Inventory and Waste Cost Simulator

Simulator

Enter the current state and Lean target

Core logic: Annual holding cost = inventory value x carrying-cost rate

Current inventory (units)

Average unit cost

Holding cost (%)

Annual throughput (units)

Current lead time (days)

Workdays per year

Lean improvement scenario

Target inventory reduction (%)

Target lead-time reduction (%)

Batch size reduction (%)

Pull-system waste reduction (%)

Kanban recommendation inputs

Container quantity

Demand variability (CV %)

Replenishment lead time (days)

Safety / service factor

Results

Inventory economics

Inventory Value: $456,000
Annual Holding Cost: $82,080
Throughput / Day: 720
Potential Lean Savings: $31,709
Lead-Time Savings: $20,520
Inventory Savings: $24,624
Recommended Kanban: 65 cards
Kanban Stock: 2,600 units
Days of Inventory: 16.7 days

Interpretation

Current inventory is tying up meaningful annual holding cost, and the Lean scenario shows a strong recurring savings opportunity.

Best opportunity: reducing inventory directly creates the largest annual savings in this scenario.

Kanban note: variability and replenishment lead time are the main drivers of the recommended card count.

Pull-system note: the pull improvement factor is modeled as a waste-reduction uplift on the remaining holding-cost burden after inventory and lead-time reductions.

Breakdown

Savings scenario

Source	Amount	Share
Inventory reduction	$24,624	46.2%

Kanban

Recommendation detail

Kanban formula: daily demand x replenishment lead time + safety stock, all divided by container quantity.

Safety stock factor: demand variability and the chosen service factor drive the protection level.

Lean target inventory after reduction: 8,400 units

Instructions

How to use this app

Enter current inventory, unit cost, annual throughput, holding-cost rate, and current lead time.
Set the Lean scenario reductions for inventory, lead time, batch size, and pull-system waste improvement.
Click `Simulate` to calculate annual holding cost and projected recurring Lean savings.
Enter container quantity, demand variability, replenishment lead time, and service factor to generate a Kanban recommendation.
Use the outputs together: annual holding cost frames today’s waste, while the savings and Kanban guidance show how a pull-based future state could change it.

The Kanban card count is directional. If you have strong seasonality, highly variable supplier performance, or mixed-model replenishment, you should validate the recommendation against real replenishment history.

Batch-size and pull gains are modeled as additional recurring savings levers layered on top of direct inventory and lead-time improvements. Adjust them conservatively when you are early in the project.

What This Inventory and Waste Simulator Helps You Quantify

This tool turns excess inventory into financial language. It estimates annual holding cost, highlights Lean waste tied to overproduction and long replenishment loops, and helps teams test how smaller batches or pull-based replenishment change the cost profile.

Use it when inventory feels normal because it has been there a long time, but leadership needs a clearer view of carrying cost, delay risk, and potential savings.

Core Inventory Logic

Metric	Formula or Logic	Meaning
Annual holding cost	Average inventory value x Holding-cost rate	Financial cost of carrying inventory over time.
Lead-time exposure	Demand x Replenishment delay	How much stock the system needs to cover replenishment lag.
Kanban quantity	Demand during lead time + safety factor	Signal-based replenishment target for pull systems.

Worked Example

If a work center carries $250,000 of average inventory and the holding-cost rate is 22%, the carrying burden is $55,000 per year before obsolescence, extra handling, or schedule distortion are fully counted. Reducing batch size or replenishment delay may cut that burden quickly without touching sales.

The simulator helps frame inventory reduction as a business decision rather than a visual housekeeping exercise.

How to Interpret the Results

High holding cost: the system is paying a large premium for slow flow.
Large Kanban quantity: demand variability or lead-time delay is still too high.
Strong savings from batch reduction: setup, flow, and replenishment design deserve review.
Little savings from small changes: the real constraint may be supplier delay or internal instability.

Inventory and Waste Frequently Asked Questions

Why is inventory treated as waste in Lean?

Because inventory hides problems, consumes cash, increases handling, and delays the visibility of defects or imbalance in the system.

What is included in holding cost?

Typical holding cost includes capital, storage, handling, insurance, shrinkage, and obsolescence risk.

Can inventory reduction create new risk?

Yes. If lead time, changeover, or process instability is not addressed, reducing inventory too early can simply expose a weak system faster.

Why does demand variability matter for Kanban sizing?

Because a pull loop must absorb normal variation. Without that adjustment, the signal quantity may look lean on paper but fail in practice.

What is the most common inventory-reduction mistake?

Cutting stock without fixing the flow drivers beneath it. Inventory should be reduced as the system becomes more stable, not as a slogan by itself.

Related Templates and Guides

Download the Standard Work Template

Use standard work to stabilize replenishment tasks, material handling, and line-side routines after inventory changes are made.

Read the Value Stream Mapping Guide

Use the guide to connect inventory cost back to flow delay, queue size, and the current-state map.