Nickel Iron Battery Manufacturing

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NiFe Factory Material and Plate Model for 20 MWh/year

Assumptions:

  • Plant output: 20,000 kWh/year
  • Planning mass intensity: 20 kg/kWh finished wet battery
  • Total finished battery mass: 400 t/year
  • 20-foot container payload basis: 28.3 t/container
  • Plate area model: 40 mg/cm² coated-face loading, 75% utilization, 1.2 V nominal
  • Resulting areal energy density used for sizing: 104 Wh/m² of coated face
Material / Metric Unit basis Per kWh Annual total for 20 MWh Commodity cost Commodity $/kWh Annual commodity cost Integrated $/kWh Annual integrated cost 20 ft containers by weight
Nickel, contained metal kg 1.20 24.0 t $17.34/kg $20.81 $416,160 $20.81 $416,160 0.85
Nickel hydroxide equivalent kg 1.90 37.9 t derived from nickel content n/a n/a n/a n/a 1.34
Iron powder kg 5.50 110.0 t $2.00/kg purchased $11.00 $220,000 $4.40 $88,000 3.89
Steel mesh / sheet / case internals kg 6.00 120.0 t $1.018/kg purchased $6.11 $122,160 $3.60 $72,000 4.24
KOH, dry basis kg 2.00 40.0 t $0.91/kg $1.82 $36,400 $1.82 $36,400 1.41
HDPE / PP case resin kg 1.00 20.0 t $0.87/kg $0.87 $17,400 $0.87 $17,400 0.71
Copper bus bars / terminals kg 0.30 6.0 t $12.758/kg $3.83 $76,548 $3.83 $76,548 0.21
Separator + binder + additives kg 0.80 16.0 t $3.00/kg assumed $2.40 $48,000 $2.40 $48,000 0.57
Deionized water kg 3.20 64.0 t $0.001/kg assumed $0.00 $64 $0.00 $64 2.26
Total 20.00 kg 400.0 t $46.84/kWh $936,732 $37.73/kWh $754,572 14.13

Electrode Plate Area Model

The next table is for factory sizing of the electrode fabrication line. It uses the aggressive planning assumption of 104 Wh/m² of coated face.

Plate metric Formula basis Per kWh Annual total for 20 MWh
Positive coated-face area 1000 Wh / 104 Wh/m² 9.62 m² 192,308 m²
Negative coated-face area matched to positive area 9.62 m² 192,308 m²
Total coated-face area, both polarities positive + negative 19.23 m² 384,615 m²
Positive metal-sheet plate area double-coated plates, so coated-face area / 2 4.81 m² 96,154 m²
Negative metal-sheet plate area double-coated plates, so coated-face area / 2 4.81 m² 96,154 m²
Total metal-sheet electrode area positive sheet + negative sheet 9.62 m² 192,308 m²

Shipping Container Summary

Shipping item Annual tonnage 20 ft containers at 28.3 t payload
Finished wet batteries 400.0 t 14.13
All nickel input, contained metal basis 24.0 t 0.85
Iron powder 110.0 t 3.89
Steel 120.0 t 4.24
KOH 40.0 t 1.41
Everything except water 336.0 t 11.87

Main Readout

  • A 20 MWh/year NiFe plant at 20 kg/kWh is about 400 t/year of finished battery output.
  • On purchased materials, this planning model lands near $46.84/kWh.
  • With aggressive in-house iron and steel integration, the same model lands near $37.73/kWh.
  • Finished-battery outbound logistics are about 14 standard 20-foot containers per year by weight.
  • The electrode line must process about 384,615 m²/year of coated electrode faces under the plate-loading assumption used here.

Nickel-Iron Battery Manufacturing Process Chain

Material / Component Raw Inputs Processing Steps Equipment Output Product
Nickel hydroxide active material Nickel scrap or nickel salts, NaOH or KOH, water 1. Dissolve nickel in acid to form nickel salt solution

2. Precipitate Ni(OH)₂ using NaOH or KOH
3. Filter slurry
4. Wash precipitate
5. Dry powder
6. Mill to particle size

Dissolution reactor
Stirred tank precipitator
Filter press
Dryer oven
Ball mill or jet mill 		Nickel hydroxide powder
Iron electrode powder Iron powder feedstock, optional additives (graphite, iron sulfide) 1. Acquire or atomize iron powder

2. Blend additives
3. Homogenize powder mixture

Powder atomizer (if internal)
Ribbon blender
Powder mixer 		Iron electrode powder blend
Potassium hydroxide electrolyte KOH pellets, distilled water, optional lithium hydroxide additive 1. Purify water

2. Dissolve KOH slowly with agitation
3. Add optional LiOH stabilizer
4. Filter solution

Mixing tank
Agitator
Filtration unit 		Battery electrolyte solution (20–30% KOH)
Nickel current collector Steel coil or mesh 1. Steel coil cleaning

2. Perforation or mesh forming
3. Optional nickel plating
4. Sheet cutting

Coil feed line
Punch press
Plating bath
Shear cutter 		Nickel current-collector sheets
Iron current collector Steel coil or mesh 1. Coil cleaning

2. Perforation or mesh stamping
3. Degreasing
4. Sheet cutting

Coil line
Punch press
Degreasing washer
Sheet cutter 		Iron electrode mesh sheets
Nickel electrode plates Nickel hydroxide powder, binder (PTFE), conductive carbon, solvent, collector mesh 1. Slurry mixing

2. Roll-to-roll coating onto collector
3. Drying oven
4. Compression/calendering
5. Plate cutting

Planetary mixer
Coating line
Drying oven
Calender rollers
Laser or punch cutter 		Nickel electrode plates
Iron electrode plates Iron powder mixture, binder, solvent, steel mesh 1. Paste mixing

2. Paste coating or filling into mesh
3. Drying
4. Compression/calendering
5. Plate cutting

Mixer
Coating station
Drying oven
Roll press
Plate cutter 		Iron electrode plates
Separator sheets Polypropylene, polyethylene, nylon, or cellulose sheet rolls 1. Receive separator rolls

2. Slit to width
3. Die-cut sheets

Slitting machine
Die cutter 		Separator sheets
Plastic battery cases HDPE or polypropylene pellets (virgin or recycled) 1. Pellet drying

2. Injection molding
3. Cooling
4. Trim flashing

Plastic dryer
Injection molding machine
Trim station 		Battery case halves
Bus bars and terminals Copper bar stock or sheet 1. Cut to length

2. Drill terminal holes
3. Surface cleaning

Saw or shear
CNC drill
Deburring tools 		Copper bus bars and terminals
Electrode stack assembly Nickel plates, iron plates, separators 1. Pick-and-place electrode stacking

2. Insert separators
3. Align stack

Automated stacking machine
Robotic arm 		Cell electrode stack
Tab welding Electrode tabs and bus bar leads 1. Align tabs

2. Weld tabs to bus bars

Ultrasonic welder
Resistance welder 		Electrically connected electrode stack
Cell insertion Electrode stack, plastic case 1. Insert stack into molded case

2. Install internal insulation

Robotic assembly station Cell assembly
Electrolyte filling Electrolyte solution 1. Metered electrolyte fill

2. Degas air bubbles

Metering pump
Fill station 		Filled battery cell
Cell sealing Cell lid, gasket 1. Lid placement

2. Ultrasonic weld or compression seal

Ultrasonic welder
Press 		Sealed battery cell
Formation cycling Newly assembled cells 1. Initial charge cycle

2. Rest period
3. Discharge cycle
4. Repeat formation cycles

Programmable formation racks
Battery cyclers 		Activated NiFe battery cells
Quality testing Finished cells 1. Leak test

2. Capacity test
3. Internal resistance measurement
4. Visual inspection

Pressure tester
Battery analyzer
Inspection station 		Qualified battery cells
Module assembly Cells, bus bars, frame 1. Arrange cells

2. Connect bus bars
3. Install terminals
4. Final inspection

Assembly bench
Torque tools 		Battery module
Recycling loop Used cells 1. Drain electrolyte

2. Shred plastic cases
3. Separate metals
4. Recover nickel compounds
5. Recycle steel

Shredder
Magnetic separator
Chemical recovery tanks 		Recovered nickel, steel, and plastics
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