WO2024170018A1 - Electrical generator - Google Patents

Abstract

- The new storage battery generates a continuous current by a continuous one-way electrochemical reaction. - The reaction is supplied continuously with materials to maintain the reaction - We use the right chemicals. When they react with one another to form a precipitate and a gas, they are separated by the cleaner and disposed of, and the gas is released. - Mini-generator: POWER FOR EVERYWAYS GENERATOR N*LINH I - take an alkali storage battery - an alkali battery is a typical example - which meets the fundamental criteria of PFEG N*LINH I. - Large generator PFEG N*LINH II - uses electrodes which are mesh boxes containing materials which are passed continuously through a pipeline system.

Description

ELECTRIC GENERATOR

POWER FOR EVERYWAYS GENERATOR N*LINH

1. Current technical status:

Batteries & accumulators for electric vehicles today are mostly rechargeable batteries & accumulators (except for a few fuel cells - which are similar to combustion engines): Based on the principle of the favorable electrochemical reaction.- Inversely (2-way) it leads to the situation as:

- Battery or accumulator has only 1 fixed electrical capacity, limited to a fixed volume and a fixed mass of material, equal to the vehicle weight. The materials to generate the one-way electrochemical reaction (discharge) run out, it is imperative to return to the reverse reaction (charge)! Like the end of a tunnel with no way out! The amount of material is always limited and unchanged, it only changes from one form of connection to another and vice versa to give and receive electrons to generate electricity and is only closed in the battery and accumulator system, so very limited range of electric vehicles.

- Battery or accumulator has a state of freedom due to an electrochemical 2-way reaction - self-balancing of the reaction. Newer rechargeable batteries & accumulators usually use materials such as Li, Ni, Fe ... with high chemical activity, the resulting compounds are often difficult to precipitate in solid form, or in the form of hydrates (swallowed water) or suspension and usually have a high degree of self-discharge (two-way reaction). - The volume of battery is very large, which is equivalent to a huge weight of 300 - 1000 kg (20% of normal vehicle weight) to be able to store enough energy at a preset distance. Instead of just carrying the amount of chemicals that create electrochemical reactions to generate electricity, we have to carry the whole system and accessories, covers... which makes the battery weight very large and causes energy loss. Battery.

- And the most annoying thing is the CHARGE service when battery & battery are empty: Where is the charging station? Charging equipment of each brand? Power source, number of people charging at the same time ... and above all charging time:

+ Slow loading customers have no time

+ Fast charging requires a separate device and power source, battery type... and greatly impacts the lifespan of the battery and charging station!

These criteria represent a huge obstacle to the competition and development of any electric vehicle company. Huge capital to cover the charging station not only for equipment, but also location, personnel ... as well as vehicle purpose, electrification and the current GREEN trend.

We invent new generation batteries with new working principle and new structure to perfectly overcome the above-described obstacles of the current PIN & batteries for electric vehicles. In fact, it is a generator that uses common, inexpensive chemicals... but in particular, they can achieve electrochemical oxidation and Generate reduction reaction in one direction - COMPLETELY! This allows them to generate electricity CONTINUOUSLY - UNLIMITED - UNLIMITED TRAVEL DISTANCE... in contrast to current batteries & accumulators:

* Material level - Instead of charging,

* Separator and gas separation (for reuse) of electrochemical reaction - Instead of STORAGE IN THE BATTERY & ACCURACY TO REJECT electrochemical reaction during charging or potentially dangerous explosion hazard like most batteries today.

2. Technical nature of the invention.

The new Accu is an instrument system with a NEW process: generates an electrochemical redox reaction. This reaction has the following properties:

- 1-way, full and continuous reaction, instead of 2-way reaction - REACTION when CHARGING as with most batteries and accumulators in use today! Of course, the reaction must meet the following necessary and sufficient conditions:

- Reaction produces a precipitate or gas ... and is

- Disconnect the separator or gas.

- FULL and CONTINUOUS FEEDING of materials from outside instead of charging like current BATTERY & rechargeable battery.

- Generates electricity continuously - infinitely, because with only a small amount of materials (1 kg for 500 km instead of 37.5 kg of petrol or 7,104 batteries with a weight of 500 kg ...) instead of current-limited capacity of any kind such as PIN or Accu (rechargeable or non-rechargeable - disposable) are popular today.

* This is the basic principle and the difference of the NEW generation BATTERY & Accu compared to current Battery & Accu. We call the new generation battery & accumulator as a generator (continuity): POWER FOR EVERYWAYS GENERATOR N*LINH! Especially for electric cars - a currently very hot field and NEW energy sources from the inexpensive, universal raw materials of the chemical industry!

To create a one-way electrochemical reaction (complete reaction) with a separator or a gas, we need to use:

- Suitable starting materials for suitable electrochemical oxidation-reduction reactions and

- Suitable solvents, in particular:

- Catalysts, separators and gases suitable for each reaction.

- We use special equipment to deliver materials and

- Filters for the separation of precipitation and

- Duct system for exhaust gas or exhaust gas absorption.

3. Detailed description of the invention.

With the above mentioned fundamental NEW design and

Operating principles, this is the prerequisite for a new technological process for all NEW generation batteries and accumulators with different compatible materials for next generation electric vehicles. Especially in areas rich in raw materials, we can build a new type of electrochemical energy generation plant on a corresponding large scale.

Let's take an example of a new working principle with 1 new Mn-Zn alkaline battery, because of the battery type (currently alkaline - alkaline batteries are very popular, because of the relatively low price, user-friendly compared to other types of batteries), meets most of the necessary and sufficient conditions of POWER FOR EVERYWAYS GENERATOR N*LINH as follows.

We already know that there are many advantages to conventional alkaline batteries:

- Very high energy density: 350 Wh/I.

- High power level: 2.8 Ah.

- Internal resistance: 0.5 Ohm.

- The potential difference between the 2 electrodes is high ~ 1.5 V.

* Special battery & accumulator of the NEW generation: POWER FOR EVERYWAYS GENERATOR N*LINH (abbreviation: PFEG N*LINH) has many outstanding advantages:

- They are safe and environmentally friendly. Chemical waste can be recycled cost-effectively through industrial chemical processes.

- Does not contain or produce very toxic substances such as Pb, Hg, Co, Br..., - Difficult to store (H_2 is the lightest gas that is easily lost), bulky, expensive storage devices such as fuel cells: H_2, methanol...

Especially fuel cells have a low efficiency (twice the percentage deducted when: producing materials and reacting to produce electricity) because to produce hydrogen, methanol ... requires a large source of electrical energy (electricity, fertilizer) with complex technology, high conservation equipment, high cost and great impact on the environment, a vicious circle?

New Accu has a common and abundant natural material source, easy to use Mn0_2, Zn, industrially produced with reasonable prices (see next section), particularly convenient and easy to use.

The basic equation of the electrochemical reaction of Mn-Zn alkaline batteries (according to www Chemie, de) is as follows:

Zn + 2MnO_2 + H_2O -> ZnO |(Kt) + 2MnO(OH) |(Kt). (I)

If you use a positive electrode made of high purity Zn and control the concentration of the alkaline KOH solvent so that it does not exceed the allowable threshold, the side effects of H_2 gas release are minimized as follows:

Zn + 2H_2O + 2OH ^A - = Zn(OH)_4 ^A {2-} + H_2 |(Bh) . (II)

Abbreviations in equations (I) & (II):

- Kt: separator, - Bh: Volatile gas

New battery with reservoir for concentrated KOH electrolyte solution.

Positive electrode is Mn0_2 plate mixed with additives (possibly in other forms)

The negative electrode is a pure Zn sheet (possibly in other forms). See Fig. 1.

From the balanced reaction equation (I) we can easily calculate the consumption of input materials and output precipitants with the following parameters:

- 1A = 1C = 6.2415 x 10 ^A 18/se ^A -1 (electron).

- 1 mole = 6.0221 x 10 ^A 23 atoms (or molecules)

- Atomgram Zn = 65.37 grams

- Molecular gram MnO_2 = 86.9368 grams

- Molecular gram ZnO = 81.3699 grams

- MolecularLet's take an example of an electric car with an average power consumption of about:

- 20 kWh per 100 km.

- Voltage: 400 V and the power transmitted in Ampere h is:

- 50 Ah for 100 km.

Of the technical parameters mentioned above, we are surprised by the extremely low material consumption: for a distance of 100 km.

+ 60,952 grams Zn and

+ 162.056 grams MnO_2.

And the amount of precipitation produced is:

+ 75,145 grams of ZnO and

+ 163.937 grams MnO(OH).

Simultaneously with a small amount of: Zn(OH)_4 precipitates and gas H_2 is released, which are controlled when used with a pure raw material source and an appropriate solvent concentration.

This shows us that using a PIN or battery nowadays is extremely wasteful, since the amounts of replacement materials and accompanying accessories such as PIN cover, solvent or filler make the weight of the PIN and battery too large to compare with the actual consumption. grams MnO(OH) = 87.946 grams.

4. New Electrochemical Mini Generator:: POWER FOR EVERYWAYS GENERATOR N*LINH I (PFEG N*LINH I). With the above power consumption of electric cars by oxidation/reduction for 100km: We have a model No.1: "ELECTRONIC MINI GENERATOR" POWER FOR EVERYWAYS GENERATOR N*LINH I first on The world uses the oxidation-reduction reactions of common materials to provide CONTINUOUS power to electric vehicles and compatible devices. See Fig.1 and Fig.2. They have special structures and connections, we can design with many different styles based on this structure and activity principle.

POWER FOR EVERYWAYS GENERATOR N*LINH I, Model 1 includes:

- The anode is made of 99.89% pure Zn: 113.88 g/sheet, it is attached to the platinum coated titanium rods to prevent corrosion and leakage.

- The cathode is made of MnO_2 and some additives to increase reactivity and conduct electricity such as: 78.468 g/sheet. it is also attached to the platinum coated titanium rods.

- The solvent (LIQ) is concentrated KOH with addition of NiOH... as a catalyst for the oxidation-reduction reaction.

- There is a partition between a pair of electrodes as an independent battery unit.

The structure and main components of Accu are similar to traditional alkaline dry batteries, they generate self-reaction when connected to the circuit (one-way reaction always occurs when there is a precipitate or gas). The only difference is that we use KOH solvent in the form of a liquid solution to easily separate and exhale the precipitator.

The oxidation/reduction takes place at the electrodes as described above, namely:

- Anode: The oxidation reaction transforms metallic Zn into precipitated

2-chloro-4-methyl ... - At the same time, the reduction reaction converts Mn0_2 into MnO(OH) precipitate.

The side reaction produces a very small amount of Mn(OH)_2 precipitated and H_2 gaseous, we can vent the gas through a separate exhaust pipe or adsorb or collect it with the large system.

For precipitates, we use a separate filter to separate them. Usually, for the current batteries and battery types for electric vehicles, after the Lemongrass or Recharge reaction, the following compounds all remain in the mixture in the solvent and stick to the electrodes. When the following reactants fill the solvent and electrodes, the potential difference between the two plates drops to the limit level, the process is finished! then it is imperative that battery & battery be charged, with rechargeable battery and PIN or discarded with disposable batteries (most batteries used for small devices today).

Totally different from this practice, with the new POWER FOR EVERYWAYS GENERATOR N*LINH I we have an automated system for separating precipitates from solvents and electrode plates by using a special chemical cleaner with corrosion-resistant, leak-free filter. We collect separator with solvent and filter separator separately from solvent. The clean solvent is pumped back to the accu tank and again receives the separator.... According to the closed circuit and as a result the separator is always filtered out and the hydrogen gas is released through separate lines. We always create a precipitating and breathable clean solvent, so that the reaction continues continuously, generates unlimited power, remains strong, while old-style accumulators and batteries have a voltage decrease according to the amount of substance after the increase of the reaction in the solvent and electrodes. In addition, passing the mixture of precipitate and solvent to the outside also cools the solvent, thereby increasing the efficiency of the electrochemical reaction.

Above all, we do not have to face the nightmare of recharging or having to recharge hydrogen, methanol ... for fuel cells when these fuels are not yet available and difficult to popularize, so very few places sell them like gasoline or oil internal combustion engine because the obstacles are difficult to overcome, especially the price is too high.

With this first model: POWER FOR EVERYWAYS GENERATOR N*LINH I, see Fig.1 and Fig.2, we can generate uninterrupted energy for electric cars driving over a distance of 40 to 50,000 km (depending on the vehicle type and operating time), using only materials from Poland:

- Zn: 9 x 30 x 113.88 = 30.75 kg and

- MnO_2: 9 x 30 x 78.468 = 21.186 kg.

With a total of 51,936 kg.

So with the new POWER FOR EVERYWAYS GENERATOR N*LINH I we have solved the distance and charging problem, which is accompanied by a series of extremely annoying obstacles that normal battery charging entails. Above all, the price is extremely attractive compared to the price of gasoline in the current energy crisis. Average example:

- 10 liters of petrol/100 km x 1,768 € = 176.8 € (Berlin ARAL, 02.2023) and

- 20 kWh/100 km x 0.4141 €/kWh = 8,282 € (Berlin VATTENFALL, 03.2023)

The following applies to PFEG N*LINH I:

- 60,952 grams Zn + 162.056 grams MnO_2/100 km ~ 6.1 € + 2.8 € = 8.9 € (Tifoo and Inoxia, 02.2023)! About 20 times cheaper than a petrol car and a little more expensive than a normal electric car - but not through the recharge gate! How wonderful!

For a person with an average driving distance of about 20,000 km/year, we automatically don't have to worry about energy for about 2 years by simply disposing of the garbage regularly (easily by ourselves or with help at a gas station or a car repair shop - depending on the Accu system and the type of car), when the mileage is ~ 1000 Km, the waste can be collected for recycling. And when the car runs 40,000-50,000 km, we replace it with new rods, new solvents and new filter bags at super attractive prices because the materials are common and inexpensive in the market. This replacement period is also the total inspection period (2 years/time) for the whole vehicle. The person of the repair shop will check the battery warranty before checking the whole car, which is very convenient for the user.

We can manufacture mini power generation system specially for electric vehicle in one package/2 years with above design.

The use of the new generator PFEG N*LINH for civil power generation requires a synchronous system, as we have shown in the first part mentioned: feeding of input materials and separate separation of output waste, continuously, with high volume. The system requires higher technology and of course the cost will be higher, along with the great advantages it brings, it is suitable for large trucks and large electrochemical power plants. We will present it as follows.

5. POWER FOR EVERYWAYS GENERATOR N*LINH II (PFEG N*LINH II) with large-scale and electrochemical power generation plant.

Together with the above working principle of POWER FOR EVERYWAYS GENERATOR N*LINH I, we build a new electrochemical generator which can continuously generate electricity, with continuous supply of raw materials and separation of waste and gas. We have electrode plates made as hollow grid boxes shaped like those shown in Fig.3. The plates have metal grids to collect the electron, and the supports and connectors between the plates and discharge the current.

To supply materials for PFEG N*LINH II, we have a pipeline system that carries raw materials with KOH solvent with appropriately large raw material particles. Since the solvent is KOH solution, they have high viscosity, so it is easy to transport the raw material particles to the containers for the normal electrochemical reaction between the plates.

We can control the speed of the electrochemical reaction, by controlling the flow rate of raw material flow and the raw material ratio through the mechanism that adds the input material into the solvent

Like the PFEG N*LINH I, the PFEG N*LINH Il system features an Accu solvent separator while generating power.

At the top of the reactor, we install a pipe to bring H_2 to the collector. Since the Large Reactor H_2 is given due attention due to its strong activity and explosion risk, the Small Battery produces very little H_2. It is stored in the batteries as a precipitant and limits the current generated to avoid danger, especially in places with high ambient temperatures. However, in a large system, we use a complete separation and adsorption system, the maximum use of the capacity of the electrochemical reactor is fully allowed to improve the efficiency of power generation.

Between the 2 opposite electrode plates, where the electrochemical reaction takes place and the precipitate is generated, we have a special system to separate the precipitator to prevent it from sticking to the electrode plates. For small devices we use automatic magnetic stirrers, larger ones use automatic sweeping brushes and on an industrial scale we use automatic levers.

Separator and solvent mixed suction tubes are placed deep in the bottom of the reaction vessel so that the entire separator can be suctioned. The ends of the tubes are adjusted so that the amount of Solution inlet and outlet are the same for each reaction vessel.

FIG. 1 Structure and function diagram of new electrochemical

Generator: POWER FOR EVERYWAYS GENERATOR N*LINH I.

1. New mounting tab for battery cover; 2.

Electrode terminal pin; 3, Titanium metal structure Platinum plated brake Safety visor; 4. Safety shield prevents short circuit between electrode terminals; 5. Mixed negative electrode MnO_2;

6.8. Exhaust pipe H_2; 7. Solvent cleaning line after filtration of the separator; 9. Positive Zn electrode; 10. Substance precipitation line;

11. Stand holder electrode stand; 13. Platinum coated titanium rod holds the electrode; 14. The suction tube is placed on the bottom of the Accu tank to hold the separator and solvent for filtration and separation; 15. Pipes to lead out the separator;

16. Leak-proof seal for solvents; 17. Baffle between

2 individual batteries; 18. Positioning bar between battery and fitting;

19. Bottle cover battery; 20. Steel housing protects the battery.

FIG. 2 Structure and function diagram New electrochemical generator

POWER FOR EVERYWAYS GENERATOR N*LINH II

1. New mounting tab for battery cover; 2. H_2 exhaust pipe;

3. Battery compartment; 4. MnO_2 line; 5. Positioning bar; 6. Electrode terminals for connecting conductors; 7. Braking mechanism

Visor; 8. Safety visor; 9. Raw material vent; 10. Electrical grid box

Zn-containing rods; 12. Line for Zn particles in the grid box of the electrode plate; 13. Exhaust pipe

H_2; 14. Grid box electrode plate contains MnO_2; 15. Leg support Grid box Electrical plate

Pole; 16. Platinized titanium base of the electrode plate grid box; 17. Binding straws

Precipitate; 18. Protective steel casing.

FIG. 3 Cross sections of PFEG N*LINH I and

Overall layout diagram of the Accu system for

Electric cars and compatible devices

1. One block is 1 PFEG N*LINH I or 1 PFEG N*LINH II. 2. Equipment for filtering substances, precipitation and injection of solvent or material mixture into the new Accu-Tank; 3. Barrel

Contains raw materials and precipitants; 4. Install the battery cover; 5. Protect the metal case;

6. Solvent return hose to the battery tank; 7. Battery compartment;

8. Channel channel lips from outside; 9. Drain pipe H_2; 10. Separator outlet to the filter; 11. The electrode plate; 12. Separator suction pipe.

Claims

PATENT CLAIMS Batteries and accumulators for electric cars today mostly use rechargeable types, they use a 2-way electrochemical reaction, new batteries POWER FOR EVERYWAYS GENERATOR N*LINH I & II are filled with universal materials at a low price and use a 1-way electrochemical reaction! They have the following claimed novelties: 1. Using continuous electrochemical reaction in one direction, generating a precipitate, generating a gas, continuously supplying materials, and separating the precipitate and exhaling to maintain a continuous electrochemical reaction. New and different are: + Continuous electrochemical 1-way reactions - Instead of 2-way reactions: they balance themselves and cause self-discharge. + All operations occur only and are limited to the preset battery & battery volume and volume. 2. Continuous supply of raw materials from outside with solvent, after being filtered out from the precipitant to produce a continuous electrochemical reaction, the amount of chemicals is adjusted accordingly depending on the reaction rate as well as the needs for each vehicle and work type conditions. New and different are: + Charging materials are common, cheap, easy to use, environmentally friendly... - Instead of charging with mountains of obstacles and being expensive, causing problems and concerns for users, car manufacturers and society need to invest a lot in equipment, energy, location, personnel... On the other hand, producing Power for Recharge also has a big impact on the environment. + Materials respond to needs - Instead of carrying an existing pole plate with a large amount of materials and accessories for 1 preset power capacity, the enormous weight of the battery and accumulator increases in a vehicle with long-distance travel and large capacity requirements. + In particular, the reactants are prepared in the form of small particles, which facilitates the loading of materials and increases the contact area, resulting in an increase in the speed and efficiency of the electrochemical reaction. + Adjustable reaction speed, depending on the energy requirement of each Vehicle, depending on the season (air conditioning or heating ...) - Instead of Plates with a fixed surface, the chemistry of the composition of the compounds gradually reduces the input for the reaction and increases after the reaction, making the reaction potential smaller and smaller, the vehicle is unstable. + Increase the efficiency of the chemical reaction by increasing the Adjust the concentration of the percentage components of the reactants. 3. Separation of precipitants and exhaust gas after the reaction. The precipitate is filtered and separated. The gas is discharged via a pipeline and collected by separate devices. New and different are: + Filter and separate the separator in the solvent and take it out - Instead of gradually accumulating in the solvent and the electrode plate, the process of discharge and charge is gradually stopped when the following substances are saturated and fill the reaction space, thereby preventing the electrochemical reaction from happening continuously and forming a reverse potential - Required to proceed backwards: charging or discharging. + Exhaust gases - Instead of keeping the battery and accumulator inside, which is very dangerous, in high temperature environments it is easy to damage or explode. + Increase the power, current and efficiency of the electrochemical reaction - Instead of limiting the current, the capacity level due to the amount of precipitate formed and especially the potential danger of the gas produced. + The solvent after filtration of the precipitate is adjusted to the appropriate temperature by separate devices before it is added to the battery and accumulator together with the reaction material (PFEG N*LINH II). 4. New electrode plates are mesh boxes containing mixtures of reactants in the form of fine granules, which are fed into the plate box. Mesh holes allow ions to pass through to react with ions between the positive and negative electrodes. The mixture of reactants is made in the form of small particles to increase the contact area, accelerate the reaction and easily circulate in the pipeline. New and different are: + The electrode plates are only charged and contain just the right amount of material for the reaction - Instead of carrying the entire weight of the plate while driving, the battery weight becomes too large + The electrode plates keep a stable position, distance from each other, no Short circuit. + Create space for ions to easily contact and react with each other, increasing reaction efficiency. + Make room for the precipitator separator to work efficiently. + In particular, the precipitates formed do not adhere to the electrode plates, but are in the solvent and can therefore be easily separated.