RU2249126C2 - Method of and device for generation of energy by convection - Google Patents

Abstract

FIELD: power engineering.

SUBSTANCE: invention is designed for generation of energy using differences of temperatures appearing at naturally occurring phenomena. Method is implemented by forced forming of channel of rising air flow and down air flow in closed tight zone containing gas and creation of vortex flows owing to synergism of two channels of flow and rotation of turbine by vortex flows to generate electric energy by generator. Device for implementing proposed method contains cylindrical rotor installed between rising gas flow channel and down gas flow channel which forms vortex flows and rotates fans. Device can be furnished with second cylindrical rotor installed between rising air flow channel and partition separating closed zone from external space thanks to which friction between rising and down flows of air is reduced.

EFFECT: increased efficiency of energy generation.

9 cl, 7 dwg

Description

This invention relates to the improvement of the method and device for generating electricity through the use of energy of the phenomenon of artificially created turbulence in order to increase the efficiency of energy use.

State of the art

Earlier, solutions were proposed for the generation of electricity, according to which the same phenomenon was artificially created as a turbulence occurring in nature, and the turbine was driven by using the energy of rotation of the gas stream in it.

It was proposed (Japanese Patent No. 6-147098, Kokai) a device for implementing this solution, which contained a sealed cylinder with gas for heat transfer; a cooling pipe installed in the cylinder in the axial direction into which the cooling fluid was introduced from the end in this axial direction; a heating pipe installed in the cylinder in the axial direction into which fluid was introduced to heat from the other end in the axial direction; a cooling flow channel for cooling gas in the form of a spiral pipe installed in contact with the perimeter of the cooling pipe; a heating flow channel for heating gas in the form of a spiral pipe in contact with the perimeter of the heating pipe, and an opening at both ends to produce a gas stream; a fan mounted at least at the inlet or outlet of the cooling flow channel and the heating flow channel, and an output shaft rotating together with this fan; moreover, the gas heated in the channel of the heating stream was introduced, on the one hand, into the channel of the cooling stream, and the gas cooled in the channel of the cooling stream, was introduced, on the other hand, into the channel of the heating stream to create convection of gas circulating in a spiral motion between a cooling stream channel and a heating stream channel; and said fan rotated due to convection created by the temperature difference of the gas to generate electricity.

However, in such a device, the high-pressure gas in the channel of the cooling stream is cooled and compressed, increasing its specific gravity, and circulates through the long channel of the spiral flow to create a centrifugal force, as a result of which the gas is pressed by centrifugal force against the round wall of the convective flow channel, which leads to a significant loss of energy due to the friction force created by this.

When creating any large model of this device, the use of a flat fin for heat transfer necessarily entails an increase in the heat transfer distance per unit width, while with a significant decrease in the heat transfer rate and, in addition, the wall thickness of the cylinder should increase with a corresponding increase in mass, which reduces the output power due to a decrease in the rate of heat exchange with the medium coming from outside.

The objective of the invention is to eliminate these drawbacks in a conventional device for generating electricity by convection, to provide an improved method for converting convection energy into energy generation energy with higher efficiency and to provide an electricity generation device for implementing this method.

SUMMARY OF THE INVENTION

The problem is solved in that in the method of generating electricity by convection according to the invention, a downward gas flow channel inside it and an upward gas flow channel outside it is formed in a cylindrical closed zone, hermetically containing gas, form a vortex flow by contacting a downward gas environment with a low temperature medium flow and contacting with the high temperature medium the upward gas flow and rotate the power generation turbine in a vortex flow to generate electric energy, while the channel of the downward gas stream and the channel of the upward gas stream are separated from each other by a cylindrical rotor located between them.

According to another embodiment of the invention, there is provided a method for generating electric energy by convection, in which a downward gas flow channel inside it and an upward gas flow channel outside it are formed in a cylindrical closed zone sealed with gas and form a vortex stream by contacting a downward gas stream with a low temperature medium and contacting with the high-temperature medium the upward gas flow and rotate the power generation turbine in a vortex flow to generate electric nergii, wherein the channel and the descending gas flow channel of the ascending gas stream separated by the first cylindrical rotor and between the ascending gas flow channel and the partition wall separating the closed zone from the outside space is mounted a second cylindrical rotor.

The above problems are also solved by the fact that the device for generating electricity by convection contains a cylinder filled with gas, a cylindrical rotor mounted in it with the possibility of rotation, fixed in its upper and lower parts and containing a spiral supply pipe of a low-temperature medium, a spiral supply pipe of a high-temperature medium installed along the outer surface of the cylindrical rotor, a turbine for driving an electric power generator and a starting fan, permanently installed bottom of the cylindrical rotor. The rib for increasing heat transfer is adjacent to the supply pipe of the low-temperature medium and to the supply pipe of the high-temperature medium. The turbine for driving the electric power generator is made in the form of thrust-creating deflectors attached below the wavy surface of the wall of the cylindrical rotor.

In another embodiment of the invention, a device for generating electricity by convection comprises a gas-filled cylinder, a first cylindrical rotor mounted therein rotatably mounted in its upper and lower parts and containing a spiral supply pipe of a low-temperature medium, a spiral supply pipe of a high-temperature medium installed along the outer side of the first cylindrical rotor, the second cylindrical rotor separating the supply pipe of the high-temperature medium and the inside the bottom wall of the cylinder from each other, a turbine for driving an electric power generator, and a starting fan, permanently mounted at the bottom of the cylindrical rotor. Moreover, the rib for increasing heat transfer is adjacent to the supply pipe of the low-temperature medium and to the supply pipe of the high-temperature medium. The turbine for driving the electric power generator is made in the form of thrust-creating deflectors attached below the wavy surface of the wall of the cylindrical rotor. Moreover, many gas outlets are made in the side wall of the second cylindrical rotor.

Brief Description of the Drawings

FIG. 1 is a schematic cross-sectional view showing, as an example, that according to the method of the present invention, a cylindrical rotor is installed between the upward gas flow channel and the downward gas flow channel.

Figure 2 is a schematic cross-sectional view showing, as an example, that according to the method of the present invention, cylindrical rotors are installed between the upward gas flow channel and the downward gas flow channel and between the upward gas flow channel and the partition separating the closed zone from the outer space.

Figure 3 is a sectional view of an example of a device according to this invention.

FIG. 4 is a cross-sectional view of an example construction of the cylindrical rotor shown in FIG. 3.

5 is a schematic cross-sectional view of a device according to this invention: two cylindrical rotors are installed between the upward gas flow channel and the downward gas flow channel and between the upward gas flow channel and the partition separating the closed zone from the outer space.

6 is a schematic cross-sectional view of an example of a device according to this invention.

7 is a schematic cross-sectional view of yet another example of a device according to this invention.

Preferred Embodiment

The following is a description of the method and device according to this invention with reference to the accompanying drawings.

According to FIG. 1, which is a schematic cross-sectional view of an example device in accordance with the method of the present invention, in which a cylindrical rotor is installed between the upward gas flow channel and the downward gas flow channel, a cylindrical rotor 2 attached to a pair of upper and lower fans 3, 4, with the possibility of rotation mounted on the hinged support elements 8, 9, is placed inside a cylindrical partition 1, separating the closed hermetically containing gas zone from the outside a space of; moreover, the lower fan 4 is connected to the input shaft of the electric power generator 10 by means of gears 5, 6 and to the output shaft of the engine 11 by means of gears 5, 7.

An upward gas flow forced to form upon contact with a high-temperature medium rises along the flow channel A → B → C → D and, on the other hand, a downward gas flow forced to form upon contact with a low-temperature medium is lowered along the flow channels D → E → F → A and G → R to form a swirling flow at the locations of the fans 3, 4, which drives the fans 3, 4 and at the same time rotates the cylindrical rotor 2 attached to them.

According to FIG. 2, which is a schematic cross-sectional view of an example device, in accordance with the method of the present invention, in addition to the first cylindrical rotor, a second cylindrical rotor is also installed between the upward gas flow channel and the upstream gas channel and the baffle separating the closed zone from the outside; wherein the second cylindrical rotor 12 has, as necessary, gas outlets 13, is installed between the first cylindrical rotor 2 and the cylindrical partition 1 in addition to the arrangement described in FIG. 1, and is forced to rotate due to the movement of the gas flow in the cylindrical partition 1, so that thereby reducing friction between the upward gas stream and the downward gas stream.

The gas between G and H is compressed to the outside between E and F by centrifugal force and creates heat of compression, which can be effectively used to increase the temperature difference with the help of a cooling medium in order to increase the heat transfer efficiency. A gas near F, whose heat is removed, is sharply compressed and receives a significant centrifugal force between A and B under the influence of an increasing specific gravity.

Then the gas between A and B enters between B and C, it is now subject to an even greater centrifugal force, but the compression is created by the gas outlets 13, and therefore the heat of compression is not created, and the expansion is caused by heat exchange with a high-temperature medium between B and C, as a result of which the specific gravity decreases. A low specific gravity gas is affected by a small centrifugal force between C and D, which is eliminated by the significant centrifugal force arising between A and B to continue circulation, and therefore significant twisting energy is generated. This is preferable in order to speed up the adjustment at the time of start-up, in order to temporarily start rotation with the help of the engine.

The following is a description of a suitable example of a device for implementing the method according to this invention with reference to the accompanying drawings.

Figure 3 illustrates in partial section an example of a device according to this invention, and Figure 4 illustrates, in section, an example of the construction of the cylindrical rotor shown in Figure 3.

According to FIG. 3, the device according to this invention consists of a cylindrical rotor 102 located inside the cylinder 101, and from a supply pipe 103 of a high-temperature medium, which surrounds its perimeter in a spiral form. The supply pipe 103 of the high-temperature medium runs along the entire length, has an inwardly directed rib 104 to increase heat transfer.

Figure 4 illustrates an example of a cylindrical rotor 102 mounted in the device, and rotatable blade 106, stationary connected to the bottom surface of this cylindrical rotor 102 and thereby mounted on the cylinder 101 with the possibility of free rotation using the hinged support elements 107 and 108 and levers 109 to separate the spiral feed line 110 of the low temperature medium from the feed line 103 of the high temperature medium installed therein. It is important that the articulated support elements 107 and 108 used here are of such a design that will allow smooth rotation of the cylindrical rotor 102 without load. For example, a design with reduced friction due to the use of bearings such as hydrostatic bearings with mercury, magnetic thrust bearings, rolling bearings on superconductors, etc.

In a device of this design, when a high-temperature medium and a low-temperature medium are introduced into the high-temperature medium supply line 103 and the low-temperature medium supply line 110, respectively, the gas in the cylinder 101 is heated near the high-temperature medium supply line 103 and the ribs 104, thereby creating an upward flow and gas in the cylindrical the rotor 102 is cooled by contact with the supply pipe 110 of a low temperature medium, while creating a downward flow.

The upward flow and downward flow formed in this way do not contact each other until they reach the bottom of cylinder 101 or come close to it, and therefore they can be used to form a vortex flow that does not lose energy due to friction, and therefore, when a start-up fan is installed in this part of the device, a strong rotation is created, and electricity can be generated with good efficiency when the power generation engine is connected to this start-up fan through the output shaft.

Alternatively, the cylindrical rotor 102 has a structure in which the surface of its wall is made wavy and has deflectors that exclude the gas flow and are installed below the wavy shape and after a certain interval; or has a structure in which the deflectors are inclined in the direction of flow, thereby eliminating the pressure vector of the flow in a collision with the pressure vector in the direction of the flow channel in and out of the cylindrical rotor 102 to reduce gas leakage. Here, the cylindrical rotor 102 need not be cylindrical with the same diameter from top to bottom, but may be in the form of a truncated cone with different diameters from top to bottom.

5 schematically illustrates a cross section of an example of a device having two cylindrical rotors installed between an upward gas flow channel and a downward gas flow channel and between an upward gas flow channel and a partition separating a closed zone from an external space.

In the drawing, two cylindrical rotors 102 and 111 are mounted in the cylinder 101, and they are mounted coaxially and concentrically with the possibility of independent rotation. The first cylindrical rotor 102 inside separates the downward gas flow channel formed by the low-temperature spiral supply pipe 112 and the upward gas flow channel formed by the high-temperature supply pipe 113 so that the downward flow and upward flow are not in contact with each other.

In this case, the second cylindrical rotor 111 is externally located between the upward gas flow channel formed by the supply pipe 113 of the high-temperature medium and the inner wall of the cylinder 101 to eliminate the decrease in the speed of the upward flow due to friction between the upward flow relative to the surface of the wall of the cylinder 101, with the exception of heat generation due to strong friction and heat of compression of the gas on the surrounding walls under the influence of centrifugal force.

Preferably, the cylindrical rotor 111 on the outside has gas outlets 114 at appropriate locations to disperse the gas, which is given an increased specific gravity as a result of compression by centrifugal force.

The gas outlets 114 are preferably in the form of a through hole at an angle in the direction opposite to the direction of rotation of the cylindrical rotor 111 to facilitate rotation of the cylindrical rotor 111.

In the device according to this invention of the described construction, the low-temperature medium and the high-temperature medium are introduced into the low-temperature medium supply pipe 112 and the high-temperature medium supply pipe 113, respectively, as a result of which a downward flow is formed inside the first cylindrical rotor 102 and an upward flow is formed outside it, and therefore the vortex flow is created in the lower part of the cylinder 101 due to convection circulation in the direction of the arrow - Figure 5.

In this case, the first cylindrical rotor 102 is rotated by a fan (not shown) mounted on its bottom to capture the vortex flow in order to increase the speed of the upward flow. In this case, the second cylindrical rotor 111 is also rotated in order to reduce the compression of the gas by centrifugal force, and also to facilitate the formation of a vortex flow due to the buoyancy force from the gas outlets 114, as a result of which the specified fan rotates faster, and the power generation efficiency its use can be greatly enhanced.

Example 1

6 illustrates an example according to which one cylindrical rotor is installed in the device according to this invention and according to the construction of which one cylindrical rotor 202 is installed inside the cylinder 200 having a coating of heat-insulating protective material 201.

According to this drawing, the cylindrical rotor 202 is driven into rotation by gas A under the influence of convection through the upward gas flow channel 203 and the downward gas flow channel 204, in order to significantly increase the output power by eliminating energy attenuation due to gas friction. The cylindrical rotor 202 has a corrugated wall surface to which thrust deflectors 205 are attached at the bottom of the corrugated portion at an appropriate interval, whereby the cylindrical rotor 202 rotates under the influence of gas pressure A applied to the deflectors 205, and this rotation can be used to drive electric power generator 214 .

In this case, baffles 205 are used to prevent gas leakage A from the gap between the upward gas flow channel 203 or the downward gas flow channel 204 and the cylindrical rotor 202, with a slope in the direction of rotation, so that the leakage of gas A can be prevented by reactive pressure in the collision of gas A with baffles 205.

Channel 204 downward gas flow is formed by contact with the supply spiral pipe 206 of the cooling medium; and this coolant supply pipe 206 has a V-shaped rib 207 attached to it at one time along the entire length in order to increase the heat transfer rate and strengthen it along the entire length. The heat exchange carried out by this V-shaped rib 207 can be increased if it is hollow, and by making passage openings 208 between it and the cooling medium supply pipe 206.

A downward gas flow channel 204 is formed along the inner side of the coolant supply spiral pipe 206 to rotate the starting fan 209 located in the opening of its lower end due to gas pressure and to start the cylindrical rotor 202 connected to the starting fan 209. The gas flows under the action of centrifugal force from the outlet / inlet 211 for gas, made in the cover plate 210 of the cylinder 200, installed near the lower bearing part of the shaft drum rotor 202 to compress and increase the gas pressure A in the upward gas channel 203 and the downward gas channel 204 near the outer perimeter of the cylindrical rotor 202 in order to ensure alignment, without the need for an oil seal, by the output gear 212 with a centrifugal clutch of the cylindrical rotor 202 .

The closed cylinder 200 is separated from a portion of the electric power generator 214 by means of a cover plate 210; and the gas A having increased pressure moves due to the centrifugal force of the cylindrical rotor 202 in order to compensate for losses from air resistance by reducing the pressure in the part of the electric power generator 214 along with up / down control of the gas output A at the lower end of the cylinder 200 to take away electric energy due to ensure the safety of high pressure gas A.

The supply pipe 213 of the heating medium consists of a corrugated casing in the form of a spiral on the inner wall of the cylinder 200 and the outer wall of the cylindrical rotor 202 and has such a design that the heating medium enters the intermediate space on the inner wall of the cylinder 200 and the intermediate space on the outer wall of the cylindrical rotor 202 serves as an upward gas channel 203.

As for the supply line 213 of the heating medium, the flow rate cross section and the cross section of the external surface area and the upward gas flow channel can be adjusted in accordance with the density of gas A by changing the angle or length of the corresponding protrusions and recesses of the spiral corrugated body.

The heat transfer area of the spiral corrugated body can also be increased by providing a spiral V-shaped rib on the inner wall of the cylinder 200 along with optimization of the axial pressure-resistant strength of the cylinder 200.

An output gear 212 with a centrifugal clutch engaging the gear 216 for generating electric power, which serves to drive the electric power generator 214 by means of an electromagnetic clutch 217, is installed at the central lower end of the cylinder 200 in this device. This output gear 215 with a centrifugal clutch is inactive start time, when the rotation moment is small, and automatically enters the connected state only during normal rotation. With an idle power generator 214, this centrifugal clutch output gear 212 can be used to directly switch to another power generator 215.

When the cylindrical rotor 202 is rotated at high speed with the crane 219 open in part 218 of the electric power generator of the cylinder 200, the gas inside the rotor is usually compressed by the centrifugal force on the surrounding walls of the rotor, resulting in negative pressure in the central part of the rotor. Therefore, the gas in the electric power generator part 218 is sucked from the gas flow opening in the cover plate at the bottom of the cylinder 202, and a lower pressure is generated in this part, and therefore the gas on the outside of the valve 219 enters the electric power generator part 218.

The operating device can be stopped by stopping the supply of the heating medium and the cooling medium to the heating medium supply pipe 213 and to the cooling medium supply pipe 206. After that, the temperature difference between the upward gas channel 203 and the downward gas channel 204 disappears, as a result of which gas convection in the cylinder 200 stops and the rotation of the cylindrical rotor 202 also stops. The suction external gas is discharged through the valve 219 for safety.

Moreover, the upper end of the cylindrical rotor 202 has a holder 222 of the rotary rim with a rotary ring 220 and the blades 221 of the rotary rim, and the state of convection of gas A can be adjusted by changing the angles of the blades 221 of the rotary rim.

The rotary rim holder 222 is connected to the thrust bearing 223, providing a tight state for the cylinder 200, the cylindrical rotor 202 is rotatable, and the cooling medium is introduced into the cooling medium supply pipe 206 through the main cooling pipe 224 passing through its center, as a result of which the cylindrical rotation rotor 202 can smoothly continue without any disturbance.

Example 2

7 illustrates an example of a device that comprises two cylindrical rotors 301, 302 in a cylinder 300 that uses solar energy as a heat source for a high temperature environment.

In this device, a second cylindrical rotor 302, which serves to reduce friction between the upward gas flow channel 304 and the inner wall of the cylinder 300, is installed in addition to the first cylindrical rotor 301, which serves to prevent contact between the downward gas flow channel 303 and the upward gas channel 304 . The first cylindrical rotor 301 and the second cylindrical rotor 302 are connected by gears 306, 307 with different rotation through the centrifugal clutch 305, as a result of which the rotation can be adjusted in accordance with the expected load on the electric generator 315.

In this device, when the first cylindrical rotor 301 rotates at high speed, gas A located therein is compressed under the influence of centrifugal force and its temperature rises, as a result of which the heat transfer rate increases due to an increase in the temperature difference relative to the downward gas channel 303 flow near it; on the other hand, when the second cylindrical rotor 302 rotates at a low speed, the gas A located therein is compressed to a lesser degree by the action of centrifugal force, and therefore it expands with decreasing temperature, as a result of which the temperature difference rises channel 304 upward gas flow, with an increase in the rate of heat transfer, resulting in increased output power even with a small temperature difference.

In this case, a significant difference rotation can, if necessary, be achieved by selecting fewer teeth in the gear 306 and more teeth in the gear 307, while the gear ratio must be determined taking into account the resulting temperature difference, the density of which has an increased gas pressure A and other things.

In this figure, the low-temperature medium supply pipe 308 is helical to form a downward gas flow channel 303 in a first cylindrical rotor 301 having a wavy wall surface, and this low-temperature medium supply pipe 308 is connected along its entire length with a V-shaped rib 309, which is hollow inside to enhance heat transfer.

The supply pipe 310 for a high-temperature medium heated by solar heat is mounted in the form of a spiral on a second cylindrical rotor 302, which also has a wavy wall surface, and is also connected along its entire length with a V-shaped rib 311, which is hollow inside to increase heat transfer. The start fan 312 is stationary mounted near the bottom surface of the first cylindrical rotor 301 and is connected to the electric power generator 315 by means of a rotation shaft 316 and gears 313, 314.

Electricity can be generated in the same way as in Example 1 in the power generation device of the indicated design, the device can be stopped in the same way.

Industrial applicability

This invention has valuable applicability as a clean source of power supply, since electricity can be generated with high efficiency due to the use of the phenomenon of creating a temperature difference that occurs in nature, for example, heating by solar heat, a temperature difference in the sea, a temperature difference created by geothermal heat, etc.

Claims (9)

1. A method of generating electricity using convection, characterized in that in the cylindrical closed zone, hermetically containing gas, a downward gas flow channel is formed inside it and an upward gas flow channel outside it, form a vortex stream by contacting a downward gas stream with a low temperature medium and contacting with the high-temperature medium the upward gas flow and rotate the power generation turbine in a vortex flow to generate electricity, while the downward channel AZOV flow channel and the ascending gas stream is separated from each other by a cylindrical rotor disposed therebetween. 2. A method of generating electricity using convection, characterized in that in the cylindrical closed zone, hermetically containing gas, a downward gas flow channel is formed inside it and an upward gas flow channel outside it, form a vortex stream by contacting a downward gas stream with a low temperature medium and contacting with the high-temperature medium the upward gas flow and rotate the power generation turbine in a vortex flow to generate electricity, while the downward channel the gas stream and the channel of the upward gas stream are separated from each other by the first cylindrical rotor, and a second cylindrical rotor is installed between the channel of the upward gas stream and the partition separating the closed zone from the outer space. 3. A device for generating electricity through convection, containing a cylinder filled with gas, a cylindrical rotor mounted in it with the possibility of rotation, fixed in its upper and lower parts and containing a spiral supply pipe of a low-temperature medium, a spiral supply pipe of a high-temperature medium installed along the outer surface a cylindrical rotor, a turbine for driving an electric power generator, and a starting fan fixedly installed at the bottom of the cylindrical rotor. 4. The device for generating electricity due to convection according to claim 3, characterized in that the rib for increasing heat transfer is adjacent to the supply pipe of the low-temperature medium and to the supply pipe of the high-temperature medium. 5. A device for generating electricity due to convection according to claim 3, characterized in that the turbine for driving the electric power generator is made in the form of thrust deflectors attached at the bottom of the corrugated wall surface of the cylindrical rotor. 6. A device for generating electricity by convection, containing a cylinder filled with gas, a first cylindrical rotor mounted in it with a possibility of rotation, fixed in its upper and lower parts and containing a spiral supply pipe of a low-temperature medium, a spiral supply pipe of a high-temperature medium, installed along the external side of the first cylindrical rotor, the second cylindrical rotor separating the supply pipe of the high-temperature medium and the inner wall of the cylinder from each other, a turbine for driving the electricity generator and a starting fan fixedly installed at the bottom of the cylindrical rotor. 7. The device for generating electricity due to convection according to claim 6, characterized in that the rib for increasing heat transfer is adjacent to the supply pipe of the low-temperature medium and to the supply pipe of the high-temperature medium. 8. The device for generating electricity due to convection according to claim 6, characterized in that the turbine for driving the electric power generator is made in the form of thrust deflectors attached below the wavy surface of the wall of the cylindrical rotor. 9. A device for generating electricity by convection according to claim 6, characterized in that the plurality of gas outlets are made in the side wall of the second cylindrical rotor.

Images