S.B.G & CIG Ceramic Solid State Batteries
S.B.G & CIG Ceramic Solid State Batteries
For January 2026. Pre-orders now in 2025
SOLID STATE AUTOMOTIVE BATTERIES
While we are mainly using a Liquid, Gel or Powder State for our 4 Main 7 Tablet Batteries we do have a Solid State option already
Final product dimensions are 7" X 3" X3"
We utilize the same 3" X 3" square base for the Standard connection which is adjustable for lengths with less material
We utilize a self-recharger by M.D.E - C/M perfected by Dr Sydney Nicola Bennett for break even or close to repurposed Lithium for Unlimited Range
RANGE. UNLIMITED + INSTANT SELF-RECHARGE
Self-Recharging Unlimited Range Batteries 1.75-7 kWh 7 Tablet designs sold at $374.99-$1499.99 from Lithim or equivalent bought at $115-120 per kWh
A rest cycle & 20 down depleted & 80 up Switch-Back controls void early degradationwith 7 Tablets
Capped Tiered Metering if Metered at $4.50 Canadian dollars per 400 Km or less & or $1-2 Cents per Km or Mile
DETAILS
Using the M.D.E - C/M Scale 3 on the Standard 7 Tablet Switch-Back
https://cmbennettbrothers.blogspot.com/2025/08/s_20.html
SIZE COMPARISONS
M.D.E - C/M 1.75 7 Tablet Switch-Back
We devide material used from the 7 kWh Battery by 4 to acheive
Effective Battery Size per 7 Tablets on a 1.75 kWh Switch-Back equals:
Minimal size required:
Length of 0.55 cm
Width of 0.38 cm
Height of 0.9 cm
Choice in size: (material wrapped)
Length of 0.75 cm
Width of 0.5 cm
Height of 0.25 cm
Maxell PSB401010H Solid State Lithium
Length of 1.05 cm
Width of 1.05 cm
Height of 0.4 cm
M.D.E - C/M
1-2-3 X 7 then a 1 cm spacing
0.5 x 7 + 7 equaling 10.5 cm
10.5cm or 4.14" fitting into a 7" exterior casing with spacing for Switch-Back mechanicals, wiring & conductive materials then corkboard wrapping
Final product dimensions are 7" X 3" X3"
We utilize the same 3" X 3" square base for the Standard connection which is adjustable for lengths with less material
SCALING DOWN TO 7 FROM 100 & THEN SPLITTING IN 7
100 kWh to 7 kWh. Scale 14.2
218 cm length to 15.35cm to 2.19 cm
150 cm width to 10.56 cm to 1.5 cm
33 cm height to 2.5 cm to 0.36 cm
Effective Battery Size per 7 Tablets on a 7 kWh Switch-Back equals:
Minimal size required:
Length of 2.19 cm
Width of 1.5 cm
Height of 0.36 cm
Choice in size: (material wrapped)
Length of 3 cm
Width of 2 cm
Height of 1 cm
1-2-3 X 7 then a 1 cm spacing
21 cm + 7 cm equaling 28 cm
28cm or 11.3" fitting into a 14" exterior casing with spacing for Switch-Back mechanicals, wiring & conductive materials then corkboard wrapping
Final product dimensions are 14" X 3" X3"
Maxell PSB401010H Solid State Lithium
Lenth of 10.5 millimetres = 1.05 centimetres
Height of 10.5 millimetres = 1.05 centimetres
Width of 4 millimetres = 0.4 centimetre
Voltage (V)2.6
Current (mA)4.0
Temperature (deg. C)-20 to +115
End Voltage (V)1.0
Lower limit voltage (V)0
Maximum current (mA)∗430.0
Temperature (deg. C)-50 to +125
Nominal Voltage (V)2.3
Nominal Capacity (mAh)∗58.0
Rated Capacity (mAh)∗67.0
Features Surface mountable
OUR REGULAR STANDARD BATTERY AT M.D.E - C/M
KWh = Minimum Km to Maximum Km
Standard
7 = 2.25 - 4.5 is 14" X 3" X 3"
Weight 110lbs
Price: $1499.99 Canadian
Scale 1
3.5 = 1.125 - 2.25 is 7" X 1.5" X 1.5"
Weight 55lbs
Price: $749.99 Canadian
Scale 2
2.34 = 0.75 - 1.5 is 4.67" X 1" X 1"
Weight 36.67lbs
Price: $499.99 Canadian
Scale 3
1.75 = 0.56 - 1.125 is 3.5" X 0.75" X 0.75"
Weight 27.5lbs
SOLID STATE - INDUSTRY EFFORTS
Standards
Ceramic-packaged all-solid-state battery packs
Ceramic-packaged all-solid-state batteries utilize a solid, ceramic-based structure for enhanced safety, reliability, and performance, especially at high temperatures. While initially limited to smaller, niche applications due to manufacturing challenges with scaling ceramic materials, companies like Maxell, Kyocera, and TDK are developing them for IoT devices and industrial equipment with long lifespans and harsh-environment resistance. These batteries replace liquid electrolytes with solid ceramic ones, boosting energy density and lifespan, and are being explored for future use in electric vehicles.
Key Features & Benefits
• Enhanced Safety:
Replacing flammable liquid electrolytes with solid ceramic materials significantly improves safety and reliability.
• High-Temperature Resistance:
Ceramic packaging and the solid electrolyte provide excellent heat resistance, allowing for usage in high-temperature industrial settings.
• Longer Lifespan:
The robust ceramic structure and solid electrolyte contribute to a longer operational life, reducing maintenance needs.
• High Energy Density:
Advancements in solid-state materials are increasing energy density, enabling smaller devices to pack more power for longer run times.
• Environmental Resistance:
The ceramic encapsulation protects the battery from harsh environmental conditions, making it suitable for demanding applications.
Applications
• Industrial Equipment:
Maxell's ceramic-packaged batteries are used in industrial robots and PLCs (programmable logic controllers) to reduce downtime from battery replacements.
• Internet of Things (IoT) Devices:
The small size, safety, and longevity make them ideal for various IoT applications and wearable devices like hearing aids and smartwatches.
• Electric Vehicles (EVs):
While still a significant engineering challenge, the performance benefits make them a target for future integration into electric vehicle battery packs.
Companies & Technology
• TDK:
Developed the world's first all-ceramic, solid-state battery (CeraCharge®) and continues to advance materials with 100x higher energy density.
• Maxell:
Manufactures large-capacity, ceramic-packaged all-solid-state batteries with long life and high-temperature resistance for industrial applications.
• Kyocera:
Provides ceramic packaging solutions to increase the usage life and withstand harsh environments for small batteries used in emerging fields.
• Sakuu:
Uses innovative printing technology to produce solid-state batteries with customizable packages and collaborates with ceramic material suppliers like NGK Spark Plugs.
CERAMIC-PACKAGED ALL.SOLOD STATR BATTERIES
Sizing a ceramic-packaged all-solid-state battery pack depends on the application's energy and power requirements, as these packs are modular and can be connected in series and parallel to achieve desired voltage and capacity. Factors like target voltage, usable capacity, operating temperature, and size constraints are crucial. You must also consider the cell's specific energy density and internal resistance to ensure the pack meets the application's demands for size, weight, and performance.
1. Define Your Application's Needs
• Energy Requirements (Watt-hours):
Determine the total energy your application needs to store, which is a combination of voltage and capacity (Wh = V x Ah).
• Power Requirements (Watts/Amps):
Identify the maximum current and voltage the battery pack must deliver to operate your device.
• Operating Conditions:
Note the temperature range your device will operate in, as ceramic-packaged batteries offer wide operating temperature ranges, but capacity can be affected.
• Physical Constraints:
Consider the available space and weight limits for the battery pack in your device.
2. Select a Ceramic-Packaged All-Solid-State Battery
• Manufacturer & Model:
Choose a manufacturer like Maxell or TDK that offers ceramic-packaged, surface-mountable all-solid-state batteries.
• Individual Cell Specs:
Note the nominal voltage, capacity (mAh or μAh), and maximum current of the individual cells.
• Energy Density:
Consider the energy density (Wh/kg or Wh/L) to understand how much energy can be stored in a given size and weight.
3. Design the Pack Configuration
• Series Connection: Connect cells in series to increase the overall voltage.
• Parallel Connection: Connect cells in parallel to increase the overall capacity.
• Combination: A combination of series and parallel connections allows you to achieve the specific voltage and capacity required for your application.
4. Calculate and Verify
• Total Voltage:
Sum the nominal voltages of the cells connected in series to meet your voltage requirement.
• Total Capacity:
Sum the capacities of the cells connected in parallel to meet your capacity requirement.
• Physical Size:
Estimate the total dimensions by summing the individual cell dimensions and considering the necessary structural support for the pack.
• Safety and Reliability:
The solid-state ceramic design offers inherent safety advantages, such as a reduced risk of fire and leakage.
Example: The TDK CeraCharge®
• The TDK CeraCharge is an SMD (Surface Mount Device) battery, allowing easy placement on circuit boards and reflow soldering, which is key to reducing production costs.
• A single CeraCharge cell has a 1.5V rating and a 100μAh capacity.
• To create a higher voltage pack, you can connect multiple CeraCharge cells in series.
• To increase capacity, you can connect cells in parallel.
• For example, connecting two CeraCharge cells in series will provide a 3.0V output, while connecting them in parallel will provide a 200μAh capacity at 1.5V.
Sizing a ceramic-packaged all-solid-state battery (ASSB) pack by kWh involves a direct calculation of Energy (kWh) = Nominal Voltage (V) x Nominal Capacity (Ah) / 1000, but the key factor for ASSBs is their high energy density potential (e.g., 300-800 Wh/kg for thin-film types), which means a smaller or lighter pack can achieve the same kWh capacity as a traditional lithium-ion battery, allowing for greater range or smaller devices.
Key Factors for Sizing
• 1. Nominal Voltage and Capacity:
Like any battery, the total kWh is calculated from the nominal voltage of the cells and their nominal capacity in Ampere-hours (Ah).
• 2. Energy Density (Wh/kg or Wh/L):
Ceramic-packaged ASSBs promise higher energy density than current lithium-ion batteries, which can increase the kWh output for a given weight or volume.
• 3. Specific Applications:
The required kWh capacity for an ASSB pack will depend on the intended application, such as an electric vehicle (EV) or a portable electronic device.
How it's Calculated
• Formula: kWh = (Nominal Voltage * Nominal Capacity in Ah) / 1000.
• Example: If a ceramic ASSB cell has a nominal voltage of 3.7V and a nominal capacity of 20 Ah, a single cell would provide 74 Wh (0.074 kWh).
Advantages of Ceramic-Packaged ASSBs
• Higher Energy Density:
This means a given kWh capacity can be achieved with a smaller and lighter pack.
• Enhanced Safety:
Ceramic packaging and the solid electrolyte inherently reduce the risks of fire and leakage compared to traditional lithium-ion batteries.
• Longer Lifespan:
ASSBs can offer greater durability, maintaining their capacity over more charge cycles than conventional batteries.
Example in Context
• A 100 kWh EV battery pack made with traditional lithium-ion technology might weigh around 1,000 pounds.
• A solid-state equivalent, due to its higher energy density (e.g., 3x higher), could provide the same 100 kWh with a weight of only about 333 pounds.
Therefore, for sizing a ceramic-packaged ASSB, you would still perform the basic kWh calculation, but the high energy density would significantly influence the required physical size and weight for that given kWh output.
INDUSTRY STANDARD IN USE IN 2025
Not for Automotive Applications
The Maxell PSB401010H is not rated in kWh but as a rechargeable battery with a specific capacity and voltage. While it features high capacity and output, its main advantage lies in its long life, high heat resistance, and safety for use in harsh industrial and high-temperature environments. The required capacity in Watt-hours (kWh) would depend on the specific application's voltage and current draw, which is not provided in the given search results, but it is available for use in power backup modules and industrial robots.
Key features of the PSB401010H:
• High Heat Resistance: The ceramic package and solid-state nature provide excellent resistance to high temperatures.
• Long Battery Life: Expected to last for over 10 years, significantly reducing maintenance and replacement needs in industrial equipment.
• High Capacity and High Output: Capable of providing significant power for demanding applications.
• High Safety: Demonstrates high safety in tests, with no ignition or smoke generation.
• Surface Mountable: Can be mounted via reflow soldering, making it suitable for various industrial manufacturing processes.
How it might be used to determine kWh:
• Consult the Datasheet:
For exact specifications, including its voltage and capacity, refer to the official datasheet provided by Maxell. The datasheet contains the technical details needed to calculate its energy capacity in Watt-hours (Wh), which can be converted to kilowatt-hours (kWh) by dividing by 1,000.
• Consider Application Voltage:
Since the total energy (kWh) is determined by multiplying voltage by Amp-hours and dividing by 1,000, the specific voltage requirement of your application is essential to determining its power-to-capacity.
FIREPROOF BOX FOR BATTERIES
M.D.E - C/M utilizes a fire resistant box encasing Batteries & a Fire Extinguisher which comes with a corkboard wrap interior casing for automotive & other treatments
Connector for Batteries is within & connected outward to the Recharger or Wind-Tunnel if not combination then digital aspects for the Energy Generator for Use & Storage
To "fireproof" a box, you must first understand that no box is truly fireproof, but rather fire-resistant for a certain duration and temperature. The most effective method is to purchase a certified fire-rated safe with a UL or ETL mark. For additional protection, place a fireproof box or document bag inside a larger fireproof safe, store it on the lowest level of your home, or use a bank safe deposit box.
Considerations Before Buying a Safe
• Temperature & Time Rating:
Safes are rated to withstand specific temperatures for specific lengths of time (e.g., 30-60 minutes at 1150°F).
• Certifications:
Look for safes with UL (Underwriter's Laboratory) or ETL (Intertek) marks, indicating their fire and water resistance ratings.
• Interior vs. Exterior:
A fire-resistant envelope on a security safe offers less protection than a completely fireproof safe.
• Water Resistance:
Many fire-rated safes also offer water protection, a critical feature to consider for a complete storage solution.
• Weight:
High-quality fire-resistant products are often very heavy.
Methods to Enhance Protection
• 1. Use a Certified Fireproof Safe:
Purchase a safe rated by UL or ETL for fire and water resistance and place important documents inside.
• 2. Use a "Belt and Suspenders" Approach:
Put a smaller, fire-rated document bag or box inside a larger fireproof safe for extra security.
• 3. Secure Placement:
Store your fireproof box or safe on the lowest level of your home to minimize potential damage from falling debris in a fire.
• 4. Utilize a Bank Safe Deposit Box:
For extremely critical documents, a bank's safe deposit box is an excellent, highly secure option.
Why "Fireproof" Isn't Absolute
• Limited Protection: While effective, even the best safes have limits and can be compromised in a major house fire that lasts for an extended period.
• Extreme Heat: Wildfires can reach temperatures that would melt most fireproof safes.
• Other Hazards: Fireproof protection does not automatically include protection from flood or other water damage.
A NEW BATTERY STORED
Some people may want to retain an extra Battery Box with Fire Extinguisher alongside First Aid Kit then if Box 1 is damaged rather than replace a Battery you can replace the box with Battery connector within in the event the connector is damaged in the rare event
"Trapping a fire" can mean several things, from physically confining a fire to a small area to setting a magical trap that explodes when triggered, or even a mechanical component in an industrial system designed to stop a fire. In a general sense, confining a fire by closing doors and windows is a key strategy to slow its spread and allow for safe evacuation.
Here are the different interpretations of "trapping a fire":
• Confining a fire to slow its spread:
During a fire, the "R.A.C.E." (Rescue, Alarm, Contain, Evacuate) procedure includes a "Contain" step. You can close doors and windows to trap a fire within a room or area, slowing its progress and potentially preventing it from spreading further.
• Mechanical Fire Traps:
These are actual devices, like the SMART PRO 150 Flame Trap from Greenpipe, that are designed to catch spilled liquids and restrict the area of a fire, or components in systems like the one by Fagus-GreCon that close a transport duct to prevent fire from spreading through it.
• Magical Fire Traps:
In fantasy contexts, a "fire trap" is often a spell or magical ward placed on an object that causes a fiery explosion when the object is opened by someone other than the caster.
• Gaming Traps:
In games like NetHack, "fire traps" are hidden floor tiles that detonate with fire, causing damage to anyone stepping on them.
• The Concept of a "Fire Trap":
This could also refer to a structure or situation that is prone to catching and spreading fire, such as a building with flammable materials.
In an emergency, confining the fire by closing doors and windows is a useful tactic to help control the fire's spread and protect the rest of the building.
PERPETUAL MOTION ACHEIVED
Fully renewable perpetual motion achieved by Dr Sydney Nicola Bennett 1996-2001 & international industry updates in innovations for 2024-2025
The Piston-Punch Wind-Tunnel or PZ Taps Kinetic - Piezoelectric Rechargers paired to an EV Electric & or Air if not Hybrid Motor without or with a 7 Tablet Battery with Emergency Safety System work in Motion & Stationary Energy of all sizes from a Wrist Watch, Glasses, Mobile Phone & Automobile to large scale Heavy Mining Vehicles
Vertical vast Lithium Growing Plants complimenting Earth finds & repurposed efforts increasing supply to a controlled renewable as we are
WRAPPING CORKBOARD IN SMALL BATTERIES
Corkboard
24 X 36 sheets are $155 Canadian yet we can do under $110
Bulletin Cork
18 X 24 sheets are $20-40
We use this for the EV Motor casings as well with ventilation
Catalogues
Build Instructions
1. Battery Wrapping
Material segregation. Placement in frame Testing
Additive materials & connectors - wired
Additive material - mechanical
Exterior wrapping
PROCESS
Point A - B 360 degree Cycle process
Design + prototype result
Raw or repurposed material if not grown
Cutting for part components
Assembly
Testing & packaging
Battery Material Charging Monitor for a Digital App
Battery Switch Interface for Digital AppMechanical Fire Extinguisher routing for Digital App
S.B.G & CIG
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