl alcohol; add phenolphthalein indicator; add lye solution drop by drop until pink. Each ml = 1 extra gram of NaOH needed per liter of oil.

Make sodium methoxide: Combine methanol (25% of oil volume) + NaOH lye (3.5g/L of oil + titration amount). Exothermic and toxic — mix in a sealed container. This is your catalyst solution.

React: Add sodium methoxide to oil heated to 55°C (130°F) with continuous mixing. React for 1–2 hours. Temperature must be maintained.

Settle: Allow 8+ hours without disturbing. Glycerin (darker, denser) sinks to the bottom. Biodiesel (golden, clearer) floats on top. Drain glycerin from the bottom valve.

Wash: Gently spray-wash biodiesel with water 3 times, allowing separation each time. This removes soap residue and catalyst.

Dry: Final heat to 150°F removes residual water. Biodiesel is ready when it appears clear and golden with no cloudiness.

Key notes: ~1 gallon oil yields ~1 gallon biodiesel. Methanol source: HEET yellow bottle, racing fuel, or industrial methanol. Lye source: hardware store drain cleaner (must be "100% sodium hydroxide"). Runs in any diesel engine with zero modification. Gels below 35°F/2°C — blend 20% petroleum diesel in winter.

Ethanol as Fuel

Ferment any sugar or starch source → distill to 85%+ ABV → fuel grade ethanol (see Chemistry section for full distillation process)
Runs in flex-fuel vehicles natively; carbureted engines need main jet needle adjustment (~30% richer mixture)
Lower energy density: approximately 30% more volume needed than equivalent gasoline energy
Also functions as: solvent, disinfectant (at 70–90% ABV), trade commodity, antiseptic for medical use

Fuel Storage Reference

Fuel	Untreated Life	Treated Life	Container	Notes
Gasoline	3–6 months	1–2 years (STA-BIL)	Metal jerry can	Ethanol blends degrade faster; E0 lasts longer
Diesel	1–2 years	5–10 years (biocide)	Metal or HDPE	Less volatile than gasoline; easier to store safely
Biodiesel	6 months	1–2 years	Dark sealed container	Degrades in light and oxygen; keep sealed
Ethanol	1+ year	2+ years	Glass or metal	Do not store in plastic — absorbs water
Wood gas	N/A	—	N/A	Generate on demand only; cannot be stored

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Fuel Storage Safety

Store away from living spaces in vented enclosures, away from all ignition sources. Ground metal containers before pouring in dry climates (static spark hazard). Never mouth-siphon gasoline — use a hand pump. Label all containers with fuel type and date filled.

5. Animal Transport

When fuel is gone and vehicles are inoperable, draft animals become the backbone of agriculture, hauling, and transport. Communities with animal power will outperform those without by an enormous margin over a multi-year timeline.

Horse Care Essentials

Daily Working Requirements

20 lbs hay + 5 lbs grain (working hard)
10–12 gallons water
2–3 acres/horse if using grazing to reduce feed cost
Hoof trim every 6–8 weeks minimum

Common Ailments

Colic: Most deadly; horse cannot vomit; keep walking; veterinary care critical
Laminitis: Hoof inflammation from rich pasture; restrict grazing on lush grass
Thrush: Bacterial hoof rot from wet conditions; clean hooves daily; treat with dilute bleach or copper sulfate solution

Harness Basics

Collar harness is the most efficient for draft work — the load is distributed across the horse's shoulders. Breastplate harness is simpler and lighter but less efficient for heavy loads. Traces connect collar to load. Singletree distributes the pull evenly between traces. A skilled person can fabricate functional harness from heavy leather (see Textiles / Tanning sections) with hand tools.

Mule vs. Horse

Feature	Horse	Mule
Hardiness	Moderate	Very high
Lifespan	25–30 years	35–40 years
Daily feed	High requirement	~30% less than horse
Forage quality needed	Good hay/grain	Survives poor forage
Disease resistance	Moderate	High
Hoof care	Regular shoeing needed	Tougher hooves, less care
Reproduction	Can breed	Sterile (requires ongoing breeding program)
"Stubbornness"	Controllable	Refuses if it senses danger — a safety feature

Ox and Draft Cattle

Any cattle breed can be trained as draft animals; start at 1–2 years old before they're fully set in their ways
Slower than a horse, but with greater pulling strength for their size and dramatically lower maintenance cost
Yoke construction: Neck yoke for single ox (wooden bow fits under throat); head yoke for a team of two (crossbeam rests on poll)
Basic commands: Gee (right), Haw (left), Whoa (stop), Get up (forward) — consistent training from the start is critical
Key advantage: The ox becomes food at the end of its working life — horses and mules do not

Donkey

The hardiest of all working animals — survives on minimal forage where horses and mules cannot
Excellent pack animal; carries 20–30% of body weight (50–80 lbs) reliably
Strong attachment to home territory makes them difficult to steal and easy to return
The loud bray is a liability in stealth situations — consider this for operational security

6. Watercraft

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Water Transport Uses 1/10th the Energy of Land Transport

Historical civilizations were built along rivers for this reason. A simple raft or skiff carrying 500 lbs downstream requires a fraction of the effort of a horse-drawn wagon carrying the same load on a dirt road. Communities near navigable waterways have an enormous logistical advantage.

Dugout Canoe

Dugout canoe with outrigger — the outrigger dramatically increases stability for open water and fishing

Dugout Canoe — Construction Details

Tree selection: Straight grain, rot-resistant species. Cedar is the first choice; cypress, tulip poplar, and basswood also work. Diameter must equal your intended finished beam width plus 6" minimum for wall thickness.
Felling and drying: Score the cut ends with a saw and apply paint or pine pitch to slow drying — this prevents cracking. Dry the log 6–12 months before hollowing.
Burn and adze: Controlled burning inside the log while adzing (scraping) accelerates removal. Burn → scrape → burn → scrape cycle. Maintain 1.5–2" wall thickness throughout.
Outrigger assembly: Two crossbeams (amas), each 18–24" long, lashed to the canoe gunwale. One float log lashed to the outboard ends. Lashing with plant fiber rope or paracord is sufficient.
Propulsion options: Double-blade paddle (fastest, most efficient), single-blade, pole in shallow water, or a simple lateen sail on a mast stepped through a thwart.

Flat-Bottomed Skiff

Flat-bottomed skiff frame plan — a 12' × 4' skiff can be built in 1–3 days and carries 4–6 people or 400–600 lbs of cargo

Flat-Bottomed Skiff Construction Sequence

Build the transom (stern board) and bow piece (stem). These anchor the hull shape.

Lay the bottom planks full length between transom and bow, glued and ring-shank nailed. Full-sheet exterior plywood (4×12 ft) works as a one-piece bottom.

Add frames and ribs across the bottom every 18" for rigidity. Bend into shape; nail to bottom planks.

Steam-bend and attach side strakes (planks) to the frames. Two strakes per side, lapping or butted. Steam bending: wrap plank in wet burlap, apply steam for 20–30 min per inch of thickness until flexible.

Caulk all seams: Drive oakum (hemp fiber) into every seam with a caulking iron. Seal with pine pitch or pine tar. Modern substitute: polyurethane marine caulk.

Install thwarts (seats) spanning the beam at thirds. These are structural members, not optional — they hold the hull shape under load.

Raft Construction

Lash logs or planks to cross-members. No joinery required — only lashing skill.
Buoyancy calculation: 1 cubic foot of wood floats approximately 30–40 lbs net. A raft 10 ft × 10 ft × 6" thick uses about 50 cu ft of wood → ~1,500–2,000 lbs gross buoyancy → supports ~800 lbs cargo plus raft weight.
Steering oar: long pole or oar at the stern on a simple pin pivot. One person steering; others can pole in shallow water.
Current does most of the downstream work — reserve energy for poling upstream or across current.

Reading Water

Environment	Key Skills	Primary Hazards
River	Reading current, eddies, strainers, knowing when to portage	Strainers (debris), hydraulics at drops, low-head dams
Lake	Wind reading, weather assessment, maintaining headings	Sudden storms, no current to assist, long exposure to wind
Coastal	Tide tables, chart reading, headland crossing timing	Tidal currents, offshore winds, rogue waves, lee shores

Reading River Current

Fastest water is on the outside of bends; slowest on the inside
Eddy: Calm water behind an obstruction (rock, point); safe stopping point; enter from downstream edge
V pointing downstream = clear, deepest channel; run this
V pointing upstream = submerged rock below the surface; avoid

Strainer Hazard

A strainer is submerged debris (fallen tree, fence) through which current flows
Current pins anything flexible (boat, body) against the debris with extreme force
Always scout unfamiliar rivers before committing
If broaching on a strainer: lean INTO it (counterintuitive), create air gap to pull away

← Textiles Next: Metallurgy →

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Related Sections

Metallurgy → Fabricating vehicle and implement parts from scrap steel · Energy → Fuel storage, electrical generation, and battery systems · Agriculture → Growing oil crops for biodiesel feedstock · Chemistry → Ethanol distillation process detail · Animal Husbandry → Breeding and maintaining draft animals