ES1306747U - Lever power multiplier device. (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Lever power multiplier device, characterized in that it is made up of a frame (1) in which a thrust element is installed, such as one or more thrust motors (2), and which feeds a series of power multiplication stages mechanically connected to each other, where each power multiplier stage has a pinion (5) that is linked through a chain or toothed transmission belt (9), to a large lever pinion (6) , the power multipliers being linked to each other through respective revolution multiplier transmissions materialized in respective differential boxes (7), having provided that the output shaft of the last multiplier is connected to an alternator or power take-off shaft for activation of industrial machinery. (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

Lever power multiplier device

TECHNIQUE SECTOR

The present invention refers to a device specially designed to transform energy using the extraordinary multiplication of power allowed by the law of the first degree lever in which the power to be applied can be less than the resistance to be overcome.

For this purpose, a power multiplier generator has been developed using the multiplied and united rotational force of successive levers, formed by series of wheels and pinions, with transmission by chains, gears, toothed belts, trapezoidal, flat, etc.

All of this driven by electric motors, or other types of motors.

This generating device can be used for the following functions:

• In the electricity sector as a generator of electrical energy.

• In the industrial mechanics sector. Given its possibility of multiplying its power in an extraordinary way, very useful for driving different machines and devices that need momentum to rotate on their axis without the need to use large electric or combustion motors.

The invention is therefore applicable in the sectors of electrical energy, renewable energy, industrial mechanics and technologies applied to the rotational movement of an axis in machines and devices.

BACKGROUND OF THE INVENTION

Although force multiplier mechanisms are known based on gear systems combined with each other that allow the output torque of the device to be increased by virtue of a drastic reduction in the input revolutions compared to the output ones, these types of mechanisms are not usable. in the scope of practical application of the invention, precisely due to this enormous reduction in revolutions that are lost in the process, so that, so that the device can be actuated with a minimum force, the output revolutions obtained are not sufficient to adapt an energy generating system such as an alternator or similar.

EXPLANATION OF THE INVENTION

The device of the invention fills the technical gap described above, offering a means of power multiplier generator, applying the aforementioned laws of the first degree lever through the rotation of united series of levers (large pinions) and pinions (medium and small) of the appropriate size depending on the power to be produced and final revolutions to be achieved, driven by electric motors or other types of motors, so that the revolutions are recovered without reducing the power.

The development and manufacturing of these generating devices allow for various sizes, composition and number of levers, being easily scalable, depending on the specific needs of each case.

As an example of the invention, a prototype base model is presented, with four stages based on lever wheels.

This generator starts the movement in the first stage driven by one or more motors, which consists of a large pinion driven by a toothed belt that transmits power from the aforementioned motor.

A small pinion is installed integrally on the shaft of this large pinion and from this small pinion the multiplied power of this first lever is transmitted to the next lever and so on in accordance with the different multiplication stages provided.

As in each lever, when multiplying the power, the revolutions decrease, it is necessary to recover them to undertake the next stage and so on.

To recover these revolutions, a mechanism called differential is used, similar to that used in vehicles, and which consists of a mechanism that distributes the engine torque between the driving wheels of a vehicle, allowing one of them to rotate at a different speed than the other. .

This differential consists of a ring gear that receives the engine torque, two pinions called satellites, another two called planetary gears and two bearings, one for each wheel.

Simplifying, in this mechanism the circumstance occurs that, if one wheel is immobilized, its corresponding planetary pinion is also immobilized and its engine torque and revolutions are transmitted to the other planetary gear and to the opposite wheel, which increases the number of revolutions.

This mechanism has been modified and adapted for the present generator, but fulfilling all the functions and possibilities mentioned.

Thus, the modifications introduced in the differential box of the device of the invention are the following:

The pinions, normally conical, installed in the shape of wedges, are modified by others with a flat crown that mesh on their edges.

A planetary gear and its corresponding driveshaft are permanently immobilized, fixing them to the frame, so that their engine torque and revolutions are diverted to the opposite planetary gear and driveshaft.

The size of the planetary gears is modified by installing the largest one in the immobilized planetary gear and bearing (which we will call the input) and the smallest size on the opposite side (which we will call the output).

Each satellite pinion that rotates freely on its axis is divided into two integral pinions, but of different sizes, which also rotate freely on the same axis.

The largest planetary pinion and the immobilized planetary gear (input) must be the same size and number of teeth.

The smallest planetary gear and the smallest planetary gear (output) must be of the same size and number of teeth.

The smaller planet pinion meshes with the larger immobilized planetary pinion, increasing the revolutions of the planets (smaller and larger size), since they are installed jointly on the same shaft that rotates freely.

Finally, the largest planetary pinion meshes with the smallest planetary gear, producing another second increase in revolutions in the output shaft or driveshaft of the differential box.

By modifying the sizes and number of teeth of the planets and planetary gears as desired, according to the conditions mentioned in the previous paragraphs, the desired revolutions in the planetary gear and output shaft are obtained, without reducing the engine torque.

The development and manufacturing of this differential mechanism also allows for diverse sizes, composition and use, being easily scalable, depending on the specific needs of each case. For example: the number of satellite sprockets can be increased. The structure can be designed in a circular shape and the differential box inside which the mechanism is installed can also be circular in shape. If a toothed ring for chains or straps is installed on this circular box on its outer edge, it can simultaneously act as a lever wheel.

Each wheel or lever pinion has a differential box attached to its edge by means of screws, as described above, which acts as the "crown" of the differential.

This differential mechanism recovers and increases the revolutions decreased when the lever effect occurs, which are necessary to undertake the next series and so on, all while maintaining unchanged the power torque that is produced with the multiplication accumulated in each series of levers.

As mentioned in the previous paragraph, the rpm is reduced in each series. when the leverage effect occurs and then they recover to undertake the next series and so on. Logically, in each recovery, the torque is modified (without reducing the power) leaving it equal in rpm. to those of the alternators.

The formula of the law of the first degree lever tells us that "The power through your arm is equal to the resistance through yours."

P x BP = R x BR.

The lever model used in this invention may resemble or correspond to that of a lathe (simple machine, fig. 1) used in ancient times to draw water from a well or lift a certain load, in which on a support It placed an axle, normally made of wood, to which a rope with a load or resistance was attached, moved by a crank at the end of said axle, which acts as a lever.

In this case, instead of a crank, a large lever pinion is installed and instead of rotating it by manual force, a motor with a chain or transmission belt is attached.

If you wish to reduce the force to be applied even further, another similar mechanism can be attached next to the previous one, which acts as a second lever, and this option can be repeated more times, as appropriate, achieving an extraordinary reduction in force in relation to the resistance to overcome.

In this device, the power is applied to the edge of the lever wheel and the fulcrum or fulcrum is the same axis of said wheel and pinion.

The application of power on the edge of the lever wheels can be done in various ways, as appropriate, namely: Using chains, gears, toothed belts, flat, trapezoidal, etc.

It can also be applied using air:

• Through air-ambient with engine-turbine, on buckets on the lever wheel. • Through air-ambient with propeller or turbine motors, installed on the edge. • Using compressed air (compressor), on buckets on the wheel.

Using water:

• By means of water with a motor-pump on the wheel buckets.

• With pressurized water (hydro-compressor) also on the wheel buckets.

Using a reducer:

• Modifying the torque as appropriate.

• Using metal spokes directly from the motor pinion to the edge of the wheel.

The torque calculation formula in Kilos/meter is as follows:

T= HP x 716/rpm.

As can be seen in this equation, if the denominator (r.p.m.) is modified, T (torque) is also modified, but the power (HP) remains unchanged.

With this power multiplier generator device through chained series of pinions and lever wheels, electrical energy is produced in a clean and renewable, non-polluting way, being easily scalable, both in size and number of lever wheels, for small, medium or large production, at the time of interest, fixed or mobile installation, autonomously or non-autonomously, without dependence on raw materials or atmospheric agents.

In the field of industrial mechanics, this power generating device is characterized because, from the final shaft of the last series of lever wheels, this shaft can be connected, with the appropriate revolutions, by means of coupling, to the direct transmission of other different mechanisms that need to drive power through the rotation of a shaft, thus eliminating the need for large electric or combustion motors.

In addition to the formula for the first degree lever and torque calculation in kg/m already mentioned above, the following formulas have also been taken into account for the development of this power multiplier generator:

-Uniform circular motion:

W (angular velocity in radians/second) = 2 pi: (divided) x 60.

2 pi: (divided) by 60 = 0.1047 (constant)

W (angular speed radians/second. Simplified) = rpm x 0.1047

Newton's second law of motion:

F = m x a (force equals mass times acceleration)

Newton's second law for rotation:

Force is replaced by T (torque). The mass is replaced by I (Inertia) and the acceleration is replaced by W (angular velocity) and the formula is:

T (torque) = I (inertia) x W (angular speed). Torque is equal to the moment of inertia about the axis of rotation times the angular acceleration.

In short, the present invention achieves its results through the application of the following mechanisms:

-First grade lever:

The greater the power arm with respect to the resistance arm, the greater the multiplication of power. If the multiplied power of the first lever is combined with a second lever of equal characteristics, the power of the first is multiplied by the power of the second, and so on.

-Mechanism or differential box; recovers the revolutions without reducing power, maintaining engine torque.

BRIEF DESCRIPTION OF THE DRAWINGS

To complement the description that will be made below and in order to help a better understanding of the characteristics of the invention, in accordance with a preferred example of its practical implementation, a set of plans is attached as an integral part of said description. where, for illustrative and non-limiting purposes, the following has been represented:

Figure 1.- Shows a perspective view of a lathe used in ancient times to draw water from a well, a mechanism that served as inspiration to develop the present invention.

Figure 2.- Shows a 3D perspective, top view, with arrows and numbers indicative of different elements installed in the lever power multiplier device made in accordance with the object of the present invention.

Figure 3.- Shows a 3D perspective view of the device in the previous figure.

Figure 4.- Shows another perspective view, from a different angle, of the device of Figures 2 and 3, with arrows and numbers indicative of different elements installed in said device.

Figure 5.- Shows a view of the closed Differential Case.

Figure 6.- Shows the interior of the Differential Case with its structure, satellite and planetary gears and bearings.

References used in the figures:

Number 1.- Frame.

Number 2.- Engine.

Number 3.- Alternator.

Number 4.- Pinion 100 mm diameter.

Number 5.- Pinion 80 mm diameter.

Number 6.- Lever pinion of 500 mm diameter.

Number 7.- "Differential box" rpm multiplier.

Number 8.- Bearings.

Number 9.- Transmission belts.

Number 10.- Flywheel.

Number 11.- 165 mm diameter satellite sprockets.

Number 12.- 70 mm diameter satellite sprockets.

Number 13.- Planetarium of 165 mm diameter.

Number 14.-Planetary of 70 mm diameter.

Number 15.- bearings.

Number 16.- Batteries.

Number 17.- Voltage regulator, electronic control unit.

Number 18.- Frequency converter for progressive start.

Number 19.- Silent-block and adjustable rubber feet.

PREFERRED EMBODIMENT OF THE INVENTION

The development of the power multiplier device follows a simple organizational order that begins with the motor that drives the power to the first lever wheel.

From the small pinion installed on the shaft of the aforementioned first lever wheel, its multiplied power is sent to the second stage of lever wheel which, having recovered its revolutions through the differential mechanism, transmits its multiplied and accumulated power to the third series and so on. the fourth series, to finally reach the Alternator that receives the accumulated and multiplied power of all the series of lever wheels with the necessary revolutions for the correct operation of the alternator.

More specifically, the device of the invention is supported by a frame (1) in which a motor (2) that produces thrust is installed.

The aforementioned motor, through its shaft and a pinion (5) of 80 mm diameter and toothed transmission belt (9), sends its power and revolutions, (in this case 1500 rpm), to a large lever pinion (6 ) of 500 mm in diameter that reduces its revolutions to 240 rpm, which constitutes a first multiplier stage.

Connected integrally by screws to this first lever, it has a differential box (7) that multiplies rpm without reducing the power, with an output of 1500 rpm necessary to undertake the second series.

For the lever calculation of this first stage, in this case the power arm is 25 cm, (lever pinion wheel radius (6): divided by 4 cm (output pinion radius (5), obtaining a power multiplication by 6 .25.

Second stage:

From the output pinion (5) of the first stage, the multiplied power is sent to a large pinion/lever (6) of 500 mm diameter installed on a second shaft, which reduces its revolutions to 240 rpm.

Connected integrally by screws to this second lever, it has a differential box (7) that multiplies rpm without reducing the power, with an output of 1500 rpm necessary to undertake the third series.

For the calculation of the lever of this second series, in this case the power arm is 25 cm, (lever pinion wheel radius (6): divided by 4 cm (output pinion radius (5), obtaining a power multiplication by 6 ,25.

Third and Fourth Stage Operation:

Similar to the operation of the previous stages.

Finally, at the output of the differential box shaft (7) of the fourth stage, a 100 mm diameter pinion (4) is installed that sends the accumulated power of the four series to another similar 100 mm pinion (4). diameter installed on the alternator shaft, with 1500 rpm necessary for the correct operation of said alternator, completing the four series of levers planned for this power multiplier prototype.

For the third stage lever calculation, the power arm is 25 cm (radius of large pinion (6) of 500 mm diameter) divided by 4 cm (radius of output pinion (5) of 80 mm diameter, obtaining a multiplication by 6.25.

To complete the lever calculation of the fourth series, the power arm is 25 (radius of the large pinion (6) of 500 mm in diameter, divided by 20 (radius of the alternator rotor (3) of 40 cm in diameter, obtaining a multiplication by 1.25.

As can be seen in the last stage, the power multiplication is minimal since the radius of the large lever pinion (25 cm) must be divided by the radius of the alternator rotor (20 cm) which is also larger in diameter, but the installation This fourth series is of vital importance because it neutralizes and avoids the multiplied decrease in power that occurs in the previous series.

Regarding the mechanism or differential box (7), as shown in Figure 6, based on the conventional structuring of these mechanisms, it has been anticipated that the modifications introduced therein are the following:

The satellite pinions (11-12), normally conical, installed in the shape of wedges, are modified by others with a flat crown that mesh on their edges.

A planetary gear (13) and its corresponding driveshaft (15) are permanently immobilized, fixing them to the frame, so that their engine torque and revolutions are diverted to the opposite planetary gear (14) and driveshaft (15).

The size of the planetary gears (13-14) is modified by installing the largest one (165mm) in the immobilized planetary gear and bearing (which we will call the input) and the smallest size on the opposite side (which we will call the output).

Each satellite pinion (11-12), which rotates freely on its axis, is divided into two integral pinions, but of different sizes, which also rotate freely on the same axis.

The largest planetary pinion (11) and the immobilized planetary gear (13) (input) must be of the same size and number of teeth.

The smaller satellite pinion (12) and the smaller planetary gear (14) (output) must be of the same size and number of teeth.

The smaller satellite pinion (12) meshes with the larger immobilized planetary pinion (13), increasing the revolutions of the satellites (smaller and larger size), since they are installed jointly on the same shaft that rotates freely.

Finally, the larger satellite pinion (11) meshes with the smaller pinion (14), producing another second increase in revolutions in the output shaft or driveshaft (15) of the differential box.

Likewise, for the best operation of the device, it is advisable to install a flywheel (10) to soften the pull that may arise from the sudden entry into load of the alternator, one or more batteries (16), a frequency converter ( 18) to start and accelerate smoothly and gradually, a tension regulator (17) and several Silent-Bolcks with adjustable rubber feet (19) to avoid unwanted vibrations and movements.

As a general rule, so that the final potential energy calculation in the device does not decrease, in the last series of the different machines that are manufactured, the arm (power) of the last series of lever wheel must be divided by the radius of the rotor (resistance) of the alternator in the case of electrical energy and to obtain the best results, try to use alternators with the smallest possible rotor radius.

In the case of industrial machines or vehicles (for example, cars-trucks, etc. in which it is desired to apply direct transmission of the total power of this multiplier to the clutch and/or gearbox, in the last series, it must be divided the lever arm (power) times the radius of the vehicle's drive wheels, (resistance) to be overcome and to obtain the best results, try to use drive wheels with the smallest radius possible.

The device thus described has different modes of operation:

A first mode as autonomous operation.

For this type of operation, one or more alternators (3), batteries (16), frequency converter (18), and voltage regulator (17) can be installed. From these batteries the motors that drive the generator are powered, which can subsequently be powered directly from the energy provided by the alternators.

The device can also function as "non-autonomous".

These multiplier models are also very useful if you want to use them as "non-autonomous", and dispense with batteries in fixed installations where there is electrical energy from the network and you decide to use said energy, allocating the total energy transformed by the alternators for the desired purposes.

In both autonomous and non-autonomous operation, it is necessary to install a frequency converter (18) in the machine to, at start-up, gradually accelerate until the planned revolutions are achieved.

In short, the present invention is based on the laws of the first degree lever whose formula and foundation are known, demonstrated, published and applied by science and industry since time immemorial.

Also decisive for the recovery of revolutions, without reducing power, is the use of the differential mechanism used with complete success in road vehicles.

In this power multiplier model, as reported in the description of the invention, what is done is to use successive series of chained levers that multiply the power received, recovering in each of them, through the modified differential mechanism, the rpm that They are lost with the leverage effect, power that they transmit from each series to the next multiplied in the form of a geometric progression, the ratio of which is the length of the radius of each large lever wheel (input), divided by the radius of its small integral pinion (output). ) that receives the multiplied and accumulated power, taking its extraordinary potential energy to the final axis of the multiplier-generator to connect it to the alternators installed in this case of electrical production, or by direct transmission to the axis of machines, vehicles or other devices that require twist in the case of its use in industrial mechanics.

Claims (1)

1a.- Lever power multiplier device, characterized in that it is made up of a frame (1) in which a thrust element is installed, such as one or more thrust motors (2), and which feeds a series of power multiplication stages mechanically connected to each other, where each power multiplier stage has a pinion (5) that is linked through a chain or transmission toothed belt (9), to a large lever pinion (6 ), the power multipliers being linked to each other through respective revolution multiplier transmissions materialized in respective differential boxes (7), having provided that the output shaft of the last multiplier is connected to an alternator or power take-off shaft for activation of industrial machinery. 2a.- Power multiplier device per lever, according to claim 1a, wherein each differential box (7) is constituted from the conventional structuring of a differential box, in which: • The satellite pinions (11-12) are materialized as flat crown gears that mesh on their edges. • One of its planetary gears (13) is fixed to the frame with its corresponding bearing (15), defining the entrance of the mechanism. • The planetarium (13) is larger than the second planetarium (14), which is smaller. • Each satellite pinion (11-12), which rotates freely on its axis, is divided into two integral pinions, but of different sizes, which also rotate freely on the same axis. • The largest satellite pinion (11) and the immobilized planetary gear (13) (input) are of the same size and number of teeth. • The smaller satellite pinion (12) and the smaller planetary gear (14) are of the same size and number of teeth. • The smaller planetary pinion (12) meshes with the larger immobilized planetary pinion (13). • The larger satellite pinion (11) meshes with the smaller pinion (14). 3a.- Lever power multiplier device, according to claim 1a, wherein the thrust element at the entrance of the device is embodied in a turbine-motor. 4a.- Lever power multiplier device, according to claim 1a, wherein the pushing element at the entrance of the device is embodied in a compressor. 5a.- Power multiplier device by lever, according to claim 1a, wherein the thrust element at the entrance of the device is materialized in a motor-pump. 6a.- Power multiplier device by lever, according to claim 1a, wherein the pushing element at the entrance of the device is materialized in a hydro-compressor. 7a.- Lever power multiplier device, according to claim 1a, characterized in that four multiplication stages participate in it. 8. a- Lever power multiplier device, according to claims 1a and 7a, characterized in that an 80 mm pinion (5) linked by a belt to a large lever pinion (6) of 500 mm participates in the first multiplication stage. diameter. 9. a- Lever power multiplier device, according to claims 1a, 7a and 8a, characterized in that in the second, third and fourth multiplication stage the output pinion (5) of the previous stage is linked to a pinion/lever large (6) 500 mm diameter installed on a second axis. 10. a- Lever power multiplier device, according to claims 1a, 7a to 9a, characterized in that at the exit of the fourth stage a 100 mm diameter pinion (4) is installed that sends the accumulated power of the four series to another similar pinion (4) of 100 mm diameter installed on the shaft of an alternator. 11a.- Power multiplier device per lever, according to claims 1a and 2a, where: • The satellite pinions (11) are 165 mm in diameter. • The satellite pinions (12) are 70 mm in diameter. • The planetarium (13) is 165 mm in diameter. • The planetarium (14) is 70 mm in diameter. 12a.- Lever power multiplier device, according to claim 1a, where the device includes one or more alternators (3), batteries (16), a frequency converter (18) and a voltage regulator (17). 13a.- Lever power multiplier device, according to claim 1a, wherein the device includes a flywheel (10).