Application

MORE VOLUME,
LESS WEIGHT

Volta Structural Battery enables spacecraft to eliminate standard battery packs, freeing up mass and volume for higher-value payloads.

LET’S GET CONNECTED

LET’S GET CONNECTED

Payload
Limits

Conventional battery packs reduce room for hosted payloads.

REDUCED POWER
CAPACITY

Uncapable of meeting the most demanding mission requirements

Thermal
Risk

Standard Li-ion batteries increase fire and venting hazards during operation.

Payload
Limits

Conventional battery packs reduce room for hosted payloads.

REDUCED POWER
CAPACITY

Uncapable of meeting the most demanding mission requirements

Thermal
Risk

Standard Li-ion batteries increase fire and venting hazards during operation.

Payload
Limits

Conventional battery packs reduce room for hosted payloads.

REDUCED POWER
CAPACITY

Uncapable of meeting the most demanding mission requirements

Thermal
Risk

Standard Li-ion batteries increase fire and venting hazards during operation.

Weight
Penalty

Traditional batteries add mass and reduce range or payload.

Design
Constraints

Bulky packs limit placement flexibility and require structural reinforcements.

Maintenance
Risk

Complex cabling and battery compartments increase failure points and inspection time.

STRUCTURAL BATTERY

STRUCTURAL BATTERY
INTEGRATION CASE STUDIES

LET’S ANALYZE YOUR CASE

6U CubeSat Panel

Structural battery integrated into 1U, enabling more instruments without increasing mass.

Rover Chassis

Energy storage built into the rover’s structure, eliminating separate battery packs.

SmallSat Bus Wall

Side panel becomes energy storage, releasing space for payloads and reducing complexity.

External Payload
Panel

Power delivered directly from exposed satellite panel structures, reducing cabling and volume.

Internal
Volume

+30%

Gain space for payload by removing conventional battery modules.

Launch
Mass

-20%

Structural integration reduces protective enclosures and redundant supports.

power
output

+200%

Na-ion chemistry enables higher peak delivery for mission-critical loads.

Energy
Density

+60%

Optimized geometry and materials exceed traditional Li-ion satellite packs.

+30%

Internal
Volume

Gain space for payload by removing conventional battery modules.

-20%

Launch
Mass

Structural integration reduces protective enclosures and redundant supports.

+200%

power
output

Na-ion chemistry enables higher peak delivery for mission-critical loads.

+60%

Energy
Density

Optimized geometry and materials exceed traditional Li-ion satellite packs.

-25%

structural mass

Replace battery packs and casings with load-bearing panels.

+15%

flight range

Lighter structure extends distance or enables additional payload.

-40%

System Volume

Panelized format eliminates need for separate compartments.

+70%

Energy-to-Mass Ratio

Aerospace-grade carbon skins and optimized geometry boost overall efficiency.

ADVANTAGES FOR SPACE

structural
mass

-25%

Replace battery packs and casings with load-bearing panels.

flight
range

+15%

Lighter structure extends distance or enables additional payload.

System
Volume

-40%

Panelized format eliminates need for separate compartments.

Energy-to-Mass
Ratio

+70%

Aerospace-grade carbon skins and optimized geometry boost overall efficiency.

-25%

structural
mass

Replace battery packs and casings with load-bearing panels.

+15%

flight
range

Lighter structure extends distance or enables additional payload.

-40%

System
Volume

Panelized format eliminates need for separate compartments.

+70%

Energy-to-Mass
Ratio

Aerospace-grade carbon skins and optimized geometry boost overall efficiency.

-25%

structural mass

Replace battery packs and casings with load-bearing panels.

+15%

flight range

Lighter structure extends distance or enables additional payload.

-40%

System Volume

Panelized format eliminates need for separate compartments.

+70%

Energy-to-Mass Ratio

Aerospace-grade carbon skins and optimized geometry boost overall efficiency.

+30%

Internal Volume

Gain space for payload by removing conventional battery modules.

-20%

Launch Mass

Structural integration reduces protective enclosures and redundant supports.

+200%

power output

Na-ion chemistry enables higher peak delivery for mission-critical loads.

+60%

Energy Density

Optimized geometry and materials exceed traditional Li-ion satellite packs.

STEP BY STEP
PRODUCT ROADMAP

2025

2026

2027

Ground Validation

TRL5 system tested with control electronics in simulated environment.

Orbital Demo

TRL7/8 Cubesat integration for in-orbit demonstration.

Mission Deployment

TRL8/9 full-scale adoption in large satellites, rovers, and exploration systems.

2021

2022

2023

STEP BY STEP
PRODUCT ROADMAP

2021

2022

2023

Ground Validation

TRL5 system tested with control electronics in simulated environment.

Orbital Demo

TRL7/8 Cubesat integration for in-orbit demonstration.

Mission Deployment

TRL8/9 full-scale adoption in large satellites, rovers, and exploration systems.

2021

2022

2023

STEP BY STEP
PRODUCT ROADMAP

2021

2022

2023

Ground Validation

TRL5 system tested with control electronics in simulated environment.

Orbital Demo

TRL7/8 Cubesat integration for in-orbit demonstration.

Mission Deployment

TRL8/9 full-scale adoption in large satellites, rovers, and exploration systems.

2021

2022

2023

STEP BY STEP
PRODUCT ROADMAP

2021

2022

2023

2024

PHASE 1

Revolutionize energy storage by integrating battery technology into structural components.

PHASE 1

Revolutionize energy storage by integrating battery technology into structural components.

PHASE 1

Revolutionize energy storage by integrating battery technology into structural components.

PHASE 1

Revolutionize energy storage by integrating battery technology into structural components.

2021

2021

2021

2021

MAIN PARTNER

FREQUENT ASKED
QUESTIONS

Revolutionize energy storage by integrating battery technology into structural components.

ASK YOUR QUESTION

FREQUENT ASKED
QUESTIONS

GET VOLTA BATTERY

Revolutionize energy storage by integrating
battery technology into structural components.

HOW IS LOREM IPSUM 1?

HOW IS LOREM IPSUM 1?

HOW IS LOREM IPSUM 1?

HOW IS LOREM IPSUM 1?

Lorem ipsum 1

Revolutionize energy storage by integrating battery technology into structural components.

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Revolutionize energy storage by integrating battery technology into structural components.

Lorem ipsum 3

Revolutionize energy storage by integrating battery technology into structural components.

Lorem ipsum 4

Revolutionize energy storage by integrating battery technology into structural components.

Lorem ipsum 1

Revolutionize energy storage by integrating battery technology into structural components.

Lorem ipsum 2

Revolutionize energy storage by integrating battery technology into structural components.

Lorem ipsum 3

Revolutionize energy storage by integrating battery technology into structural components.

Lorem ipsum 4

Revolutionize energy storage by integrating battery technology into structural components.

Lorem ipsum 1

Revolutionize energy storage by integrating battery technology into structural components.

Lorem ipsum 2

Revolutionize energy storage by integrating battery technology into structural components.

Lorem ipsum 3

Revolutionize energy storage by integrating battery technology into structural components.

Lorem ipsum 4

Revolutionize energy storage by integrating battery technology into structural components.

FREQUENT ASKED
QUESTIONS

Revolutionize energy storage by integrating battery technology into structural components.

ASK YOUR QUESTION

FREQUENT ASKED
QUESTIONS

Revolutionize energy storage by integrating battery technology into structural components.

ASK YOUR QUESTION