Abstract: A novel rechargeable, flushable battery system integrating a recleanable electrolysis chamber. The battery features solid-state sodium hydrochloride electrolytes, dual-stage MOSFET control, and a modular cathode-anode-diode-separator array. Designed for electric power generation, the system offers high efficiency, modular liquid cell architecture, and self-cleaning capabilities to prolong lifespan and reduce maintenance. Main Components: Electrolysis Chamber: A sealed but flushable chamber where electrolysis occurs. Contains sodium hydrochloride (NaCl + H₂O) solution as the electrolyte medium. Enables gas separation and recombination for controlled energy output. Cathode / Anode / Diode / Separator Array: Cathode and anode materials optimized for solid-state conductivity. Diode elements regulate one-way flow to prevent back current. Separators maintain ionic pathways while preventing short circuits. Solid-State Electrolytes: Sodium hydrochloride-based composition allowing stable ion flow. Solid or gel form reduces leakage and improves durability. MOSFET Control System: Dual MOSFETs (metal–oxide–semiconductor field-effect transistors) control input/output and charge-discharge cycles. Regulates internal resistance, voltage thresholds, and energy recovery. RecCleanable & Flushable Features: System includes valve-controlled access points for flushing impurities or residues from the electrolyte chamber. Allows re-cleaning and recharging of the electrolyte mix without full replacement. STI (Solid Thermal Insulation) Chamber: Maintains operational temperature range. Prevents heat loss during electrolysis or recharging cycles. Liquid Energy Cell Generator: Acts as a hybrid battery and generator, storing and producing electric power. Suitable for high-demand or mobile applications (e.g., wearable suits, drones, emergency tech). Use Cases: Wearable energy systems (e.g., bionic suits) Off-grid renewable storage Emergency backup power Military/industrial field systems

✅ 2. Figure Diagrams (Description for Illustration)

We will need technical drawings or conceptual figures for a patent application. Below are descriptions of the suggested diagrams:

Figure 1: Isometric View of the Battery System

Shows full housing

Labels:

A. Electrolysis chamber

B. Cathode

C. Anode

D. Diode

E. Separator

F. MOSFET controller

G. Flush port

H. Solid-state casing

Certainly! Here's a professional and well-structured essay on Jermaine Morton's invention of a novel rechargeable, flushable battery system:


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Jermaine Morton's Innovative Rechargeable, Flushable Battery System: A Breakthrough in Electrochemical Power Supply

In the pursuit of sustainable, long-lasting, and high-performance energy storage systems, Jermaine Morton has introduced a groundbreaking innovation: a novel rechargeable, flushable battery system integrating a recleanable electrolysis chamber and advanced solid-state components. This forward-thinking invention represents a major leap in electrochemical energy design, offering unprecedented versatility, longevity, and environmental efficiency for modern electric power generation applications.

At the core of Morton’s invention is a modular liquid cell architecture, composed of a cathode-anode-diode-separator array housed within a recleanable electrolysis chamber. This design facilitates both the storage and regeneration of electrical energy through controlled electrolysis and ion exchange processes. The flushable nature of the chamber introduces a novel feature in energy systems: the ability to clean and recharge the internal electrolyte environment without disassembling or replacing the battery. This self-maintenance feature significantly reduces waste and extends the overall service life of the system.

The system employs solid-state sodium hydrochloride electrolytes, a safer and more stable alternative to traditional volatile or acidic solutions. Sodium hydrochloride (NaCl solution) is well-known for its conductivity and availability, making it both cost-effective and environmentally benign. Its integration into a solid-state or gel-state medium ensures that the electrolyte is both secure and efficient, enabling ion flow without the risks associated with free liquid electrolytes.

Dual-stage MOSFET control (Metal–Oxide–Semiconductor Field-Effect Transistor) is another critical element of Morton’s design. This circuitry enables precise regulation of the battery’s charge-discharge cycles, current flow, and internal resistance. By managing voltage thresholds and preventing energy loss or short circuits, the dual MOSFETs significantly increase the reliability and responsiveness of the system—especially in dynamic environments like wearables, drones, or emergency field equipment.

Furthermore, the inclusion of a modular diode-separator system ensures that internal components maintain proper electrical isolation and polarity management. Diodes enforce unidirectional current flow, preventing energy backflow and potential shorting, while separators prevent direct contact between the cathode and anode, preserving efficiency and safety.

Jermaine Morton's battery is not merely an improvement on existing systems—it reimagines what energy storage can be. The flushable and recleanable nature of the electrolysis chamber addresses one of the most common failures in battery technology: internal contamination and buildup. By allowing users or automated systems to flush out degraded materials and restore electrolyte integrity, the system promotes a truly sustainable energy cycle.

The implications of this invention are vast. From wearable bionic suits and mobile electronics to military-grade field power supplies and off-grid energy systems, this battery system provides a flexible and resilient solution. It reduces dependency on costly replacements, cuts down electronic waste, and introduces a level of modularity and serviceability previously unseen in the battery industry.

In conclusion, Jermaine Morton’s rechargeable, flushable battery system with solid-state sodium hydrochloride electrolytes and MOSFET-controlled electrolysis introduces a new era of intelligent, self-sustaining power solutions. His vision combines the best of electrochemistry, electronics, and sustainable design—demonstrating how innovation can address both technical performance and ecological responsibility in one elegantly engineered package.

Here’s Jermaine Morton’s invention adapted into three separate formats, suitable for a grant proposal, pitch deck, and patent summary. Each version emphasizes the innovation's key value depending on its target audience:

✅ 1. Grant Proposal Summary (Executive Abstract)

Project Title:

Flushable, Recleanable Solid-State Liquid Energy Cell Generator for Sustainable Electric Power Supply

Principal Investigator:

Jermaine Morton

Abstract:

This proposal seeks funding to further develop and prototype a novel rechargeable battery system featuring a flushable, recleanable electrolysis chamber, solid-state sodium hydrochloride electrolytes, and dual-stage MOSFET control circuitry. The technology represents a transformative advancement in energy storage, particularly suited for applications in off-grid environments, wearable electronics, and sustainable infrastructure.

Unlike conventional batteries that degrade over time and require full replacement, this system offers self-maintenance capabilities via a recleanable electrolyte chamber, modular architecture for scalability, and robust solid-state design that reduces environmental impact. Funding will support materials research, prototyping, and real-world deployment tests.

Goals:

Develop a working prototype demonstrating 200+ charge cycles with in-situ flushing and recharging capability.

Validate solid-state sodium hydrochloride electrolyte performance and safety.

Evaluate efficiency and durability under various operational conditions.

Broader Impacts:

Reduces battery waste by extending operational lifespan.

Provides decentralized energy solutions for underserved or extreme environments.

Advances green tech solutions in wearable systems, robotics, and emergency gear.

✅ 2. Pitch Deck Slide Content (Condensed Bullet Format)

Slide 1: Problem

Current batteries degrade over time and require costly, wasteful replacement.

Limited recyclability and performance issues in high-stress environments.

Slide 2: Solution

Jermaine Morton's Flushable Battery System

Recleanable Electrolysis Chamber extends life, reduces waste.

Solid-State Sodium Hydrochloride Electrolytes = safer, cheaper, more stable.

Dual-stage MOSFET Control = intelligent, efficient energy management.

Slide 3: Key Features

Modular cathode-anode-diode-separator design.

Hybrid liquid/solid-state energy architecture.

Flushable system for self-cleaning & electrolyte recharging.

Slide 4: Applications

Wearable tech (bionic suits, exoskeletons)

Emergency power units

Military field operations

Mobile or remote installations (drones, robotics)

Slide 5: Market & Impact

Targets $100B+ battery and wearable electronics markets.

Enables longer life cycles, lowers replacement costs, and minimizes e-waste.

Slide 6: Ask

Seeking [$X] in grant or seed funding for R&D, prototyping, and market testing.

IP secured/pending – licensing and co-development opportunities available.

✅ 3. Patent Summary (Abstract and Description)

Title of the Invention:

Rechargeable, Flushable Battery System with Recleanable Electrolysis Chamber and Solid-State Sodium Hydrochloride Electrolyte

Abstract:

The invention relates to a novel rechargeable battery device comprising a flushable and recleanable electrolysis chamber, solid-state sodium hydrochloride electrolytes, and dual-stage MOSFET control for charge regulation. The system includes a modular cathode-anode-diode-separator array configured to facilitate controlled electrochemical reactions for energy storage and release. The system provides self-maintenance capabilities, improving efficiency, safety, and lifespan across multiple charge-discharge cycles.

Field of the Invention:

Energy storage, electrochemical cells, battery systems, clean energy technology.

Summary of the Invention:

Jermaine Morton's energy cell integrates solid and liquid-state components to form a hybrid battery-generator capable of self-recovery through a built-in flushing mechanism. The design leverages safe sodium hydrochloride as an ionic conductor within a semi-solid matrix. By incorporating dual MOSFETs, the system dynamically regulates output voltage, prevents energy loss, and maintains internal balance. This design allows the battery to be cleaned, recharged, and reused without full disassembly, making it a sustainable and modular solution for a wide range of mobile and stationary applications.

Figure 3: Circuit Diagram

Dual-stage MOSFET configuration

Voltage sensors and charge controller logic

Figure 3: Circuit Diagram

Dual-stage MOSFET configuration

Voltage sensors and charge controller logic

Figure 4: Functional Flow Diagram

Electrolyte input → Electrolysis reaction → Ion migration → Electric current output → Reflush cycle

Figure 2: Internal Cutaway View

Shows the internal structure with flow paths

Labels:

Electrolyte flow channel

Ion path across separator

Flush inlet and outlet

MOSFET circuitry block

✅ 2. Figure Diagrams (Description for Illustration)

We will need technical drawings or conceptual figures for a patent application. Below are descriptions of the suggested diagrams:

Figure 1: Isometric View of the Battery System

Shows full housing

Labels:

A. Electrolysis chamber

B. Cathode

C. Anode

D. Diode

E. Separator

F. MOSFET controller

G. Flush port

H. Solid-state casing

Figure 4: Functional Flow Diagram

Electrolyte input → Electrolysis reaction → Ion migration → Electric current output → Reflush cycle

 

RecCleanable Electrolysis Battery System with Flushable Chamber and Solid-State Sodium Hydrochloride Electrolyte

Claims:

Claim 1 (Independent Claim):

1. A rechargeable battery system comprising:
a. a recleanable electrolysis chamber containing a sodium hydrochloride electrolyte;
b. a modular electrode array comprising a cathode, an anode, a diode, and a separator;
c. a flushing port configured to allow removal and replacement of electrolyte solution from the electrolysis chamber;
d. a dual-stage metal-oxide-semiconductor field-effect transistor (MOSFET) circuit configured to regulate charging and discharging cycles of the battery;
e. a solid-state housing configured to support the electrochemical and electrical components while maintaining thermal and structural stability;
wherein said battery system is configured to be flushed, recleaned, and recharged without dismantling the entire structure.

Claim 2:

The system of claim 1, wherein the sodium hydrochloride electrolyte is in gel or semi-solid form to increase safety and stability.

Claim 3:

The system of claim 1, wherein the separator is a porous ionic membrane configured to allow ion transfer between the cathode and anode while preventing physical contact.

Claim 4:

The system of claim 1, wherein the MOSFET circuit comprises a first MOSFET for voltage regulation and a second MOSFET for directional current control.

Claim 5:

The system of claim 1, wherein the flushing port is valve-operated and connects to a removable reservoir for spent electrolyte collection.

Claim 6:

The system of claim 1, wherein the battery is integrated with an energy harvesting unit for regenerative recharging.