Main block of drop-power station

Abstract

Four similar gravitational sub-systems connected with one another to keep rotational energy substantially constant caused by gravity as a result of the combined interaction between two elements having different groups of gravity masses and different speeds.

Description

BACKGROUND

[0002] The present invention utilizes the certain interaction between four special unbalanced freely rotating sub-systems, each of which taken alone converts gravitational energy into mechanical energy using the method and system described in U.S. Pat. No. 5,921,133.

[0003] The present invention is a logical completion of this patent and incorporates this patent by reference.

[0004] Here is a quotation from the U.S. Pat. No. 5,921,133 (see col.2, lines 9-16): “the process of obtaining a certain special unbalance includes certain steps to find the proper place and correct masses for them to make the free-falling rotation more powerful”.

[0005] This patent states that each of the “unbalanced masses 2,9 can represent many different unbalanced masses”.

[0006] Following that method the applicants are experimented to find the proper placement and weight of a collection of unbalanced masses placed on the sub-systems. The objective was to find such locations and amounts of the masses such that the sub-systems, having a certain relation to each other would have kinetic energy to continue rotate with substantially constant speed.

[0007] The present invention is a first step for a large-scale production of real clean energy.

SUMMARY OF THE INVENTION

[0008] Accordingly, it is an object to provide a new way for a “Main block of drop-power station”.

[0009] In keeping with this way and with others, which will become apparent hereinafter, another feature of the present invention resides, briefly stated, in a main block of a drop-power station for producing energy by means of the certain interaction between four similar sub-systems (two opposite blocks), each of which taken alone converts gravitational energy into mechanical energy and each of which has the first rotatable special unbalanced element and the second rotatable special unbalanced element.

[0010] The first rotatable special unbalanced element has thereon a gear periphery and the first group of unbalanced masses having the values of 6 units of mass, 4 units of mass, 3 units of mass, which are in the beginning of movement spaced equidistantly on a circle with a radius having the value of 75 units of length accordingly to the “1 o'clock”, “5 o'clock” and 9 o'clock” positions.

[0011] the second rotatable element has thereon the system of local unbalanced masses in connecting with the gears and the second group of unbalanced masses having the values 5 units of mass, 3 units of mass, and 1 unit of mass, which are in the beginning of movement spaced equidistantly on a circle with a radius having the value of 75 units of length accordingly to the “11 o'clock”, “3 o'clock” and 7 o'clock” positions.

[0012] in each sub-system taken alone the first (rotatable) element has a certain kinematic relation to the second (rotatable) element and they are connected to one another by means of a central overrunning clutch and gears spaced equidistantly on the periphery of the second element, having a local unbalanced mass on each gear as its source of power, said local unbalanced mass having an axle attached therethrough and connect to each gear by means of a local overrunning clutch.

[0013] the local unbalanced masses as a system is balanced, so that in each sub-system taken alone, the first rotatable element is powered by the first group of unbalanced masses, by the second group of unbalanced masses, and by sequential impulses of force that are generated as result of a rotation of the local unbalanced masses around their respective axles and as a result of the constant rotational separation of the second group of unbalanced masses from the first group of unbalanced masses

[0014] said sequential impulses of force and a particular configuration of positions and amount of the unbalanced masses cause said first rotatable element to rotate with increasing speed during the first half of a rotational cycle of said rotatable element and with decreasing speed during the second half of the rotational cycle of said first rotatable element

[0015] in each sub-system taken alone, the second rotatable element is powered by the second group of unbalanced masses, by the first group of unbalanced masses, by sequential impulses of force that are generated as a result of a rotation of the local unbalanced masses around their respective axles and as a result of the constant rotational separation of the second group of unbalanced masses from the first group of unbalanced masses and by means of the gears

[0016] the second element rotates slower than the first one and undergoes five revolutions in the period of time that the first element rotates through six revolutions; there being six revolutions in a single cycle

[0017] the action of a local unbalanced element, which make the first element turn faster than second element combined with a certain interaction between two special groups of gravity masses acting on the rotatable elements provide for each sub-system taken alone a certain changeable relationship between their magnitude and as a result a positive sum of driving moments, which is bigger than negative sum of driving moments in any intervals of movement, and which is sufficient to increase power during the first three revolutions and to decrease power during the second three revolutions of a cycle, but not lower than power of initial position.

[0018] each sub-system taken alone has an ability to continue rotate due to the 148 units of kinetic energy by the end of each interval of movement, which is the same as a potential energy in the initial position of movement

[0019] the combining each of two sub-systems taken alone in a way that the certain friction interaction between their's first and second rotatable elements occurs at the connection between them and a certain interaction between two special groups of gravity masses occurs at the connection inside them the first and second elements begin to operate at the same time and enhance each other's ability of a limited self-accelerating which is coming from the first element of the first sub-system to the second element of the second sub-system, from the second element of the second sub-system to the first element of the second sub-system, as well as from the first element of the third sub-system to the second element of the fourth sub-system, from the second element of the fourth sub-system to the first element of the fourth sub-system such interaction protects the power of a single cycle from the downfall and provides a stable 6 revolution cycle of free rotation.

[0020] The first element of the second sub-system and the first element of the fourth sub-system are connected by means of their friction disks that provide sufficient friction between them so that movement of the first element of the second sub-system causes the first element of the fourth sub-system to move when the third and fourth sub-systems are released from an initial position.

[0021] The third and the fourth sub-systems as a second block begin to operate and interact with the first and the second sub-systems as a first block after duration of one-half of the rotational cycle of the first rotational element. That one-half of the rotational cycle of the first rotational element occurs with increasing velocity.

[0022] The interaction between two similar opposite blocks when the increase and decrease in the velocity of one of them is counteracted by a decrease or increase in the velocity of the second one provides a free rotation with a substantially constant velocity.

[0023] The invention itself will best be understood from the following description of a preferred embodiment, which is accompanied by the following drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

[0024] FIG. 1 is a front view of a schematic representation of a main block of drop-power station.

[0025] FIG. 2 is a side view of the system shown in FIG. 1.

[0026] FIG. 3 a ) is a diagram of the interaction between two special unbalanced group of gravity masses in a sub-system taken alone in 30 degree and 15 degree intervals of movement.

[0027] FIG. 3 b ) is a diagram of combined interaction between two similar opposite blocks having combined cycle of 9 revolutions.

DESCRIPTION OF THE PREFERRED EMBODIMENT

[0028] The main block of drop-power station includes four similar sub-systems (two opposite blocks), which are based on a support 1 with bearing 10, as seen in FIG. 1 and FIG. 2.

[0029] Each sub-system taken alone has a special unbalanced wheel 3.

[0030] The special unbalanced wheel 8 has thereon a gear periphery and the first group of unbalanced masses 9 having the values of 6 units of mass, 4 units of mass, 3 units of mass, which are in the initial position of movement spaced equidistantly on a circle with a radius having the value of 75 units of length accordingly to the “1 O'clock”, “5 O'clock”0 and “9 O'clock” positions.

[0031] The special unbalanced wheel 3 has thereon the system of gravitational lever 7, which is balanced, while each of the levers taken alone is unbalanced (local unbalanced mass). As well, wheel 3 has thereon the second group of unbalanced masses 2 having the values 5 units of mass, 3 units of mass and 1 unit of mass, which are in the beginning of movement spaced equidistantly on a circle with a radius having the value of 75 units of length accordingly to the “11 O'clock”, “3 O'clock” and “7 O'clock” positions.

[0032] In each sub-system taken alone the wheel 8 has a certain kinematic relation to the wheel 3 and they are connected to one another by means of a central overrunning clutch 11 and gears 6 spaced equidistantly on the periphery of the wheel 3, having lever 7 on each gear as it source of power.

[0033] In each sub-system taken alone, the wheel 8 is powered by the first group of unbalanced masses 9, by the second group of unbalanced masses 2, and by sequential impulses of force that are generated as a result of a rotation of the gravitational lever 7, which make wheel 8 turn faster and hence more frequently than wheel 3.

[0034] The short shoulder of “GL” is the radius of the gear 6, which is connected to a gear periphery of wheel 8. The “GL” has an axle 5 attached therethrough and connect to each gear 6 by means of overrunning clutch 4. From the point of view of the motionless system, the “GL” works as a well-known Archimed Lever, according to which the power and distance are self-balanced. The amount gained in power is equivalent to the amount lost in distance.

[0035] From the point of view of the rotating System the picture globally changes, when the wheels start moving powered by its own gravity masses.

[0036] In this case the outer force on the long shoulder of the “GL” is the long shoulder itself, because it tends to keep itself vertical, due to the gravitation. This tendency itself is a description of how the “GL” works.

[0037] The size of the longer shoulder can be increased as much as one wants. And this will increase the “GL” power, but wouldn't cause a decrease in the distance, because the shorter shoulder duplicates the movements of the longer one.

[0038] This is independent of the length of the long shoulder. When the “GL” makes one full turn around a general axle (axle of a rotation system) the short shoulder also makes one fill turn around its own axle (not less and not more).

[0039] It means that “GL” gains in distance, but it doesn't lose power, because it power is gravitation.

[0040] The action of a lever 7, which make the wheel 8 turn faster than wheel 3 combine with a certain interaction between two special groups of gravity masses 9 and 2 acting on the wheels provide for each sub-system taken alone a certain changeable relationship between them and as a result a positive sum of driving moments, which is bigger than negative sum of driving moments in any intervals of movement, and which is sufficient to increase speed during the first three revolutions and too decrease speed during the second three revolutions of a cycle Table 1-3, FIG. 3a).

[0041] Also the gravitational levers7 provide a constant rotational separation of the second group of unbalanced masses 2 from the first group of unbalanced masses 9 as a source of a sequential impulses of force.

[0042] All sub-systems connected to one another by means of friction disks 12.

[0043] The first and the second sub-systems as well as the third and the fourth sub-systems connected to one another with the wheels 3 and 8, having different speeds.

[0044] It is proven that the wheel 3 rotates slower than the wheel 8 and undergoes five revolutions in the period of time that the wheel 8 rotates through six revolutions; there being six revolutions in a single cycle.

[0045] Such friction interaction between the wheels having different speeds enhance each other's ability of a limited self-accelerating which is coming from the wheel 8 of the first sub-system to the wheel 3 of the second sub-system, from the wheel 3 of the second sub-system to the wheel 8 of the second sub-system, as well as from the wheel 8 of the third sub-system to the wheel 3 of the fourth sub-system, from the wheel 3 of the fourth sub-system to the wheel 8 of the fourth sub-system.

[0046] Such interaction protects the power of a single cycle from the downfall and provides a stable 6th revolutions cycle of free rotation.

[0047] A certain friction interaction between the first and the second sub-system, as well as between the third and the fourth sub-system is reaching by means of an adjusting knob 13—screw14—nut 15—footstep 16 and springs 17,18.

[0048] The first sub-system starts to operate and interact with the second sub-system at the same time after the lever 19 makes 45 degree turn from “12 O'clock” to “6 O'clock” position. At that moment plungers 20, 21 falling down through the holes 22 in an axle 23 and through the holes 24 in a support 1 powered by their gravity masses and springs 25.

[0049] The wheel 8 of the second sub-system and wheel 8 of the fourth sub-system are connected by means of their friction disks 12 that provide certain friction between them by means of an adjusting knob 26—screw27—nut 28—footstep 29 and springs 30.

[0050] The third and the fourth sub-system as a second block begin to operate and interact with the first and second sub-systems as a first block after duration of one half of the rotational cycle when the lever 31 makes 45 degree turn from “12 O'clock” to “6 O'clock” position and plungers 32,33 falling down through the holes 34 in an axle 35 and through the holes 36 in a support 1 powered by their gravity masses and springs 37.

[0051] The interaction between two similar opposite blocks when the increase or decrease in the velocity of one of them is counteracted by a decrease or increase in the velocity of the second one provides a free rotation with a substantially constant velocity FIG. 3b)

Claims

1. Main Block of drop-power station comprising: the four similar sub-systems each of which taken alone converts gravity into mechanical energy by means of a sequence of impulses of force and each of which has a first rotatable element and the second rotatable element the first rotatable special unbalanced element has thereon a gear periphery and the first group of unbalanced masses having the values of 6 units of mass, 4 units of mass, 3 units of mass, which are in the beginning of movement spaced equidistantly on a circle with a radius having the value of 75 units of length accordingly to the “1 o'clock”, “5 o'clock” and 9 o'clock” positions. the second rotatable element has thereon the system of local unbalanced masses in connecting with the gears and the second group of unbalanced masses having the values 5 units of mass, 3 units of mass, and 1 unit of mass, which are in the beginning of movement spaced equidistantly on a circle with a radius having the value of 75 units of length accordingly to the “11 o'clock”, “3 o'clock” and 7 o'clock” positions. in each sub-system taken alone the first (rotatable) element has a certain kinematic relation to the second (rotatable) element and they are connected to one another by means of a central overrunning clutch and gears spaced equidistantly on the periphery of the second element, having a local unbalanced mass on each gear as its source of power, said local unbalanced mass having an axle attached therethrough and connect to each gear by means of a local overrunning clutch the local unbalanced masses as a system is balanced, so that in each sub-system taken alone, the first rotatable element is powered by the first group of unbalanced masses, by the second group of unbalanced masses, and by sequential impulses of force that are generated as result of a rotation of the local unbalanced masses around their respective axles and as a result of the constant rotational separation of the second group of unbalanced masses from the first group of unbalanced masses said sequential impulses of force and a particular configuration of positions and amount of the unbalanced masses cause said first rotatable element to rotate with increasing speed during the first half of a rotational cycle of said rotatable element and with decreasing speed during the second half of the rotational cycle of said first rotatable element in each sub-system taken alone, the second rotatable element is powered by the second group of unbalanced masses, by the first group of unbalanced masses, by sequential impulses of force that are generated as a result of a rotation of the local unbalanced masses around their respective axles and as a result of the constant rotational separation of the second group of unbalanced masses from the first group of unbalanced masses and by means of the gears the second element rotates slower than the first one and undergoes five revolutions in the period of time that the first element rotates through six revolutions; there being six revolutions in a single cycle the action of a local unbalanced element, which make the first element turn faster than second element combined with a certain interaction between two special groups of gravity masses acting on the rotatable elements provide for each sub-system taken alone a certain changeable relationship between their magnitude and as a result a positive sum of driving moments, which is bigger than negative sum of driving moments in any intervals of movement, and which is sufficient to increase power during the first three revolutions and to decrease power during the second three revolutions of a cycle, but not lower than power of an initial position. each sub-system taken alone has an ability to continue rotate due to the 148 units of kinetic energy by the end of each interval of movement, which is the same as a potential energy in the initial position of movement the combining each of two sub-systems taken alone in a way that the certain friction interaction between their first and second rotatable elements occurs at the connection between them and a certain interaction between two special groups of gravity masses occurs at the connection inside them the first and second elements begin to operate at the same time and enhance each other's ability of a limited self-accelerating which is coming from the first element of the first sub-system to the second element of the second sub-system, from the second element of the second sub-system to the first element of the second sub-system, as well as from the first element of the third sub-system to the second element of the fourth sub-system, from the second element of the fourth sub-system to the first element of the fourth sub-system and which is protect the power of a single cycle from the downfall and provides a stable cycle of free rotation. the combining each of four sub-systems in a two opposite blocks when a certain friction interaction between their first rotatable elements occurs at the connection between them and a certain interaction between two special double groups of gravity masses occurs at the connection inside them, the third and fourth sub-systems as a second block begin to operate and interact with the first and second sub-systems as a first block after duration of one-half of the rotational cycle of the first rotatable element when increase or decrease in the velocity of one of them is counteracted by a decrease or increase in the velocity of the second one and provides free rotation with a substantially constant velocity.

2. The system of the claim 1, wherein the first and second rotatable elements are wheels having different speeds of rotation and friction disks for connection between sub-systems

3. The system of the claim 1, wherein the local unbalanced mass is a gravitational lever, which makes the first element rotate faster than second element without loosing its power