Claim
The embodiments of the invention in which an exclusive property or privilege is claimed are defined as follows.
Claim 1 : A circular spiral pipe boiler.
1. The boiler consists of upper portion and lower portion container, circular upward spiral pipe, and a heating element.
2. The heating element sits on the bottom of the lower portion container.
3. The continuous pipe, with a bottom circle on the heating element, from the bottom around the inner surface of container spirals up into the upper portion container shaped like a bowl polished to reflect sunlight.
4. The upward piping ends with a top pipe circle on the top edge of upper portion container.
5. The spiral pipe is partially filled with water, leaving the upper section with the top pipe circle for steam only.
6. Steam is controlled above boiling point. When the temperature of steam or pipe down to boiling point, the bottom heating element is switched on, and then off at a preset upper limit of temperature.
7. There are steam outlets and receivers on the top pipe circle.
8. Steam from outlet through connecting pipe turns the steam turbine's blades, which are tightly enclosed with two ends of steam entrance and exit, and then comes back into steam receiver.
9. Steam outlets and receivers are provided also for connections with the steam forwarders.
Claim 2: A steam forwarder.
1. In order to keep steam circulating in the pipe circle, a steam forwarder is installed between the steam pipe circle and a pipe circle of residual winds or water force.
2. The steam forwarder contains two sacks. Each sack has two ends of intake and outgo. Sacks may be made of silk coated with rubber on inner and outer layers, or of other materials.
3. One sack is connected with the steam pipe circle through intaking pipe from the steam pipe circle and outgoing pipe to the steam pipe circle.
4. Of the intaking pipe there is a rubber hose section. An electromagnet ring is fixed seal tightly inside the hose section. And opposite to the ring a metal sphere is also fixed with a spring on the inner perimeter of the hose. The inner diameter of the ring is slightly smaller than the sphere, which is smaller than the inner diameter of the hose
5. Another sack is connected with the pipe circle of residual wind or water force, with intaking pipe from the pipe circle and outgoing pipe to the pipe circle.
6. Of the outgoing pipe there is a rubber hose section. Inside the rubber hose section there are also an electromagnet ring and a metal sphere with spring.
7. The size of each sack is about three quarters of the enclosed container of the steam forwarder.
8. When power for both electromagnet rings is switched off, the steam expanding pressure is filling up the steam sack and squeezing the wind or water sack.
9. When power for both electromagnet rings is switched on, both metal spheres are attracted to electromagnet rings, and block the passage of steam from the intaking pipe, as well as the passage of wind or water through the outgoing pipe. The wind or water sack is immediately filled fully with wind or water and expanded to squeeze the steam sack, push steam forward into the steam pipe circle.
10. Power for both electromagnet rings is switched on and off continuously to push steam forward continuously inside the pipe circle in one way direction.
11. The steam outlet leading steam through the steam turbine and then back to the steam pipe circle is also following the same circulating direction.
12. Wind or water in the system is also reinforced by the continuous on and off switch of electric power. Reinforced wind or water goes to turn another turbine through the release exit before release or directing into another pipe circle of wind or water.
13. In a row pipe circles of wind or water, steam forwarders, and boilers' steam pipe circles can be arranged in such a way that each pipe circle has two steam forwarders on both sides, except circle at either ends of the row. The direction of intaking and outgoing of steam forwarder is reversed every other one in the row.
Claim 3: A power reinforcer.
1. The steam forwarder is converted to a power reinforcer, by adding another set of electromagnet rings and metal spheres at another diagonal positions.
2. Electric power for one set of rings is on, at the same time for another set is off, vice versa. Two sacks containing same sort of or different sources of natural power take turn to squeeze each other and push contained wind, water, liquid, steam, or gas forward in pipe circles.
3. Reinforced power then is directed to turn turbines through release pipes before release. Residual power can be utilized again by directing into another pipe circles of power reinforcers, as long as mass is not spread too thin.
Power reinforcers and pipe circles can be connected one after another. Next to a pipe circle there is a power reinforcer. Then next to a power reinforcer there is a pipe circle, and so on
Each pipe circle is connected with two power reinforcers on both sides. Same sort of natural power contained in the pipe circle is pushed forward in one way direction.
The intaking and outgoing direction of the power reinforcer has to be reversed every other one in order to enable one way direction of circulation inside every pipe circle.
The steam forwarder with boiler and the power reinforcer can be incorporated into a system to utilize multiple sources of power to enhance overall power level. |
Title of Invention: A Continuous Power Source Of Steam In Circulation, And Power Reinforcement
Specification
In drawings which illustrate embodiments of the invention, two essential parts contribute to the system:
1. A Circular Spiral Pipe Boiler, as shown on figure 1.
2. A special device, named Steam Forwarder, as shown on figure 2.
The boiler, figure 1, has a heating element, no.16, on bottom of the lower portion container, no 17. The continuous pipe from the bottom around the inner surface of container spirals up into the upper portion container shaped like a bowl, no.18, polished to reflect sunlight. The upward piping ends with a circle, no.5, on the top edge of boiler container.
The spiral pipe is filled with water partially, no.15, leaving the upper section, no.14, with the top circle for steam only.
Steam is controlled above boiling point. When the temperature of steam or pipe down to boiling point, the bottom heating element is switched on, and then off at a preset upper limit of temperature.
There are steam outlets or receivers on the tope pipe circle, no.19. The steam circle may be connected with several steam forwarders and several steam turbines. From steam outlet steam is leading through connecting pipe to turn the steam turbine blades, which is tightly enclosed with two ends of steam entrance and exit, and then returning into the steam circle through steam receiver.
In order to keep steam circulating in the steam pipe circle, a steam forwarder, figure 2, is installed between the steam pipe circle, no.5, and the pipe circle of residual wind or water force, no.9, after turning the wind or water turbine and before release.
The steam forwarder contains two sacks. Each sack has two ends of intake and outgo.
On sack, no.4 is connected with the steam pipe circle through intaking pipe, no.6, from the steam circle and outgoing pipe, no.7, to the steam circle. Of the intaking pipe there is a rubber hose section, no.l. An electromagnet ring, no.2, is fixed inside the hose section. And opposite to the ring a metal sphere, no.3, is fixed with a spring that is fixed on the inner perimeter of the hose. The inner diameter of the ring is slightly smaller than the sphere, which is smaller than the inner diameter of the rubber hose.
Another sack, no.8, is connected with the pipe circle of residual wind or water force, no.9, with intaking pipe, no.10, from the circle and outgoing pipe, no.l 1, to the circle. Of the outgoing pipe there is a rubber hose section, no.l. Inside the rubber hose section there are also an electromagnet ring, no.2, and a metal sphere with spring, no.3.
The size of each sack is about three quarters of the enclosed container, no.l 3, of the steam forwarder.
When power for both electromagnet rings is switched off, the steam expanding pressure is filling up the steam sack and squeezing the wind or water sack.
When power for both electromagnet rings is switched on, both metal spheres are attracted to electromagnet rings, and block the passage of steam from the intaking pipe, as well as the passage of wind or water through the outgoing pipe. The wind or water sack is immediately filled fully with wind or water and expanded to squeeze the steam sack, push steam forward into the steam pipe circle.
The wind or water sack is expanded and squeezed by the power turned on and off continuously. Wind or water inside the wind or water circle is forced forward in circulation. Reinforced wind or water through the release exit, no.12, goes to turn another turbine before release.
Power for both electromagnet rings is switched on and off continuously to push steam forward continuously inside the steam circulating circle in one way direction
The steam outlet leading steam through the steam turbine and then back to the steam circle is also following the same direction of circulation.
In a row, pipe circles of wind or water, steam forwarders, and boilers' steam pipe circles can be arranged in such a way that each pipe circle has two steam forwarders on both sides, except circle at either ends of the row. The direction of intaking and outgoing of steam forwarder is reversed every other one in the row.
In order to reinforce the strength of wind, water, liquid, steam, or gas supply or power, a steam forwarder can be converted to a power reinforcer, figure 3, by adding another set of electromagnet rings and metal spheres at another diagonal positions.
At the same time electric power for one set of rings is on, for another set is off, vice versa. Two sacks containing same sort of or different sources of natural power take turn to squeeze each other and push contained wind, steam, water, liquid, or gas forward in pipe circles.
Reinforced power then is directed to turn turbines through release pipes before release.
Residual power can be utilized again by directing into another pipe circles of power reinforcers, as long as mass is not spread too thin.
Power reinforcers and pipe circles can be connected one after another. Next to a pipe circle there is a power reinforcer. Then next to a power reinforcer there is a pipe circle, and so on. Each pipe circle is connected with two power reinforcers on both sides, pushing contained same sort of natural power in one way direction circulating inside the pipe circle.
The intaking and outgoing direction of the power reinforcer has to be reversed every other one in order to enable one way direction of circulation inside every pipe circle.
The steam forwarder with boiler and the power reinforcer can be incorporated into a system to utilize multiple sources of power to enhance overall power level.