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Shipped / ProductionENTERPRISE AI · ENERGY SWAP CASE

Automated drone battery swap, powered by IoT + BMS.

Built around endurance bottlenecks in agricultural spray drones, we shipped a drone energy operator an intelligent swap system combining IoT, smart energy storage, automated swap stations and BMS. When a drone hits low battery it can auto-return, auto-swap and auto-relaunch — cutting manual handling and keeping field operations continuous.

Book a 30-min consultation See how it works

Single swap time

0%↓

Manual intervention

0/7

IoT monitoring

0 layers

System architecture

LIVE · ENERGY SWAP

Live

SINGLE SWAP

90s end-to-end swap

Auto-return

Triggered on low battery

BMS health

Live SoC / SoH

Manual intervention 0%↓

Automated operation

0 slots / station

Live IoT sync

IoTGSKJAIBMSGSKJAIAutomated swapGSKJAIMini-program dispatchGSKJAIReal-time data loopGSKJAISmart energy storageGSKJAIIoTGSKJAIBMSGSKJAIAutomated swapGSKJAIMini-program dispatchGSKJAIReal-time data loopGSKJAISmart energy storageGSKJAI

/ 01 — THE PROBLEM

Drones reached the farm — endurance became the bottleneck.

The constraint was never flight capability. It was energy resupply.

On large-scale field operations the client kept hitting the same four problems. Together they framed the system challenge we set out to solve.

P-01 · PAIN POINT

Single charge time

30-40 min

A battery flies briefly, then sits on the charger for ages

The legacy loop — return, detach, charge, wait — breaks operational continuity every cycle.

P-02 · PAIN POINT

Manual dependency

Frequent

Manual swap is slow and carries safety risk

Repeated handling, high heat, unstable contacts and pilot fatigue accumulate into a hard ceiling on throughput.

P-03 · PAIN POINT

Battery health visibility

None

No real-time view of each battery's health

Without SoC, temperature, cell health and cycle count, battery life and failure rates are not controllable.

P-04 · PAIN POINT

Coordinated modules

The drone operations loop is incomplete

The client needed a full system — energy management, dispatch and automated operations — not another piece of hardware.

/ 02 — LIVE SAMPLE

How a drone completes one automated swap

We broke the old "stop and charge" pattern into five automated stages.

Same operations chain. The left column is how it used to run manually; the right column is what the system does today.

STAGE · 01

Low battery

BEFOREPilot manually decides to return

NOWSystem detects low battery and triggers return

STAGE · 02

Return to base

BEFOREManual battery removal

NOWDrone auto-docks at the swap station

STAGE · 03

Battery swap

BEFOREManual plug and unplug

NOWMechanical swap unit handles it end-to-end

STAGE · 04

Battery check

BEFORENo real-time status visibility

NOWBMS evaluates battery health automatically

STAGE · 05

Relaunch

BEFOREPilot manually restarts the mission

NOWSystem resumes the flight task automatically

/ 03 — HOW WE THINK

We didn't just build another charger.

We compared three resupply paths and chose intelligent automated swap.

Our test: does the energy system become part of the drone, or just one more piece of gear next to it?

APATH · A

Traditional manual charging

Low cost

Simple to deploy

Long waits

Heavy operational breaks

High manual dependency

Fine for low-frequency small jobs. Not for continuous field work.

BPATH · B

Manual swap with spare batteries

Shorter waits

Partial efficiency gain

Still manual

No battery visibility

Complex ops

A transitional step. Doesn't scale into intelligent operations.

CPATH · C

Our Choice

Intelligent automated swap system

Auto-return and auto-swap

Smart BMS

Live IoT monitoring

Data-driven operations

Upfront engineering investment

Energy becomes part of the drone, not a separate device.

/ 04 — HOW IT WORKS

A five-step pipeline built around energy dispatch

Five modules — from the drone to the mini program — close one energy loop.

The system decomposes into: drone, automated swap station, BMS, IoT data platform, and mini-program dispatch.

STEP · 01

Drone auto-return on low battery

Continuously monitors battery, status and mission progress, then triggers return to the nearest swap station.

IoTFlight control syncDispatch logic

STEP · 02

Swap station performs the swap

Auto-locate, identify the unit, remove the old battery, install a fresh one — no operator in the loop.

Mechanical unitBattery IDPrecise positioning

STEP · 03

BMS for battery intelligence

Full-stack monitoring of voltage, temperature, current, SoC and SoH, with auto-balancing and health scoring.

BMSBalancingHealth scoring

STEP · 04

IoT data platform sync

Drone, battery and station state stream to the cloud in real time, driving alerts and dispatch policy.

IoT gatewayLive messagingAnomaly alerts

STEP · 05

Unified mini-program dispatch

Operators check runtime, inventory and alarms in the mini program and push dispatch commands remotely.

Mini programAdmin consoleAccess control

SYSTEM ARCHITECTURE

Four layers, bottom-up energy coordination

Layered View

Application

APPLICATION

Mini programDispatch consoleAlert center

Platform

PLATFORM

IoT platformData syncTask dispatch

Algorithm

ALGORITHM

BMSCell balancingState prediction

Device

DEVICE

Swap stationDroneEnergy storage

Data flow: device → algorithm → platform → application↑ uplink · ↓ control

DESIGN PRINCIPLES

Core design principles

01
Continuous operation over single-flight endurance
The goal isn't longer flights. It's no interruptions.
02
Automation over manual workflows
Automated swap removes operator effort and operator error.
03
Batteries are assets, not consumables
BMS makes every battery trackable and manageable.
04
System coordination over standalone devices
Drone + battery + IoT + platform + dispatch — every piece matters.

/ 05 — SYSTEM IN PRODUCTION

The mini program, running in production

Payment, deposit, orders, swap, KYC, work orders — a complete business loop.

The screens below are captured from the live operations mini program. Each state maps to a real business flow.

BUYOUT

Device buyout

Asset-style purchase for battery hardware, with BMS status and coupon support.

DEPOSIT

Deposit and refund

Outstanding deposits, order status and refund requests — full closed loop.

ORDERS

Order center

Rental, purchase, swap and charge orders unified into one view and state machine.

SWAP DONE

Swap completion receipt

Battery removed, order details one tap away.

KYC

KYC verification

Dual-side ID OCR, profile confirmation and upfront risk checks.

PAID

Paid · device refund

Once payment clears, users can request a refund or review payment details.

WORK ORDER · Work order center

One mobile flow for battery and cabinet work orders

For both asset types — battery and cabinet — operators run intake → on-site work → close-out from a single panel, covering fault location, merchant, online state, slot ID and other key fields.

Asset types

Order states

100%

Mobile handling

Fault locationMerchantOnline stateSlot IDAction log

Cabinet #123665447895

Done

Cabinet #123665447896

Pending

Battery #BAT-072

Healthy

Dispatch · T-2419

Syncing

All shots are from the live mini program (anonymized).

/ 05.5 — OPERATION COCKPIT

A single platform cockpit

Every device, battery and work order — on one panel.

Moving operations from "scattered control" to "one platform" is the key change this system delivers.

/ 06 — THE RESULT

From "stop to charge" to "keep working"

Six dimensions show what changed after launch.

DIMENSION

BEFORE

AFTER

Resupply method

Manual charging

Automated swap

Single resupply time

30-40 min

< 90s

Manual involvement

Frequent manual ops

Automated

Battery management

Manual judgement

Live BMS

Operational continuity

Frequent interruptions

Continuous operation

Operating model

Scattered control

Unified platform

"Pilots used to dread the constant return-and-swap cycle. Now the system handles the swap and pilots focus on the actual job. On large fields the throughput gain is hard to miss."

Client · project lead

CLIENT TESTIMONIAL · 2026

/ 07 — TECHNICAL HIGHLIGHTS

Engineering highlights

Every battery, every swap and every device — visible by default.

AUTO-DOCKING

Automated swap

Drone and station dock automatically — minimal operator involvement.

BATTERY MGMT

Smart BMS

Live status per battery improves safety and extends service life.

IOT SYNC

Live IoT sync

Devices, platform and mini program stay in sync in real time.

GREEN ENERGY

Greener energy use

Smart storage and swap together reduce energy waste.

/ 08 — WHERE IT FITS

The same swap architecture extends to more new-energy scenarios.

Starting from agricultural spray drones, energy dispatch reaches further.

Agricultural spray drones

Automated swap and endurance

This case

Inspection drones

Long-duration patrols

EXTENDABLE

Logistics drones

High-frequency delivery resupply

EXTENDABLE

Electric motorcycles

Urban swap network

EXTENDABLE

Energy storage units

Smart battery dispatch

EXTENDABLE

Industrial robots

Automated energy resupply

EXTENDABLE

Want to know which approach fits your scenario?

Related cases

Other projects delivered by Wavesteam — AI, IoT, platform builds and enterprise software.

Engineering Delivery

If you're staring at a concreteengineering problem, we can skip the small talk and start from scope, integrations and milestones.

These projects usually involve business systems, device integration, AI workflows or multi-role back-offices. We assess feasibility against real delivery constraints and give recommendations close to the implementation stage.

Business email

contact@boilingwater.cn

Office

10F, South Tower, Kingkey Yujing Times, Longgang District, Shenzhen

Home All case studies Book a consultation

Shipped / ProductionENTERPRISE AI · ENERGY SWAP CASE

Automated drone battery swap, powered by IoT + BMS.

Book a 30-min consultation See how it works

Single swap time

0%↓

Manual intervention

0/7

IoT monitoring

0 layers

System architecture

LIVE · ENERGY SWAP

Live

SINGLE SWAP

90s end-to-end swap

Auto-return

Triggered on low battery

BMS health

Live SoC / SoH

Manual intervention 0%↓

Automated operation

0 slots / station

Live IoT sync

/ 01 — THE PROBLEM

Drones reached the farm — endurance became the bottleneck.

The constraint was never flight capability. It was energy resupply.

On large-scale field operations the client kept hitting the same four problems. Together they framed the system challenge we set out to solve.

P-01 · PAIN POINT

Single charge time

30-40 min

A battery flies briefly, then sits on the charger for ages

The legacy loop — return, detach, charge, wait — breaks operational continuity every cycle.

P-02 · PAIN POINT

Manual dependency

Frequent

Manual swap is slow and carries safety risk

Repeated handling, high heat, unstable contacts and pilot fatigue accumulate into a hard ceiling on throughput.

P-03 · PAIN POINT

Battery health visibility

None

No real-time view of each battery's health

Without SoC, temperature, cell health and cycle count, battery life and failure rates are not controllable.

P-04 · PAIN POINT

Coordinated modules

The drone operations loop is incomplete

The client needed a full system — energy management, dispatch and automated operations — not another piece of hardware.

/ 02 — LIVE SAMPLE

How a drone completes one automated swap

We broke the old "stop and charge" pattern into five automated stages.

Same operations chain. The left column is how it used to run manually; the right column is what the system does today.

STAGE · 01

Low battery

BEFOREPilot manually decides to return

NOWSystem detects low battery and triggers return

STAGE · 02

Return to base

BEFOREManual battery removal

NOWDrone auto-docks at the swap station

STAGE · 03

Battery swap

BEFOREManual plug and unplug

NOWMechanical swap unit handles it end-to-end

STAGE · 04

Battery check

BEFORENo real-time status visibility

NOWBMS evaluates battery health automatically

STAGE · 05

Relaunch

BEFOREPilot manually restarts the mission

NOWSystem resumes the flight task automatically

/ 03 — HOW WE THINK

We didn't just build another charger.

We compared three resupply paths and chose intelligent automated swap.

Our test: does the energy system become part of the drone, or just one more piece of gear next to it?

APATH · A

Traditional manual charging

Low cost

Simple to deploy

Long waits

Heavy operational breaks

High manual dependency

Fine for low-frequency small jobs. Not for continuous field work.

BPATH · B

Manual swap with spare batteries

Shorter waits

Partial efficiency gain

Still manual

No battery visibility

Complex ops

A transitional step. Doesn't scale into intelligent operations.

CPATH · C

Our Choice

Intelligent automated swap system

Auto-return and auto-swap

Smart BMS

Live IoT monitoring

Data-driven operations

Upfront engineering investment

Energy becomes part of the drone, not a separate device.

/ 04 — HOW IT WORKS

A five-step pipeline built around energy dispatch

Five modules — from the drone to the mini program — close one energy loop.

The system decomposes into: drone, automated swap station, BMS, IoT data platform, and mini-program dispatch.

STEP · 01

Drone auto-return on low battery

Continuously monitors battery, status and mission progress, then triggers return to the nearest swap station.

IoTFlight control syncDispatch logic

STEP · 02

Swap station performs the swap

Auto-locate, identify the unit, remove the old battery, install a fresh one — no operator in the loop.

Mechanical unitBattery IDPrecise positioning

STEP · 03

BMS for battery intelligence

Full-stack monitoring of voltage, temperature, current, SoC and SoH, with auto-balancing and health scoring.

BMSBalancingHealth scoring

STEP · 04

IoT data platform sync

Drone, battery and station state stream to the cloud in real time, driving alerts and dispatch policy.

IoT gatewayLive messagingAnomaly alerts

STEP · 05

Unified mini-program dispatch

Operators check runtime, inventory and alarms in the mini program and push dispatch commands remotely.

Mini programAdmin consoleAccess control

SYSTEM ARCHITECTURE

Four layers, bottom-up energy coordination

Layered View

Application

APPLICATION

Mini programDispatch consoleAlert center

Platform

PLATFORM

IoT platformData syncTask dispatch

Algorithm

ALGORITHM

BMSCell balancingState prediction

Device

DEVICE

Swap stationDroneEnergy storage

Data flow: device → algorithm → platform → application↑ uplink · ↓ control

DESIGN PRINCIPLES

Core design principles

01
Continuous operation over single-flight endurance
The goal isn't longer flights. It's no interruptions.
02
Automation over manual workflows
Automated swap removes operator effort and operator error.
03
Batteries are assets, not consumables
BMS makes every battery trackable and manageable.
04
System coordination over standalone devices
Drone + battery + IoT + platform + dispatch — every piece matters.

/ 05 — SYSTEM IN PRODUCTION

The mini program, running in production

Payment, deposit, orders, swap, KYC, work orders — a complete business loop.

The screens below are captured from the live operations mini program. Each state maps to a real business flow.

BUYOUT

Device buyout

Asset-style purchase for battery hardware, with BMS status and coupon support.

DEPOSIT

Deposit and refund

Outstanding deposits, order status and refund requests — full closed loop.

ORDERS

Order center

Rental, purchase, swap and charge orders unified into one view and state machine.

SWAP DONE

Swap completion receipt

Battery removed, order details one tap away.

KYC

KYC verification

Dual-side ID OCR, profile confirmation and upfront risk checks.

PAID

Paid · device refund

Once payment clears, users can request a refund or review payment details.

WORK ORDER · Work order center

One mobile flow for battery and cabinet work orders

Asset types

Order states

100%

Mobile handling

Fault locationMerchantOnline stateSlot IDAction log

Cabinet #123665447895

Done

Cabinet #123665447896

Pending

Battery #BAT-072

Healthy

Dispatch · T-2419

Syncing

All shots are from the live mini program (anonymized).

/ 05.5 — OPERATION COCKPIT

A single platform cockpit

Every device, battery and work order — on one panel.

Moving operations from "scattered control" to "one platform" is the key change this system delivers.

/ 06 — THE RESULT

From "stop to charge" to "keep working"

Six dimensions show what changed after launch.

DIMENSION

BEFORE

AFTER

Resupply method

Manual charging

Automated swap

Single resupply time

30-40 min

< 90s

Manual involvement

Frequent manual ops

Automated

Battery management

Manual judgement

Live BMS

Operational continuity

Frequent interruptions

Continuous operation

Operating model

Scattered control

Unified platform

"Pilots used to dread the constant return-and-swap cycle. Now the system handles the swap and pilots focus on the actual job. On large fields the throughput gain is hard to miss."

Client · project lead

CLIENT TESTIMONIAL · 2026

/ 07 — TECHNICAL HIGHLIGHTS

Engineering highlights

Every battery, every swap and every device — visible by default.

AUTO-DOCKING

Automated swap

Drone and station dock automatically — minimal operator involvement.

BATTERY MGMT

Smart BMS

Live status per battery improves safety and extends service life.

IOT SYNC

Live IoT sync

Devices, platform and mini program stay in sync in real time.

GREEN ENERGY

Greener energy use

Smart storage and swap together reduce energy waste.

/ 08 — WHERE IT FITS

The same swap architecture extends to more new-energy scenarios.

Starting from agricultural spray drones, energy dispatch reaches further.

Agricultural spray drones

Automated swap and endurance

This case

Inspection drones

Long-duration patrols

EXTENDABLE

Logistics drones

High-frequency delivery resupply

EXTENDABLE

Electric motorcycles

Urban swap network

EXTENDABLE

Energy storage units

Smart battery dispatch

EXTENDABLE

Industrial robots

Automated energy resupply

EXTENDABLE

Want to know which approach fits your scenario?

Related cases

Other projects delivered by Wavesteam — AI, IoT, platform builds and enterprise software.

Engineering Delivery

If you're staring at a concreteengineering problem, we can skip the small talk and start from scope, integrations and milestones.

Business email

contact@boilingwater.cn

Office

10F, South Tower, Kingkey Yujing Times, Longgang District, Shenzhen

Automated drone battery swap, powered by IoT + BMS.

The constraint was never flight capability. It was energy resupply.

A battery flies briefly, then sits on the charger for ages

Manual swap is slow and carries safety risk

No real-time view of each battery's health

The drone operations loop is incomplete

We broke the old "stop and charge" pattern into five automated stages.

Low battery

Return to base

Battery swap

Battery check

Relaunch

We compared three resupply paths and chose intelligent automated swap.

Traditional manual charging

Manual swap with spare batteries

Intelligent automated swap system

Five modules — from the drone to the mini program — close one energy loop.

Drone auto-return on low battery

Swap station performs the swap

BMS for battery intelligence

IoT data platform sync

Unified mini-program dispatch

Four layers, bottom-up energy coordination

Core design principles

Payment, deposit, orders, swap, KYC, work orders — a complete business loop.

One mobile flow for battery and cabinet work orders

Every device, battery and work order — on one panel.

Six dimensions show what changed after launch.

Every battery, every swap and every device — visible by default.

Automated swap

Smart BMS

Live IoT sync

Greener energy use

Starting from agricultural spray drones, energy dispatch reaches further.

More case studies

AI Chinese Learning System

EV Charging & Battery Swap Platform

Smart Community Management

If you're staring at a concreteengineering problem, we can skip the small talk and start from scope, integrations and milestones.

Automated drone battery swap, powered by IoT + BMS.

The constraint was never flight capability. It was energy resupply.

A battery flies briefly, then sits on the charger for ages

Manual swap is slow and carries safety risk

No real-time view of each battery's health

The drone operations loop is incomplete

We broke the old "stop and charge" pattern into five automated stages.

Low battery

Return to base

Battery swap

Battery check

Relaunch

We compared three resupply paths and chose intelligent automated swap.

Traditional manual charging

Manual swap with spare batteries

Intelligent automated swap system

Five modules — from the drone to the mini program — close one energy loop.

Drone auto-return on low battery

Swap station performs the swap

BMS for battery intelligence

IoT data platform sync

Unified mini-program dispatch

Four layers, bottom-up energy coordination

Core design principles

Payment, deposit, orders, swap, KYC, work orders — a complete business loop.

One mobile flow for battery and cabinet work orders

Every device, battery and work order — on one panel.

Six dimensions show what changed after launch.

Every battery, every swap and every device — visible by default.

Automated swap

Smart BMS

Live IoT sync

Greener energy use

Starting from agricultural spray drones, energy dispatch reaches further.

More case studies

AI Chinese Learning System

EV Charging & Battery Swap Platform

Smart Community Management

If you're staring at a concreteengineering problem, we can skip the small talk and start from scope, integrations and milestones.