WO2012028154A2 - Machine works by the power of floation and produces energy - Google Patents

Machine works by the power of floation and produces energy Download PDF

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Publication number
WO2012028154A2
WO2012028154A2 PCT/EG2010/000034 EG2010000034W WO2012028154A2 WO 2012028154 A2 WO2012028154 A2 WO 2012028154A2 EG 2010000034 W EG2010000034 W EG 2010000034W WO 2012028154 A2 WO2012028154 A2 WO 2012028154A2
Authority
WO
WIPO (PCT)
Prior art keywords
floating unit
water
reaction
hole
machine
Prior art date
Application number
PCT/EG2010/000034
Other languages
French (fr)
Other versions
WO2012028154A3 (en
Inventor
Sabry Abdo El-Alfy
Maher Mahmoud El-Tonsy
Original Assignee
Sabry Abdo El-Alfy
Maher Mahmoud El-Tonsy
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Sabry Abdo El-Alfy, Maher Mahmoud El-Tonsy filed Critical Sabry Abdo El-Alfy
Priority to PCT/EG2010/000034 priority Critical patent/WO2012028154A2/en
Publication of WO2012028154A2 publication Critical patent/WO2012028154A2/en
Publication of WO2012028154A3 publication Critical patent/WO2012028154A3/en

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Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F03MACHINES OR ENGINES FOR LIQUIDS; WIND, SPRING, OR WEIGHT MOTORS; PRODUCING MECHANICAL POWER OR A REACTIVE PROPULSIVE THRUST, NOT OTHERWISE PROVIDED FOR
    • F03BMACHINES OR ENGINES FOR LIQUIDS
    • F03B17/00Other machines or engines
    • F03B17/02Other machines or engines using hydrostatic thrust
    • F03B17/04Alleged perpetua mobilia

Definitions

  • ammonia gas is used and the volume decreases
  • This unit moves up and down and consists of:
  • inner pot that has the same installation of the outer pot , but the inner vessel diameter is less than the outer vessel diameter .
  • Piston moves within the inner vessel and it is compactly attached to it.
  • CD-barrier installed in the vessel and its internal holes each hole has a cover.
  • the cover is installed in the base by using screw and the base is installed in the barrier disc and the cover moves under the effect of its weight in this form ( 1 ) the lid points downwards and the holes are open and gas
  • (NH 3 ) at the top of the barrier disc is connected to ammonia gas at the bottom of the barrier disc and the pressure on gas (NH 3 ) at the top of the barrier will move to the disc gas from the bottom of the barrier disc and then to (NH 4 OH) and the water i.e. the pressure from the piston moves to the elements in the field of reaction.
  • each floating unit contains two holes enters its nail-called nail of carrying and installation one end of the nail is fitted in the chain and the other part is fitted in the parallel chain and the screw is to hold and install the floating unit and when it moves, this moves the chain.
  • arrow indicates the direction of movement and floating unit, in this case (Figure 1) floating unit moves from top to bottom.
  • the front part of floating unit is a cone-shaped to reduce friction with water.
  • the volume increases and the piston moves downwards and the water No. (15) goes out through the hole in the back cover (1)
  • the average density of floating unit decreases and the pushing force of water affecting the floating unit increases and moves heading to the top then the Chain moves to move the gear and the horizontal axis and then the main gear moves to transmit motion.
  • Holder of the machine is installed in the inner vessel containing chair Bearings wear that the axis carrying gears installed in to.
  • the horizontal axis installed in the holder axis.

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  • Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Other Liquid Machine Or Engine Such As Wave Power Use (AREA)

Abstract

According to the principle of Lushatele when you use the following chemical reaction: NH3 (g) + H2O (Li) NH4OH (Li) In a pot (floating unit) First case: The movement starts from the gear at the top of the machine and the front part of floating unit heading to the bottom By increasing the pressure on the system by the piston, reaction moves in the direction of the exponential and consumes NH3 and the volume of the system becomes less and the average density increases and the pushing force of water decreases then the vessel containing the system (floating unit) moves to the bottom till it reaches the gear at the bottom of the machine. Second case: By reducing the pressure and the separation of gas NH3 from the reaction field, the reaction goes in the opposite direction, which works to form the gas (NH3) and the volume of the system increases, the average density of floating unit decreases, the pushing force of water to the floating unit increases, the floating unit rises from the bottom to the top heading to the surface of the water in the well. There is a continuous exchange between the first case and the second case. We can get the kinetic energy that can be converted to any form of energy.

Description

Machine Works by The Power of Floation and
Produces Energy
Technical Field:
It is A machine works by the power of floation and produces energy Background Art:
None
Disclosure of Invention :
Idea of the machine
Principle of lushatele
When there is a balanced chemical reaction (incomplete, reflection) and a change in one of the factors affecting it takes place , The reaction goes in the direction that removes this change.
Factors that affect the balanced chemical reaction:
1 - Pressure
2- concentration
3- Temperature
4- The number of moles
Example:
Figure imgf000002_0001
And so on
reaction in the first number (1)
Figure imgf000002_0002
the field of reaction contains both ammonia , ammonium hydroxide and water:
Figure imgf000002_0003
When an increase in pressure on the system (field of reaction) happens, the reaction goes in this direction:
Figure imgf000002_0004
ammonia gas is used and the volume decreases
When a decrease in pressure takes place, the reaction goes in this direction:
Figure imgf000002_0005
to produce ammonia gas and the volume increases .
on the separation of gas NH3 or part of it out of the field of reaction, the reaction goes in this direction:
Figure imgf000002_0006
It Works to produce ammonia and increase the volume of the field of reaction And the increase or the decrease the pressure affects the direction of the reaction because the field of reaction contains gas.
Brief Description of Drawings:
Figuref 1)
This unit moves up and down and consists of:
1. A Rear lid cover for the entry and exit of water from the well or vessel form (1 ) In this case, water enters in the floating unit from the slot on the outside cover.
2. Water surrounds the floating unit which causes the pushing power to the floating unit and it is found in the well or the vessel.
3. External cylindrical vessel and in the front cone shape to reduce friction with water during motion and the back cover is installed in to its back.
4. Cavity between the outer and inner container filled with air it reduces the weight of floating unit in the water.
5. Nail for installing the inner vessel and the outer vessel .
6. inner pot that has the same installation of the outer pot , but the inner vessel diameter is less than the outer vessel diameter .
7. Piston (weight) moves within the inner vessel and it is compactly attached to it.
And moves under the effect of its weight , and in this form (1 ) it works to increase pressure on existing vehicles
8. Ammonia ( NH3 )
Figure imgf000003_0001
9. CD-barrier installed in the vessel and its internal holes each hole has a cover. The cover is installed in the base by using screw and the base is installed in the barrier disc and the cover moves under the effect of its weight in this form ( 1 ) the lid points downwards and the holes are open and gas
(NH3) at the top of the barrier disc is connected to ammonia gas at the bottom of the barrier disc and the pressure on gas (NH3) at the top of the barrier will move to the disc gas from the bottom of the barrier disc and then to (NH4OH) and the water i.e. the pressure from the piston moves to the elements in the field of reaction.
10. Open hole in the disc checkpoint
1 1. Cover hole
12. Open hole in the disc checkpoint
13. A hole in the back cover
14. Water from the well enters from the hole in the back cover
15. Nail for installing internal and external vessels .
16. Hole in the outer vessel it is called hole of carrying and installation, each floating unit contains two holes enters its nail-called nail of carrying and installation one end of the nail is fitted in the chain and the other part is fitted in the parallel chain and the screw is to hold and install the floating unit and when it moves, this moves the chain.
17. Nail for carrying and installation.
18. arrow (signal) indicates the direction of movement and floating unit, in this case (Figure 1) floating unit moves from top to bottom.
19. a place to install the barrier disc in the inner pot.
20. Ammonia gas.
21. Nail for installing the inner vessel and the outer vessel .
22. the front part of floating unit is a cone-shaped to reduce friction with water.
23. Solution NH4OH and water(HzO)
Explaining the work of the floating unit in Figure (1):
It Begins its work at the gear at the top of the machine into the gear at the bottom of the machine, and the front part of a floating unit is heading to the bottom.
the piston (7) presses and moves downwards into the inner pot (6) under the effect of its weight and the pressure increases on the reaction field :( H20 ' NH3 ' NH4OH )
as a result of the increase of the pressure, the reaction goes in this direction :(
Figure imgf000004_0001
i.e. ammonia is reduced
this produces ( NH OH ) and volume decreases and the piston moves downwards and the water enters from the well to a floating unit through the hole (13) in the back cover (2), this increases the average of density of the floating unit and the force of pushing of water affecting Floating unit decreases and the floating unit moves from top to the bottom until it reaches the gear at the bottom of the machine.
Figure (2)
floating unit moves in Figure (2) from the gear at the bottom of the machine to the gear at the top of the machine.
Composition:
1. Stud link internal and external vessel
2. the front part of floating unit is heading to the top.
3. Cavity filled with air between the inner and outer vessels.
4. Stud link internal and external vessel.
5. internal pot.
6. Cover of the hole moves under the effect of its weight and it is in the figure (2) the hole in the barrier disc is closed and the ammonia gas at the top of the barrier is separated from the reaction field and the number of moles of ammonia gas and concentration of ammonia is decreased in the field of reaction.
7. CD-barrier.
8. hole in Disc barrier is closed.
9. Ammonia gas. 10. hole for carrying and the installation.
1 1. hole for carrying and the installation.
12. Ammonium hydroxide solution and water
Figure imgf000005_0003
13. Nail for installing the internal and external vessels.
14. Piston (weight).
15. Water can come out of the slot in the rear back cover.
16 back cover.
17. Nail for installing the internal and external vessels.
18. Ammonia gas.
19. place to install the internal and external vessels.
20. Arrow shows the direction of movement for the floating unit and in the form of 12 the floating unit moves from the bottom to the top.
21. Cavity filled with air between the internal and external vessels.
22. Nail for installing internal and external vessels.
23. floating unit surrounded by water.
24. A hole in the back cover.
Explain the floating unit Fig (2)
when the floating unit start at the lower gear in the machine and also the front part of floating unit is heading upwards, the piston (14) chips away the pressure (reduces pressure) on the reaction field
Figure imgf000005_0002
under the effect of
weight downwards and the cover of the hole No. (6) starts to move to the bottom under the effect of its weight and the hole is closed and ammonia No. (9) are separated from the reaction field and the reaction goes in this direction:
Figure imgf000005_0001
The volume increases and the piston moves downwards and the water No. (15) goes out through the hole in the back cover (1) The average density of floating unit decreases and the pushing force of water affecting the floating unit increases and moves heading to the top then the Chain moves to move the gear and the horizontal axis and then the main gear moves to transmit motion.
There are two factors that make the reaction in Figure (2) move in the direction of ammonia formation (N¾) :
1. Separation of ammonia gas ( NH3) by the barrier disc and the cover of hole.
2. Reducing pressure on the field of reaction.
Figure (3)
1. A Vessel or a well containing the machine and water
2. The main gear for motion transmission
3. Surface of the water in the well
4. Holder of the machine
5. Gear is top of the machine
6. Floating unit moves downwards 7. chain
8. Nail for carrying and installation
9. Arrow shows the direction of movement downwards
10. A Rear lid cover for the entry and exit of water from the well or vessel form (1) In this case, water flows out of the floating unit.
1 1. the front part of floating unit is heading to the bottom.
12. A hole in the back cover
13. Holder of the machine is installed in the inner vessel containing chair Bearings wear that the axis carrying gears installed in to.
14. an axis holder with a chair of bearings and the axis holder installed in to the inner wall of the well.
15. Base of the vessel or well
16. Bearings
17. The horizontal axis installed in the holder axis.
18. an axis holder with a chair of bearings and the axis holder installed in to the inner wall of the well.
19. hole for carrying and installing.
20. Nail for carrying and installing.
21. Arrow shows the direction of movement upwards.
22. the front part of the Floating unit is heading upwards.
23. Floating unit moves upwards.
24. Water in the well that causes the pushing force.
25. Gear installed in the horizontal axis
26. Gear installed in the horizontal axis
27. Horizontal axis
28. Nail for installing
Explaining the work in Figure (3)
the floating unit number (6) moves due to the increasing pressure of the piston on the reaction field as a result of the course of reaction in this
direction:
Figure imgf000006_0001
And the volume becomes less and the water enters from the well to a floating unit through the hole in the back cover and the average density of floating unit increases and moves until it reaches the gear number (26) and the zipper moves from the top to the bottom and the gear moves and the horizontal axis moves around itself and main gear moves to transmit motion.
Upon the arrival of floating units from the top to the bottom, it begins to rotate and change direction of movement and also the front part of floating unit is heading upwards. The pressure decreases by moving of the piston under the effect of its weight to the bottom and the holes in the disc barrier are closed, Number of moles and concentration of ammonia gas in the field of reaction decreases.
As a result, reaction goes on this direction :
Figure imgf000006_0002
i.e. production of ammonia gas
In this case there are two factors make the reaction goes on the direction of ammonia formation:
1. Lack of pressure.
2. Separation of ammonia gas from the reaction field.
Figure (4)
1.A Vessel or a well
2. Surface of the water in the well
3. Holder
4. The main gear of the movement
5. Sleeve to stop water from releasing from exit hole of horizontal axis
6. Bearings wear
7. The horizontal axis
8. chain
9. Nail for carrying and installing
10. the front part of the Floating unit is heading downwards
1 1. Flotation unit moves to the bottom
12. Flotation unit moves to the top
13. A hole in the back cover
14. Horizontal axis
15. Piston
16. chain
17. Water in the well cause the pushing force
18. Nail for carrying and installing
19. Bearings wear
20. Nail for installing
21. Well Base
Figure (5)
1. gear
2. Bearings wear seat
3. Horizontal axis
4. Base installed in the inner wall of the well in which the horizontal axis is installed
5. floating Unit moves downwards
6. chain
7. the front part of the Floating unit
8. A Rear lid
9. Surface of the water in the well
10. Bearings wear
1 1. A hole in the back cover
12. Flotation unit moves to the top
13. the front part of the Floating unit is heading upwards
14. Back cover 15. chain
16. Well
17. Base
18. Nail for installing
19. Bottom of the well
Figure (6)
1. the main gear of the movement
2. the front part of Floating unit
3. chain
4. gear
5. Base
6. Horizontal axis
7. Base installed in the inner wall of the well carrying a chair bearing wear and carrying the horizontal axis
8. Bearings wear
9. Nail for carrying and installation
10. hole for Carrying and the installation
1 1. Flotation unit moves downwards
12. Rear lid
13. Gear
14. chain
15. Bearings wear seat
16. base installed in the inner wall of the well
17. Nail to install a chair of Bearings
18. Nail for installing
19. Flotation unit is heading to the top
20. the screw for installing
21. chain
Figure (7)
1. Chain
2. Chain
3. A hole in the back cover
4. Back cover
5. Flotation unit moves downwards
6. Nail for carrying and installation
7. Hole in a floating unit containing the nail for carrying and installation
8. the front part of Floating unit
9. Gear
10. base installed in the inner wall of the well
1 1. Gear
12. hole for Carrying and the installation
13. the front part of Floating unit 14. Nail for carrying and installation
15. Flotation unit moves upwards
16. Nail for carrying and installation
17. back cover
18. A hole in the back cover
19. Bearings wear
20. Bearings wear seat
21. Horizontal axis
22. Nail for installing the base in the inner wall of the well Figure (8)
1. A hole in the back cover
2. Back cover
3. Chain
4. Floating unit
5. Nail for carrying and installation
6. Nail for carrying and installation
7. Arrow shows the direction of movement of floating unit from the top to the bottom
8. the front part of Floating unit
9. Chain
10. Chain
1 1. Chain
12. the front part of Floating unit
13. Arrow shows the movement of floating unit from the bottom to the top
14. Floating unit moving from the bottom to the top
15. hole for Carrying and the installation
16. Pin-point of carrying and the installation in the zipper
17. Nail for carrying and installation
18. Pin-point of carrying and the installation in the zipper
19. back cover
20. A hole in the back cover the bottom
Figure (9)
1. outside pot
2. space filled with air between the external and internal vessel 3. the inner pot
4. Piston (weight)
5. Hole for Carrying and the installation
6. Ammonia
7. CD-barrier
8. a place to install the disc of the barrier in the internal vessel in the floating unit
9. Installed base in the CD-barrier in which the hole cover is installed by stud link 10. screw for Installing the cover of hole in the base
1 1. Open hole
12. the Cover of the hole is moves under the effect of its weight to the bottom and the hole is open
13. a place to install the disc of the barrier in the internal vessel in floating unit
14. the solution of water and ammonium hydroxide NH4OH ' H20
15. Hole for Carrying and the installation
16. Stud link of internal and external vessel
17. Stud link of internal and external vessel
Figure (10)
1. Outer Wall
2. Cavity filled with air between the internal and external vessel
3. Ammonia gas
4. the hole Cover closed as it moves to the bottom under the effect of its weight and closes the hole and separates ammonia gas above the surface of disc barrier and ammonia at the bottom of the barrier and the number of moles of ammonia decreases in the field of reaction
5. point for installation the barrier Disc in the internal vessel
6. CD-barrier
7. Closed hole
8. Installed base in the CD-barrier in which the hole cover is installed by stud link
9. Nail for binding the cover of the hole to the base
10. inner pot
1 1. Hole for Carrying and the installation
12. A hole in the barrier disc is closed
13. Ammonia gas
14. water surrounds floating unit
15. Cavity filled with air between the inner and outer vessel
16. Solution of water and ammonium hydroxide NH4OH ' H20
17. Stud link of internal and external vessel
18. Stud link of internal and external vessel
19. Hole for Carrying and the installation
20. water surrounds floating unit
21. Piston (weight)
Figure (11)
1 - water surface in the well
2 - When you put a floating unit on its own in the water its weight and its content must be equal to zero (suspended in the water at height h ) as in figure
(1 1)
3 - A floating unit at a height h from the surface of the water in the well

Claims

Claims
1. A machine works by the power of floation and produces kinetic energy
2. It Works around the clock
3. It is not affected by any climatic factors
4. It is a direct application of the principle of the Lushatele in the balanced chemical reaction (not complete or reflexive)
5. According to the principle of Lushatele when you use the following chemical reaction:
Figure imgf000011_0001
6. Increasing the pressure on the reaction makes the reaction goes in the direction of decreasing the volume i.e. in direct proportion and the average density of the system increases and the pushing force of water to the floating unit
7. by Reducing the pressure and the separation of ammonia from the reaction field, the reaction goes in the opposite direction and the volume increases and the average of density of the system and decreases, the pushing force increases leading to rising the floating unit upwards, with the recurrence of the two step (6), (7) we get the constant kinetic energy that can be converted to any form of energy .
reaction used :
Figure imgf000011_0002
Or the like
Conditions to be found in the machine:
1-the Speed of the movement of floating units in the water (the speed of
movement of the machine) must be less than the average speed of free fall of the piston (weight) alone in the water so that it weight can have pressure on the content of floating unit.
2. When you put a floating unit on its own in the water its weight and its content must be equal to zero (suspended in the water at height h ) as in figure ( 1 1 ). Where h is the distance between the surface water in the vessel or the well and the bottom of the gear at the bottom of the machine (position change direction of movement of units from the top to float down to the position from bottom to top)
3. the number of floating unit Must be increased during the height h until the completion of a chemical reaction and come to the state of balance, whether exponential or reverse as it is slow and not as fast as the interaction of combustion.
4. Number of holes in the disk barrier must be many and the distances between them are very small so that there is a complete mixing between the ammonia gas over the barrier disk and ammonia gas under the barrier disk and that when floating unit moves from the top to bottom.
PCT/EG2010/000034 2010-08-29 2010-08-29 Machine works by the power of floation and produces energy WO2012028154A2 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
PCT/EG2010/000034 WO2012028154A2 (en) 2010-08-29 2010-08-29 Machine works by the power of floation and produces energy

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
PCT/EG2010/000034 WO2012028154A2 (en) 2010-08-29 2010-08-29 Machine works by the power of floation and produces energy

Publications (2)

Publication Number Publication Date
WO2012028154A2 true WO2012028154A2 (en) 2012-03-08
WO2012028154A3 WO2012028154A3 (en) 2012-05-03

Family

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PCT/EG2010/000034 WO2012028154A2 (en) 2010-08-29 2010-08-29 Machine works by the power of floation and produces energy

Country Status (1)

Country Link
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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2015023198A1 (en) * 2013-06-20 2015-02-19 C Rnu Ion Float turbine

Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3934964A (en) * 1974-08-15 1976-01-27 David Diamond Gravity-actuated fluid displacement power generator
US20100024413A1 (en) * 2008-08-04 2010-02-04 Seong Woong Kim Engine for energy conversion

Patent Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3934964A (en) * 1974-08-15 1976-01-27 David Diamond Gravity-actuated fluid displacement power generator
US20100024413A1 (en) * 2008-08-04 2010-02-04 Seong Woong Kim Engine for energy conversion

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2015023198A1 (en) * 2013-06-20 2015-02-19 C Rnu Ion Float turbine

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